Surface aspects of excitons in semiconductors

Progress in Surface Science, Vol. 36, pp. 179-287 Printed in the U.S,A. All rights reserved.

0079-6816/91 $0.00 + .50 Copyright @ 1991 Pergamon Press plc

SURFACE ASPECTS OF EXCITONS IN SEMICONDUCTORS A.E. CHEREDNICHENKO and V.A. KISELEV Leningrad State University, Solid State Department, Institute of Physics, 198904, Staryi Petergoff, Leningrad, U.S.S.R., and, A.F. Ioffe Physico- Technical Institute, Academy of Sciences of the U.S.S.R., 19402 I, Leningrad, U.S.S.R. Abstract This review considers the factors which influence the exciton behavior at the semiconductor surface and, consequently, are revealed through excitonic optical spectra. The basic knowledge of excitons in semiconductors is first presented. The experimental exciton reflectance spectra of OdS and CdSe crystals are discussed followed by an analysis of the results which make use of the near-surface "dead-layer" model. In particular, the effect of the electron irradiation on the exciton reflectance lineshape and exciton photoluminescence is considered with reference to the physical factors which control optical spectra. Various mechanisms of localization of excitons in a semiconductor surface region are presented. Relevant experiments on low-temperature photoluminescence and reflectance are discussed. Finally, the effect on the exciton reflectance of the electric field of the space-charge layer considered in detail.

Contents

Page

1.

Introduction

181

2.

Wannier-Mott excitons. Energy considerations

182

3.

Excitons: Mechanical, Coulomb, real (polaritons)

186

4.

Exciton reflectance spectra

191

A.

191

Thomas-Hopfield near-surface "dead" layer and the exciton reflecfivity

179

180

A.E. Cherednichenko and V.A. Kiselev

5.

B.

The effect of keV-electron irradiation on exciton reflectance spectra

198

C.

Interpretational problems

205

D.

Interference effects in thin crystals. Size quantization of excitons

211

E.

Exciton transition layers and a formal model

215

Crystal defects and localization of excitons

218

A.

Bound excitons

218

B.

The effect of keV-electron irradiation on the exciton photoluminescence spectra

220

C.

Surface and near-surface excitons

225

D.

Localization of excitons in rectangular potential wells

229

E.

Localization of excitons in defect-rich surface layers

237

E

Localization of excitons by fluctuations of a near-surface

6. A.

random potential

241

Band bending and its relevance to excitons and exeiton spectra

244

Band bending in semiconductors

245

B.

The effect of a uniform electric field on excitons

248

C.

The effect of a non-uniformelectric field on excitons

254

D.

Exciton relectivity in the ease of thin SCLs

257

E.

Quasilocalization of excitons in the SCL field and the effect of damping

267

E

The effect of SCL on the phase of the reflected light

273

G.

Exciton reflectance in the case of wide SCLs

276

References

283

Abbreviations

ABCs AWs DL EB ERL ETL SCL

Additional boundary conditions Additional waves Dead layer Electron bombardment Exciton reflectance lineshape ~xciton transition layer Space charge layer

Excitons at Semiconductor Surfaces

181

1.Introduction In surface physics, the most sensitive probe is the electron, be it in Auger spectroscopy, in low energy electron diffraction, or in photoelectron spectroscopy. However, the photon also provides information on surface phenomena, though its penetration into the bulk of the material usually exceeds that of the electrons. Optical techniques are, for instance, ellipsometry, spectroscopy of the vibrational structure of physisorbed chemisorbed molecules, spectroscopy of surface polaritons.

IR and

In this review we intend to discuss one more optical technique which can be used to investigate surface (near-surface) layers of semiconductors. The purpose of the paper is to present an exoiton as a probe in the studies of surface (near-surface) properties of real semiconductor crystals, either as grown or subjected to various surface-sensitive treatments (e.g., electron irradiation). We will conoentr~ate mainly on A2B 6 - compounds (CdS, OdSe) and summarize the present state of understanding of the problem based on

our

experimental

and

theoretical

studies

and

also

on

the

results obtained by other researchers specializing in the field of the exoiton behavior at a semiconductor surface. We shall show that some of the data on the exciton reflectance spectra

may

serve

a

useful

guide

to

understanding

surface

properties of real semiconductors. In particular, the overall shape of the exciton (polariton) reflectance signal appears to be a sensitive function of the presence below a semiconductor surface of the exciton-free layer (the so-called "dead" layer). The width of this layer can be varied from several tens to thousands of ~gstroms by a number of techniques (e.g., by keV-eleotron bombardment). A theoretical lineshape analysis of the reflectance will be given which evidence the role of the exciton-free layer and space charge layer (SOL) in the formation of the exciton

182

A.E. Cherednichenko and V.A. Kiselev

reflectance lineshape (ERL). Studies

of

the

so-called

bound

exciton

luminescence

and

its

modification under electron bombardment will be presented in Sect. 5 and various physical mechanisms of the exciton localization at a semiconductor surface will be discussed. Finally, in Sect. 6 the effect on the exciton reflectance of the SOL will be considered in detail. We also note that surface aspects of exciton photoconductivity phenomenon are not considered in this review. A detailed account of

a

surface

sensitivity

of

photoconductivity

spectra

is

in

preparation. 2. Wannier-Mott Excitons. Energy Considerations An

exciton

is

the energy

quantum of

an electronic

propagating in insulating or semiconductor crystals.

excitation In case the

energy band model is well applicable, it can also be regarded as a composite particle hole

in

the

of an electron

valence

band

bound

in the conduction band and a to

each

other

by

the

Coulomb

attraction between them. If the electron and hole are so far apart that

the atomic

structure

of

the

crystal

can be

ignored

their

mutual potential can be written as v = -e2/~

,

(2.1)

where p is the electron-hole separation and ~ is the macroscopic (long

wavelength)

dielectric

constant

generally

taken

as

the

square of the refractive index. Such a composite particle, which we

call

Wannier-Mott

exciton

(see

[1,2])

may

analogy with the hydrogen atom. The potential Coulomb potential

reduced by

the dielectric

be

visualized

(2.1)

by

is just the

constant,

and there

will be bound states of the exciton system having total energies lower than the bottom of the conduction band. By analogy with the hydrogen (n=1)

atom

state

the binding (the

energy

energy level

of

the

referred

exciton to

the

in

the ground

bottom

conduction band) is given by the m o d i f i e d R y d b e r g formula:

of

the

Excltorl lit 6ernk~nductor Surfaces

183

4

~e ~1 = - ~

= (~/=o)'s-2"~1~

,

(2.2)

where ~ is the reduced mass of the exoiton ~-1 = m;1 + ~ 1 , formed from

the

effective

masses

m e , mh

of

the

electron

and

hole,

respectively, m 0 is the free electron mass and IEIH i = 13.6 eV is the ionization potential of the free hydrogen atom. Pot a simple case of isotropio non-degenerate baud extrema at the zone center the kinetic energy of the carrier is E k = ~2k2/2m = where m is the effective mass (me for the electron and m h for the hole) and Phk is the momentum at the extremum. The resulting spectrum for the exciton energy consists of the sum of the internal energy and the exciton center-of-mass kinetic energy ~e 4

Q¢K)

=

2~2~2n2 +

~2K2

2.

'

¢2.3)

where I = m e + m h, h~ is the momentum of the center of mass and n = 1,2,3 .... o0. £n is measured from the band edge EG. Thus, the

Fig. 1. Energy of the exoiton bands for Wazluier Mot t excitons vs waveveotor K. The d~mhed line represents the energ~ vs waveveotor dispersion curve 0~ ~ o o u p l e d photon.

184

A.E. Cherednichenko and V.A. Kiselev

exciton spectrum consists of a series of parabolic bands below E G which merge into a continuum at high energies, The

binding

energy

of

the n=1

exciton

electron-hole at the band edge given by

see Fig. I.

relative

to

the

free

(2.2), often called the

"exciton Rydberg", can also be expressed in terms of the "exciton Bohr radius" given by

Rex c = ~ 2 s / ( ~ e 2 )

= (~/mo)-l.

8-R,I:I

,

(2.4)

where RH = 5.29"10 -9 om is the radius of the first Bohr orbit for the free hydrogen atom. (2.2)

and

(2.4)

Note that the factors ~/m 0 and 8 entering

reduce

the

binding

energy

and

correspondingly

increase the radius by a factor of 102 or even 103 as compared with the hydrogen atom. As a result, typical values of the exciton Rydberg

in A2B6-compounds

are

of

the

order

of

10 meV

and

the

exciton radius is about a few tens of ~ugstroms. By virtue of its large

size

the

Wannier-Mott

exciton

is

extremely

polarizable.

Consequently the applied electric field has a pronounced effect on exoitons. In what follows we shall show that the exciton spectra are

very

sensitive

to

the

surface

electric

field

which

is

an

scheme

is

an

essential point to be emphasized here. As

shown

infinity

of

transitions

in

Fig.

I

the

overlapping create

exciton continua;

excitons

of

energy

level

nevertheless,

well-defined

its

energy

optical and

can

therefore be sharp. This a consequence of momentum conservation. In

the

case

of

direct

transitions,

i.e.,

vertical

on

the E(K)

diagram, a photon of energy ~L0 can only create an exoiton with K = nt0/c, where n is the refractive cm -I so that ~2K2/2M ~ IO-SeV.

index.

For ~

~ eV, o/c

~ 105

Thus the only exoitons which can be directly created by a photon have

a

well-defined

negligible.

energy,

Transitions

electron-hole pairs,

and

involving

their

kinetic

the

creation

on the other hand,

give

energy of

is free

continuous spectra

for E > E G, since momentum conservation only puts one condition on k e and kh, leaving the relative motion of the electron and hole free to be specified by energy conservation. For the exciton, the

Exdtons at Semiconductor Surfaces

185

requirement that the electron and hole sts~V together eliminates this degree of freedom. The existence of sharp optical transitions in a crystal is evidence for the existence of exoitons. It is difficult to produce excitons in sufficient concentrations to observe directly the transitions amor~ the exoiton levels, but it is possible to observe the transitions between the valence band edge and an exoiton level. A series of sharp lines occurring on the long wavelength side of the absoz-ption edge and merging into the continuum has been first observed in cuprous oxide Ou20 (see, e.g., [3]). The spacing of the exoiton levels has been found to be in surprisingly good agreement with the Rydberg formula for n > 2. Later, large-radius Wanniez--Mott exoitons were revealed in a great number of semiconductors (for the A2B6-compounds see, e.g. [4]). It is evident that it the energy surfaces are not isotropio and non-degenerate the exoiton problem is considerably more complicated. A sketch of the energy band structure of A2B6-oompounds (wurtzite) is shown in Fig. 2. In wurtzite-type crystals the conduction band is simple, whereas the valence band consists of the three close-lying bands F 9, r 7, and r 7 which arise due to crystalline field and spin-orbit splitting effects. The valence bands are termed A, B, O, starting from the uppermost valence band, respectively. An appropriate optical excitation yields A-, B-, and O- exoiton series.

Fig. 2. A sketch of the energy bands in wurtzite-type crystals.

B

C

r, x(ooo)

186

A.E. Cherednichenl(o and V.A. Kiselev

Note, that the A-exciton is only allowed for light polarized perpendicular to the hexagonal axis ElO (~ is the electric field vector of the light and o is the unit vector along the hexagonal axis (c-axis)). A free exoiton at liquid helium temperatures has a velocity N of about 106 cm/s, so for an impurity concentration N ~ IO150m -3 its lifetime before capture iS expected to be (Nov)-I ~ I0-9s. Thus the exciton is a short lived excited state of the crystal observed at low temperatures near the band edge (below ~5000 ~ for OdS and ~7000 ~ for CdSe) so that virtually the only way of studing it is by optical spectra, v~Z., transmission, refleetlvity and luminescence. (We note that the exeiton photoconductivity phenomenon is b~¥ond the scope of the present review), To conclude, we note two more points important from the experimental point Of view. (a) Optical experiments are essentially performed at loW temperatures (moStly at 4.2K) insofaras the exciton binding energies are very small which results in an easy thermal dissociation of exoitons. (b) The exciton absorption coefficient in the cr~stal with allowed direct transitions may be of the Order of ~IO 5 om -I . This has two consequenoies. (i) Ex0itons thus excited are essentially generated in the near-stu~f~ce region of a cr~stal. (ii) Small penet~mtion depth of the exoiton does not allow transmission studies, hence, exciton reflectance ~easurements need to be carried out instead.

3, Exoitons! Mechanical, Ooulomb, Real (Polaritons) Figure I corresponds from an experimental point of V i m to a low-resolution spectroscopy, whe~ the intersection of the photon dispersion curve and the eXciton band is given by a point. In the case of a high resolution this approach would be inappropriate, especially for the ground (n = I) states of dipole-active exoitons [5] which are characterized by a large oscillator strength. More accurately the exciton states in the region of their intersection with the photon dlspe2sion should be considered as in Fig. 3.

Excitons at SemiconductorSurfaces

~

b

I I ! !

/

187

o

I wL~--" 7

/ k

~

k

Fig. 3. Exciton dispersion curves. (a)- mechanical approximation, (b)- Coulomb approximation which allows for the longitudinal field, (c)- with allowance for longitudinal and transverse fields.

Figure 3a corresponds to the approximation mentioned above, when the longitudinal electric field, produced due to the exciton wave propagation is not taken into account and the interaction with the transverse electromagnetic field is negleQted. Within that approximation the exoitons are referred to as mechanical [6], therefore, the approximation is termed mechanical. The inclusion of the longitudinal electric field arising already in a more simple system of the Lorentz oscillators [7], when longitudinal vibrations (exoitons) are excited, leads to increase in the energy of these excitations by the value h(~ L - ~0 ) ~ ~ L T (Fig. 3b). The longitudinal exciton, that is the exciton with P~K, P being the vector of polarization, is refem~ed to as the Coloumb exoiton [6], so that the approximation is a Coulomb one. The exoitons with the polarization PIK that do not interact with the longitudinal field

188

are

A.E. Cherednichenko and V.A. Kiselev

still

mechanical

in

this

case.

Lastly,

an

account

of

the

interaction with the transverse electromagnetic field brings about modification

of

yielding real The

above

the

transverse

excitons

[6]

(photoexcitons

considerations

vibrations by Born

exciton

were

applied

dispersion

(Fig.

3c),

[8], polaritons to

crystal

[10], and to excitons by Pekar

[9]).

lattice

[8], Hopfield

[9] and Agranovich [ 1 1 ] . Figure

3 can

also

dielectric

theory.

associated

with

be

The

the

treated

from

the point

of view

of

the

excitation of a dipole-active exciton polarization

of

the

medium

P(R,~)

is

which

satisfies the following equation [6,8,12]: B(~° where B = ~O/M, is

the resonant

+ q2(~))

= _~ 2 ( R , ~ )

~ = (2%)-1~O~LTSO , q2= _ B - I ( ~ frequency

the mechanical

~(~,~)

of

the mechanical

exoiton damping;

,

(3.1)

_ ~2 _ ¢ ~ p )

exoiton

at

a n d ~0

K = O; F i s

s 0 is the background dielectric

constant which contains contributions from all interactions except the exciton in question. A right-hand part of the electric field may be mechanical

field vector, treated as

exciton,

connected with

the driving

since

for

the

(3.1) incorporates

the exciton wave.

force with respect

latter

we

have

E

=

derivation of (3.1) was suggested by Pekar [8]. Equation a material

equation

for

the medium which

Maxwell's set of equations for fields.

is

additional

The

to

the

O.

The

(3.1) is to

the

For a homogeneous medium

one can make use of the Fourier transform and write down, in the case of an isotropic medium, the relation of the following type: 1

~(k,~)

= ~--~[s(E,~)

where the dielectric function ~(k,~) ~(k,~)

(3.2)

- s012(1~,~) is of the form:

= ~£O((fl) - 4'Fu30/((o2 - (,o2

- B k 2 + ~,~r)

,

(3.3)

For the mechanical excitons ~. = O, P # O, and, as it follows from (3.2),

~(~,~)

= ~,

or

Excitons at Semiconductor Surfaces

~(k)

~ (~0 + t ak2/(2M) -

(F/2

189

,

(3.4)

which corresponds to Fig. 3a. For the Coulomb exciton there is only a longitudinal component of the electric field E~k. Since the displacement field B = 80 ~ + 4~7 is transverse we have case D = O. From (3.2) follows 8(k,~) = O, or ~(k)

~ ~0 + %_,T + '%k2/(aM) -

61/2

,

in this

(3.5)

which corresponds to the longitudinal exciton in Fig. 3b. Lastly, for the real excitons (polaritons) there exists only a transverse component of the field EIK, for which the Maxwell equations are related to D by = (02k2/~2)E Solving

(3.6)

together with

(3.6)

(3.2) we arrive at the dispersion

relation: 8(k,~) = c2k2/602

.

(3.7)

It is convenient to solve the equation for k or n (n = ck/~ is the index of refraction). Resulting is the Pekar's which defines the polariton dispersion:

nl,2(~)

I = {60 + 2-

[Q ± (a2 + b ) 1 / 2 ] } 1 / 2

Mc 2 where G = ~°O~ 2 (~2 _ ~02 + ¢~F) - 60;

equation

,

[8]

(3.8)

Mc280~LT b = 8

t~02

These relations define the two polariton branches in Fig. 3c. The polariton approach will be utilized below. In some cases, however, the mechanical exciton approach appears to be more convenient for discussion. Such is the case of the exciton localization in potential wells, which we intend to treat at some length below. As to the calculation of the crystal optical properties, it will be

190

A.E. Cherednichenko and V.A. Kiselev

performed making allowance for the photon-exciton coupling,

i.e.,

within the framework of the polariton theory. In case the exciton mass M is not infinite the mechanical exciton band has dispersion and ~ depends not only on ~ but on k as well. The dependence of on k is referred to as spatial dispersion. Actually this implies a possibility for the excitation to propagate through the crystal in a purely mechanical way when no macroscopic [6,12].

This

also

implies

that

reference point of a medium

the

fields are involved

electric

is not

polarization

in

completely specified by

a

the

field at the same point. The situation is represented by the first member in (3.1) which contains the second derivatives with respect to coordinates.

Therefore a solution to the problem requires an

introduction of the boundary conditions. They are additional with respect

to the Maxwell's

theory and,

hence,

are referred to as

additional boundary conditions (ABCs). Additional boundary conditions have been intensively studied and were a subject of much discussion.

The efforts of the theorists

were essentially concentrated on three main problems: ABOs

appropriate

from a phemenological

point

(i) Type of

of view

(we note,

that even the necessity for introduction of the ABCs was sometimes under

question),

(ii)

The

comparison with experiment, making

use

of

various

attempts

to

specify

the

AB0s

from

(iii) The attempts to derive the ABOs

microscopic

models

of

the

surface.

The

results of the theoretical efforts in these fields were discussed in several reviews and monographs (see, e.g., [6,8,13,14]). The ABO can be given in the form of a linear relation [6]

c

(P + 7 ~ 0

c

dz

)lz:o

: (~

+ ~ ~o ~z

)lz=o

,

(3.9)

where 7, ~, and ~ are functions of frequency (usually ~ = ~ = O is supposed).

Specification of the ABC

is dictated by the physical

properties

of a medium

and,

and

surface

hence,

the ABC

is not

universal. To solve the problem one should specify the properties of the medium and its surface.

Excitons at Semiconductor Surfaces

191

Most common is the ABO introduced by Pekar [8]

#(z

= o) = o

(3.1o)

.

I n a number of papers the calculations of the exoiton reflectance lineshapes were compared for several different ABCs with the experimental spectra. Patella et al. [15] have concluded that the theory based only on the ABC approximation gives a poor fit to the experiment.

4. Exoiton Reflectance Spectra A. Thomas-Hopfield near-surface refleotivity

"dead" layer and

the

exoiton

A theory of exoitons in confined media based on the boundary conditions, the ABOs included, suggests that the exciton state (the exciton binding energy, oscillator strength, damping, etc.) is unperturbed up to the very boundary or perturbed in a very thin layer. The effect exerted on exoitons by the latter is, to a fair approximation, usually neglected. Such an approach, though, may prove inappropriate insofaras, in reality, there exists a near-surface layer where excitons are drastically perturbed. The part of the layer where exoitons are totally damped is referred to as the exciton-free layer or "dead" layer (DL). The concept of the DL was first introduced b y H o p f i e l d a n d Thomas [12]. 0onsider a simple hydrogenio exciton in its ground state. The interaction between the exoiton and its image results in a potential energy of the exoiton ( in a z-plane)

v(z)

1

=~.--

8-1

(--g~)

~

('

Rexo3

.--~--.

,

(4.1)

where E B is the exciton binding energy. Since 8 is greater than !, the force is repulsive. If all the effects of the surface could be

192

A.E. Cherednichenko and V.A. Kiselev

represented by a potential U(z) for the exciton, U(z) would have to be sufficiently repulsive to cause a free exciton to be totally reflected from an effective barrier a finite distance inside the surface. Thomas and Hopfield were first to replace the potential U(z) by an infinite potential barrier, as indicated in Fig. 4. The layer

1

is

referred

to

as

a

Thomas-Hopfield

dead

layer

for

excitons. We note that

the binding energy of the ground exciton vs the

distance z of its center of mass from the surface has been first calculated in

[16] by taking into account the influence of the

image

on

approaching

the

surface. The main conclusion arrived at by the authors was

forces

both

the

electron

and

hole

that

the exoiton binding energy was found to equal the bulk effective exoiton Rydberg only far away from the surface. For z ~ 1.5 Bohr radius, exciton ionization occurs. Oorrespondingly one has in this model

a

layer

decreasing

where

from

its

the bulk

exciton value

approximation depicted in Fig.

to

polarizability zero.

The

is

gradually

infinite

barrier

4 by a dashed line suggests

that

the Pekar's boundary condition P = 0 apply at and to the left of such a barrier.

ZL,

Fig. 4. A formal adiabatic potential (solid line) and the infinite barrier approximation (dashed line).

Excitons at Semiconductor Surfaces

Actually,

193

three spatial regions should be considered,

as applied

to excitons (see Fig. 5): z < 0 (I), 0 < z < 1 (II), and z > 1 (IiI). The first two are characterized by classical indices of refraction n = I and n O = ~ 0 ' respectively. The usual Maxwell boundary conditions plus the P=O boundary condition determine the connection between the second and third regions.

n-1 10

k~

R2 0

1,

z

Fig. 5. A schematic diagram of the normal-incidence exciton reflectacne problem with a dead layer of thickness i. I O, R I , R2 are incident and, respectively, reflected beams.

The exciton reflectance lineshape

(ERL) is primarily determined

by the phase delay between the two interfering beams R I and R 2. The first analysis of the experimental reflectivity measurements using a spatial dispersion approach was carried out by Hopfield and Thomas [121 who pointed out several anomalies in the reflectance spectra to be discussed below. The DL of Thomas and Hopfield, thus depicted is clearly of intrinsic origin and bears no connection with the particular conditions of the surface, taken as an ideal geometry boundary. In general, there will be other contributions to the DL to be discussed further. Whatever the origin of the DL may be, it allows, within a hard wall approximation, treatment of its effect on the reflectance in terms of interference between the light

194

A.E. Cherednichenko and V.A. Kiselev

beams reflected at the vacuum - semiconductor

(z = O) and at the

DL - bulk (z = l) boundaries, respectively. The hard wall DL model has been generalized to arbitrary values of 1 not related to Rex c by Evangelisti et al

[17,18] and it can

be depicted as in Fig. 6.

0.61-

m

-

o ,

,

,

,

I

i

I

I

l

I I

l

I I

g I

I

I i

Fig. 6. Calculated exciton lineshape of the normal-incidence reflectance for the A (n=l) exoiton in CdS. The DL depth 1 was used as a parameter. 1,nm: a- O; b- 4.7; c- 7.1; d- 9.5; e- 11.8; f- 14.2; g- 19.O; h- 26.1; i- 37.9; j- 52.1; k- 71.1; l- 80.6. The positionsof the transverse and longitudinal exciton frequencies are shown by arrows. [18].

Excitons at Semiconductor Surfaces

195

The DL is supposed to be uniform and is characterized by the parameter 1 and a real non-resonant index of refraction, equal, for instance,

to the background index of refraction of a crystal

n O . The crystal bulk is characterized by the dielectric function (3.3). The incident light I 0 generates

in the crystal

with the wave numbers k I and k 2 defined by (3.8). incidence reflectance is given in the form [18] P12 + P23

e~e

R

The

normal

,2 I

1 + /"12r'23e ~'e

two waves

I

,

(4.2)

where ~12 is a constant, ~23 is a function of a resonant character which defines the ERL, and the round-trip phase delay (or the phase angle) e is e = 4'11~_01/~,

,

where k is the wavelength of light in vacuo.

(4.3)

The value of R is

seen to be a periodical function of 1 with a period k/(2n O) which is of the order of 102nm for semiconductors. A reversal of the ERL for the An= I exoiton in OdS is shown in Fig. 6 [18]. With increasing 1 the reflectance minima give place to maxima (and u~ce uersa) and a reversal of the lineshape occurs. With further increase of 1 the maximum is shifted towards long wavelengths. A prominent feature of the ERL is the refleotivity peak at the frequency ~L - the so-called "spike". It is nominated, for the sake of brevity, the "right" spike as referred to the spectral position of the reflectivity minimum. The emergence of the right-spike structure in the case of a homogeneous DL model is accompanied by the decrease of the main reflectivity maximum. The spike problem has been treated in detail by Benemanskaya et al. [ 1 9 ] who attacked the problem of the exoiton reflectance spectra modification under keV-electron bombardment

(see Sect. 4B)

The authors made use of the approach, developed in [12,18,20] and calculated the ERLs in OdS using the two-layer model depicted in

196

Fig.

A.E. Cherednichenko and V.A. Kiselev

5 with

spatial

dispersion

taken

into account.

In addition,

the exciton damping parameter F was introduced and its effect on the ERL was investigated in a wide range of variations o~ 1. The calculation

was

carried

out

for

the

An=l-exciton

in p-geometry

(~,Io, klc) or normal incidence. The following formula was used to calculate

the

reflectivity

coefficient

(with

allowance

for

the

Pekar's ABO [8]) •

2

1 -n o

¢2knol no+n

/ e

R =

(4.4)

,

1 +

e ~2kno 1 I +no

no+n*

where n o = W ~oI' n = (nln2 + ~ol)/(nl + n2)' ~o1 is the background dielectric constant for light with Eic, k is the wave vector of the exciton,

i is the depth of the dead layer,

and n 1

and n 2 are the refractive indices of the transverse waves. For the computer

calculations

the

values of the parameters:

authors

of

[19]

used

the

following

the longitudinal - transverse splitting

~LT = 2 meV, Eoi = 8.3, M = 0.9 m O, and 0~0 = 2.5524 eV. The DL depth 1 was varied from 0 to 1000~ and the damping F from 0 to 1 meV.

Fig.

7

shows

the

calculated

reflectance

spectra

for

a

negligible increase of l, with ~F = 10 -5 eV corresponding to that value

of

experiment at ~L

the

damping

which

(see below).

yields

Note,

the

(the spike) appears at 1 ~ 60~,

2Rex c. At

layer values

best

agreement

with

that a subsidiary reflectance

1 > 150~ and

peak

i.e. at the value close to small

rtF ( < 10 -4 eV)

results were found to be close to the data of

the

[18] shown in Fig.

6. The inversion of the ERL occurs at 1 ~ 200~, and the return to the initial lineshape at 1 ~ 850~. The results make it possible to estimate

the

values

of

1

and

I~.

A

comparison

between

these

calculations and experiment will be done in Sect. 4B. Alterations of the DL depth observed to occur under application of the external

field,

surface-sensitive

keV-electron techniques

will

irradiation be

shown

to

and result

other from

the

Excitons at Semiconductor Sudaces

197

changes in the near-surface electric field value and also from the emergence of the defect-rich near-surface layer, which is evidenced by the studies of low-temperature exciton photoluminescence spectra and, in particular, of their modification under electron irradiation (Sect. 5B).

I

0.6

0.¢

•

~'\

0.~

Fig. 7. Calculated ERLs for the A (n=1) exciton in CdS as a function of the DL depth 1

Note,

on

the other hand,

that

the outlined model

suggests

a

completely transparent homogeneous DL, though it is evident that field-induced changes in the value of the exciton damping P should be taken into account. Large values of P yield an exciton-free layer which, in fact, is responsible for the observed alterations of the lineshapes under electric field. It is also evident that the layer can not be derived straightforward from the DL in the spirit of Hopfield and Thomas [12] by merely increasing i since the latter is of intrinsic origin and is due to increase in ~0 but not in r as in the former case. On the other hand, it is clear that the exoiton-free layer caused by the abrupt increase in the damping value should likewise result in the rotation of the ERL

198

A.E. Cherednichenko and V.A. Kiselev

when 1

is varied.

Sect.

6 where

field

is

This

allowance

made.

The

issue for

latter

shall the

be

considered at

inhomogeneous

brings

about

the

length

character of diffusion

of

in the the

boundary of the exciton-free layer which may be so strong that the ERL rotation will not proceed at all. In what follows it will be shown that the electric field may lead to localization of excitons near a semiconductor surface.

B. The

effect

of

keV-electron

irradiation

on

exciton

reflectance spectra The

exciton

reflectance

spectra

of

semiconductors

with

the

direct allowed transitions appear to be drastically influenced by the surface. The ERLs are markedly affected by the surface states, near-surface defects, and, especially, electric fields. It is well kwown that strong variations in the lineshapes can be found among different materials and, in a given material, among various levels of the hydrogen-like excitonic series. Quite often, a given line may

look

rather

different

semiconductor material.

from

This

sample

is

true,

to

sample

of

in particular,

the

same

of A2B 6 -

compounds in which the ERLs may vary depending on the conditions for crystal growth and generally uncontrollable surface conditions in a given specimen. The for

electron bombardment chapping

the

(EB) has proved a suitable

reflectance

spectra.

In

discussed in this section keV-electrons were

the

technique

experiments

taken advantage of

(the penetration depth into the material being of a few hundreds of ~ngstroms).

The

(CdS [19,21], CdSe oil-free

vacuum

experiments [22], ZnSe

using

the

were

performed

on A2B 6

crystals

[23]). The EB was performed in an cryostat

permitting

optical

and

electrical measurements at 4.2K. Irradiation-induced changes in the exciton spectra vs electron fluence were registered ~ s~tU without warm up. Near-to-normal-incidence reflectance spectra were measured from a plane containing the C-axis for light polarized both parallel and perpendicular to it. By the effect on the ERL

Excitons at Semiconductor Sudace$

199

the electron irradiation can be classified into a low-dose (1013-1015) e/cm 2 and a high-dose (9 1016) e/om 2 one. The low-dose EB produced reversible changes in the ERL which are discussed below. Fig. 8 shows the changes of the exciton reflectance spectra of a 0dS crystal for the An= I- exciton that occurred under low-fluence electron irradiation with 3 keV electrons. The as-grown crystal is seen to reveal the right-spike structure (curve I), whereas after EB the left-spike structure appears instead (curve 2). (Note that the left spike is the reflectance peak at ~L which is situated to the left from the reflectance minimum (also see Fig. 7). Further exposure to electrons results in a reversal ("rotation") of the ERL.

R

a~ a~ ?i 8. 8. Experimental exciton reflectance spectra of CdS at T=4.2K vs 3-keV electron irradiation dose (a low-fluence case).

0,I

200

A.E. Cherednichenko and V.A. Kiselev

R

A

O_

Ill,

0.2! 0

8"=1

,

I

,

,

,

2 I

~1

I

I

I

I

I

~o wl.

2.550

2.570

2.650

2.570

E,eV

Fig. 9. Experimental exciton reflectance spectra of CdS at T=4.2K vs electron irraditaion dose [19].

Figure 9 shows the modification of the exciton reflectance

for

the An= 1-, Bn= 1-, and An= 2- excitons in CdS [19]. (Note that according to the sketch of the energy bands presented in Fig. 2 along with the An= I- excitons, a more short-wavelength structure associated with the B-band and excited states of the excitons may arise). The initial ERL of the An=1-exoiton also features the

ExcilOnsat Semiconductor Surfaces

~,n'rn 680.0 6"/8.0 676.0 67#.0

A..I

670.0 668.0

201

666.0

8n=2

O#

An=2 O~ 0.2!

0.31-

Ill

A.

0.~

0.~ b, 0.2

4 1+?00 1#'/~ f#?80 ¢ t#820

1#900 ~ I#9#0" 1#g80 0251

Pig. 10. Experimental ERL of 0dSe vs dose of EB [22].

202

AE. Cherednichenko and V.A. Kiselev

right-spike structure whereas following low-fluenoe electron irradiation the left spike appears. This is accompanied by the enhancement oZ the main reflectance maximum. Similar effects are readily revealed in the spectra of 0dSe crystals

(Fig. 10, curve

2). It is pertinent to note that these findings are peculiar of the A-exciton. The low-fluence EB has only a slight effect on the B-exciton (compare curves I and 2). The reason for this difference is discussed in Sect. 6). The analysis of the exciton reflectance in CdS was performed in [19] using the DL model (see Sect. 4A). As seen from Fig. 9 the initial spectrum features the coefficient at the main maximum

right spike, the reflectivity is 0.42. A comparison with the

calculated spectra yields for the Afl=S-exciton a DL value liA SO~. After a low-dose EB (curve 2) the right spike is converted to the left one and the main reflectivity maximum is markedly increased spectra

(by approximately

O.1).

According

to

the

theoretical

(Fig. 7), the ERL in this case corresponds to a DL liA

60~, which is close to the intrinsic DL thickness (~2Rex c) in this compound. This was the smallest DL thickness that the authors could obtain experimentally in CdS (for CdSe, see Sect. 4C). With further increase in the EB dose, the ERL tends to return to the initial state (curve 3), i.e., the depth of the DL begins to increase. Curves 4 and 5 reveal a gradual "rotation" for all of the exciton resonances indicating that

of the ERL the DL is

increased. A comparison with the theoretical spectra yields liA 160~, ~ = 10 -4 eV and lIA ~ 200~, and ~ = 5-10 -4 eV for curves 4 and 5, respectively. With increasing electron

irradiation

dose

the

spike

evolves

towards a maximum and the ERL has an inverted appearance (see ctu~ve 5 in Fig. 9, curve 4 in Fig. 10). Note that curve 6 in Fig. 9 agrees in shape with the initial spectrtum (which corresponds to a phase shift of about 2~, see Fig. 6) though the reflectivity is markedly damped. This implies that the high-fluence EB increases both the DL depth and the value of the damping (~U ~ 5.10-4eV). It appears that the boundary between the DL and the crystal bulk can no longer be represented by a plane which results in an additional

Excitons at Semiconductor Surfaces

smearing

of

the

spectrum.

(Note,

that

the

203

shortcomings

of

the

DL-model have been touched upon at the end of Sect. 4A and will be considered

in

what

follows).

The

changes

in

the

reflectance

induced by the EB persisted for hours provided the sample was not heated.

Annealing

of

a

moderately

irradiated

sample

at

room

temperature with an exposure to air usually recovers the initial lineshapes.

The authors of

[19,221 concluded that the effect of

the EB was reversible. Following high-dose EB, when the total dose reached 1018 or more an overall decrease of the exciton structure was revealed. This effect was partially reversible. An incomplete of

the

high-fluence

recovery

EB

spectrum which

was was

observed

following

assumed

to

be

the

repeated

due

to

the

subthreshold-irradiation-induced defect creation. Similar reversal of

the

ERL

under

EB

was

observed

for

the

excited

states

of

excitons each featuring its characteristic phase of rotation. The analysis of the ERL and its modification under EB in CdS single

crystals

has

been

performed

by

Benemanskaya

et

al.[19]

within the framework of the DL-model (Sect. 4A) with low values of the exciton damping F, spatial dispersion having been taken into account.

The experimental

lineshapes were

compared with

the the

calculated ones. The changes of the spectra under low-fluenoe EB were interpreted as a result of a decrease of the DL depth to the value of about

60 ~

(Fig. 9, curve 2) which

is

typical of

the

intrinsic DL with the ERL featuring the left spike.

It is evident

that

the

reversible

reflectance

and

spectra

irreversible

are

of

changes

different

of

origin.

The

exciton

former

are

associated with oxygen desorption and recharging of surface and near-surface

centers under low-fluence EB resulting in the band

bending decrease. In the initial state there occurs at the surface of the CdS crystal a field corresponding to

the depletion.

The

transition I ~ 2 is corresponds to the decrease of the electric field,

which

takes

place,

apparently,

as

a

result

of

the

electon-irradiation-induced oxygen desorption (direct evidence of the band bending

decrease under low-dose EB has been obtained in

[22] for the case of 0dSe crystals). This means that curve 2, on the DL model, corresponds to an "ideal" surface, when the DL is

204

A.E. Cherednichenko and V.A. Kiselev

equal to the intrinsic DL of Thomas and Hopfield. No such state, however,

was observed on natural

crystal surfaces.

with further increasing of the EB dose an

appearance

of

the

initial

ERL.

We note

that

(see curve 3) the ERL has

Only

then

corresponding to an increase in 1 relative

do

the

changes

to the initial value

occur in the ERL (see curves 4,5). Thus, successive effect of the EB

is first

depth.

The

to reduce

and

then,

latter case p~oceeds

gradually,

to

from either

increses

the

the DL

electric

field

increase or, as it will be shown in Sect. 5, from the formation of the defect-rich near-surface layers. The increase in the amount of irradiation results

leads

in

the

to

the

storage

modification

of

of

the

the

electric ERL.

field

Note,

which

that

the

experimental data on the effect produced by EB on the ERL of CdS crystals result

of

at

SOK

the

reported by

Ratsch

[24] were

electron-beam-induced filling

interpreted as of

surface

a

states

with electrons from the bulk, producing a negative surface charge and a depletion layer below the surface. Thus,

that part of the

effect is reversible which is due to the inhomogeneous field and Franz-Keldysh effect at the surface

(Sect.

6). Annealing at room

temperature in atmosphere surroundings recovers the spectra. The irreversible decrease of the exciton reflectance following a repeated

high-dose

long-lived defects,

EB,

is

e.g.,

more complex defects

predominantly

sulfur

(see Sect.

associated

with

the

(selenium) vacancies Vs(Vse)

or

5.E). To account for the overall

decrease of the reflectance resulting from the repeated high-dose electron

irradiation

the

authors

oZ

[19]

had

to

use

in

calculations of the reflectance a somewhat enlarged value for the bulk

damping

near-surface

parameter layer

is

r.

The

formation

evidenced

by

of

the

the

defect-rich

analysis

of

the

the

main

photoluminescence spectra (see Sect. 5E). Additional

features

on

the

long-wavelength

reflectivity maximum may be observed

side

of

(see, Figs 9,10). The lines

labelled I s and I se appear to be very sensitive to the EB. These features are also revealed in the photoluminesoenoe

spectra and

will be discussed below. In conclusion we wish to point out that the DL-model with hard

Excitons at Semiconductor Surfaces

205

edges enables a qualitative description of the features in the ERL under EB. A more adequate description which makes allowance for the effect of the inhomogeneous electric field on the exciton resulting in its field dissociation and quasilooalization at the surface will be given in Sect. 6. Still that seems to be only an approximate model,

since

the electron irradiation has a complex

effect on semiconductors and a non-trivial electron energy loss distribution should result in complicated field and defect distributions in irradiated specimens.

O. Interpretational problems As noted, Hopfield and Thomas [12] were the first to introduce a near-surface exciton dead-layer (DL) model. The original variant of the DL, namely, the one with hard edges could explain several features in the exoiton reflectance lineshapes (ERLs). Starting from mid-1970s much effort was given to investigation of surface aspects of the exciton behavior in semiconductors with a particular emphasis on the study of the ERL in various semiconductor crystals. The spectra were explored under application of the electric field, following etching, electron and ion irradiation, additional illumination. Studies of the ERLs and their alterations under various external stimuli revealed several important features. Some of them, such as the occurrence of a maximum at the frequency corresponding to the longitudinal exciton ~L (the so-called spike) and its spectral stability have been interpreted within the framework of the intrinsic DL model whereas a reversal of the ERL has been explained within the extrinsic DL with a varying depth [18] (see, Sect. 4A). The extrinsic DL observed to occur in A3B5-compounds has been treated in [17,25] as arising due to the exoiton ionization in nea~-surfaoe electric fields. This issue as applied to A2B6-compounds shall be discussed in detail in Sect. 6. It appeared, however, that a number of experimental data could not be understood within the DL-model: the occurrence of the

206

A.E. Cherednichenko and V.A. Kiselev

"left"

spike

pulsation,

(see Sect.

stretching

multy-spike

4B), of

structure

exciton reflectance

the

ERL

(see Sect.

accounted for by the DL-model. the

attention

to

those

along

6).

enhancement

the

These

frequency

features

and

scale,

can not

be

The aim of this section is to draw

features

in

the

ERLs

of

CdS

and

CdSe

crystals that are anomalous from a traditional point of view. A marked sensitivity of the excitonic spectra to various surface treatments

indicate

that

physical

conditions

at

a

semiconductor

surface dominate the ERLs. Possible mechanisms of the influence of a

surface

on

excitons

are

discussed

in Sect.

5C.

A

comparison

between the calculated ERLs and experiment allows in some cases to gain

information

about

near-surface

exciton

transition

layers

(ETLs),- see Sect. 4E. Several

authors

Patella et al. with

the

definite

attention

to

the

anomalies

in

the

ERLs.

[15] compared the experimental ERLs in CdS crystals

theoretical choice

experiment Close

paid

ones

between

for the

different ABCs

DL-depths

was

made.

The

and

ABCs.

fit

with

No the

was rather poor for the large values of the DL-depth.

correlation

between

the

magnitude

of

the

spike

and

the

magnitude of the main reflectivity peak Rma x has not been revealed which is at variance with the DL-model. calculated

ERLs

and

experimental

ones

Discrepancies were

also

between the

pointed

out

by

Brozer et a1.[26]. Of

particular

interest

is

indicated by several

authors.

of

only

a homogeneous

damping ~ ,

DL

for

a

complex

The left spike arises very

(see, e.g.,

small

values

with minimal

the intrinsic DL

spike

in the model

of

the

exciton

values

(1 ~ 2Rexc).

of

in CdS crystals could only be the DL depths

or more

only

the

structure

right could

equal to zero [22]. Hence,

spike be

corresponding

For the CdSe crystal

DL should be about 10 nm [28], but, as Fig. left-spike

a

[12,27]). The left-spike ERL (Figs. 7,8)

observed by Benemanskaya et al.[19]

nm

of

about lO-5eV, which is too low a value relative to the

commonly used revealed

structure

is

11 shows,

available,

obtained

for

1

for DL of 5

though ~

to

the intrinsic

4 nm

a

slight

setting

F

the left-spike ERL in CdSe crystals can

not be reproduced within the frames of the homogeneous DL model.

Excitons at SemiconductorSudaces

207

0.2

Wo

wL

Fig. 11. Calculated ERLs for the A(n=1 ) exciton in OdSe as a function of the DL depth i. 1,nm: (I)- O; (2)- 4; (3)- 11; (4)- 15; (5)- 30. P = O. Fig. 12 shows the fine structure of the spike observed in the exciton reflectance of OdSe at T=4.2K by Batyrev et al. [29]. The spike consists of the two maxima near ~L; a more complicated structure was reported by Davydova et al.[30] on OdSe crystals with "shifted" exoiton spectra (Fig. 13). In Sect. 5D we shall discuss the nature of the shifted exoiton spectra in CdSe crystals and give comparison between the experimental and calculated lineshapes. In addition to the anomalies in the region of ~L' 0dS and CdSe crystals show various features on the long-wavelength side of the main reflectance maximum (see, e.g., Figs. 9,10). Prominent features seen in the figures result from exoiton localization at the surface (near-surface) centers which is also evidenced by the studies of the photoluminesoenoe spectra (see Sect. 5).

208

A.E. Cherednichenko and V.A. Kiselev

0.5

/

O,4 {z

O.3

/ 0.2

R 0.4

0.1

0.3

-0

/, b

Fig. 12. Experimental exciton reflectance spectra in the vicinity of the A (n=1) exciton in OdSe at T=4.2K [29]. (a)- initial spectrum; (b) - after a 3-keV low - fluence electron irradiation A complex structure o f the spike is seen.

0.1~

o.1

0

!

i

!

~t700 14720 74740

4

It is pertinent to note that exciton spectra are measured at low temperatures where the exciton damping due to temperature is insignificant. With temperature rise, one should expect a spectral shift, line broadening, and other temperature effects. As for the EP~L, a number of authors (see, e.g.,[23]) reported a reversal of the lineshape upon heating from T=4.2K to 77K which has been ascribed to a thermally induced increase in the DL depth value.

Excitonsat SemiconductorSurfaces

209

R ¢u~. un,.

Fig. 13. Experimental exoiton reflectance spectra in the vicinity of the A (n=1) exoiton in CdSe at T=4.2K [30].

I 682.0

R,, n m I 678.0

I

F, rt~V

I

~

t

0,8

t tA 0.*

"

/~°'2"' / I" /.I/.,.,'-~ the ERL of OdS vs temperature [27]. A solid curve represents a theoretical dependence on I~.

/RmLn'°l°

t

O.a

8or, K

210

A.E. Cherednichenko and V.A. Kiselev

Pevtsov et ai.[27] studied the exciton reflectance in CdS single crystals in the temperature range 2K
the

reflectivity

signal

were

observed,

especially

spectral region of a minimal reflectivity value 2 m n i The magnitude of the minimal reflectivity R m n i zero at T ~ 3OK increased. model

of

To

(plane " R mni

account

for

the

dropped to nearly

- T") and afterwards monotonically

this

Hopfield-Thomas

in

(Fig. 14).

[12]

observation has

been

the

homogeneous

utilized.

A

DL

distinct

step-wise change in the reflected wave phase by 2~ at about 3OK [31] allowed to ascribe this finding to the Brewster effect 0). Note,

(R =

that the values of the exciton damping r derived from

the experiments were

two orders

of magnitude

as large as those

obtained with making allowance for the exciton-phonon scattering. In Sect. 6 an alternative explanation for the observed anomalous effect is suggested. Permogorov et al.

[32] examined the exciton reflectance spectra

of CdS

crystals which

random

illumination

induced

the

spike

temperature for

a

initially revealed no

of in

a

sample

the

long

at

liquid

spectrum,

which

period

of

time

spike

structure.

helium

temperature

persisted

The

A

at

occurrence

this

of

the

illumination-induced spike has been ascribed as due to initiation or alteration of the SCL. Profound changes in the ERLs of several CdS samples have been reported

in

[33]

following

illumination

with

k

~

51OO~.

Preliminary illumination of a sample was performed at T = 4 . 2 K u s i n g a 250W halogen lamp. The light beam passed through a monochromator and

a

heat

filter.

ERLs

were

taken

with

increasing

amount

of

illumination (time of illumination). The intensity of the probing light was low enough not to affect the ERL. A pattern of

illumination-induced changes of

the lineshape of

the An=1-exoiton is given in Fig. 15 for a number of expositions (in minutes).

Initial spectrum is seen to have no peculiarities,

whereas after exposure to a 5-min illumination an enhancement of the

reflectance

exposition

time

was

revealed.

the

marked

With

changes

further in

the

increase

of

the

magnitude

of

the

reflectance as well as in the lineshape were observed and at the

Excitons at Semiconductor Surfaces

same

time

the

left

spike

appeared.

As

a

211

result

of

a

30-min

exposure a reversal of the ERL to the initial shape was observed. Alterations

of

the ERLs

with

increasing amount

of

illumination

will be discussed at some length in Sect. 6.

R

0.4

20

30m£~

O.Z

Fig. 15. Evolution of ERL of OdS with illumination time. T=4.2K.

D. Interference effects in thin

crystals.

Size

quantization

of excitons The

discussions

in

the

previous

sections

have

indicated

the

usefulness of the refleotivity measurements in bulk crystals for estimation of the magnitudes of the dead layer the

interference

features

(DL) which govern

in the exciton reflectance

lineshapes

212

A.E. Cherednichenko and V.A. Kiselev

(ERLs). This section shortly discusses a more complicated case of interference

features observed

to occur

in the vicinity of

the

exciton resonance transition in thin crystals. An important contribution to the exciton optical response comes from the so-called additional or anomalous waves

(AWs)

[6,12]. We

note, that inherent in the concept of AW's is the problem of the additional boundary conditions (ABO's) which was discussed at some length in Sect. been

3. The

demonstrated

by

existence

a

number

of additional of

light waves has

techniques

(see.

e.g.,

the

reviews [34,35]). The direct verification of the theory of the AW has been performed by Kiselev et al. experimental

and

theoretical

[36-38] as a result of the

studies

of

the

reflectivity

and

transmission in thin CdS and 0dSe crystals. The

computer and experimental results

for the reflectivity

in

the neighborhood of exciton A in a CdS platelet 0.34~ thick are compared in Fig. for

the

16. For

two-wave

the calculations,

interference

in

a

Pekar's

slab

were

formulas

used.

[8]

The

ABC

employed was that of Pekar eliminating the exeiton polarization at the boundaries of the medium. The computation involved a set of parameters common for different thicknesses but different damping terms.

The

calculations

following

the

ABC

scheme

enabled

authors to reproduce the essential features of the spectra, the side

one-period Fabri-Perot and

the

two-period

high-energy side of ~L" Fig. 16 shows that on interference

feature

(FP) (FP

interference plus

AW)

the low-energy

can

be

observed.

on

the

the ~z.

low-energy

interference

on

the

side of e L a distinct This

is

due

to

the

FP

interference of excitons from the lower polariton branch (see Fig. 3c).

On

the high-energy

side

of ~L

two

series

of

interference

peaks occcur. The first one corresponds to the FP interference of exciton polaritons from the upper branch; the peaks in this series are well separated. Another series superimposed on the first one consists

of much

closer

spaced peaks

and

is due

to

the mutual

interference of exciton polaritons from both of the branches. Thus, optical

the

AWs

spectra

produce of

thin

several crystal

interesting platelets.

features The

in

the

interference

Excitons at SemiconductorSudaces

213

structureadditional to the one that should be observed with M = is a direct proof of the fact that the AWs do exist. Studies of interference due to AWs provide evidence for proximity of the ABO to

that

of Pekar

for

low-energy

waves arise as a result of

exeitons

[37,38].

Additional

excitation of polaritons. Nonetheless,

it seems also useful to consider the problem within the mechanical approximation [39]. The mechanical exciton is depicted by (3.1) at E=O.

In

the

case

of

a

plane-parallel

conditions should be imposed (e.g., boundaries

platelet

the

boundary

the Pekar's ABO P=O) on both

(let them be z = 0 and z = a). In other words, a thin

plane-parallel semiconductor platelet constitutes a quantum well for excitons which is approximated by a rectangular potential well with

infinitely high

walls.

It

is

evident

that

the mechanical

exciton band (3.4) is size-quantized in the direction z normal to the crystal plane and the solutions of (3.1) along z would depend on z as

sin(N%z/a), where N = I, 2, 3 ....

part

Pig.

of

17

rectangular well

which

corresponds

is shown with

to

In the right - hand

real

values

of

k=k z

a

the levels spaced by the values

(P~V~/a)2/(2M) as referred to the bottom of the well. These levels are

represented

on

the

mechauical

exciton

dispersion

(dashed

curve) by points, or, more strictly, the levels and corresponding points indicate the bottoms of the 2D subbands in the x,y - plane. A much more complicated problem arises when the exciton - photon coupling is

to be

taken into account

[39] as

in the case when

transmission and reflection coefficients of a crystal platelet are to be derived (see Fig. 16). The exciton levels in a rectangular well can be shown [39] to govern the interference structure which is

the

result

of

both

the

FP

interference

within

the

entire

frequency range explored and the interference between the AWs for ~ ~L" A theoretical account of the size quantization of excitons fits fairly well the features of the experimental spectrum 16).

In

what

follows,

we

shall

discuss

the

(Pig.

long-wavelength

structure at ~ < ~L which is due to the exciton localization in a quantum well. We note, that the levels of the mechanical excitons in the well do not coincide with corresponding features optical specti~m [40].

in the

214

A.E. Cherednichenko and V.A. Kiselev

Rtheo,

Rez~r

- 0.6

0.# 0.6 0.2 0.4 0 0.2 0

486.4

486.0

#85.2

485.6

#84.8

~8~. ~ A, , n m

Fig. 16. Reflectivity from a CdS crystal (0.34 ~un thick) in the region of the A(n=1) exciton. The upper curve is experimental (in arbitrary units) taken at T=I.6K, the lower curve is theoretical.

I

O" z~'Ct ~z

z =O

k--link

k=Rek

Fig. 17. Schematic representation of the optical response of excitons localized in: rectangulsr well ( a ) ; surface 6-potential (b).

Excitons at Semiconductor surfaces

215

This observation is accounted for by Fig. 17. The points in Pig. 17a [40] o o ~ e s p o n d to mechanical exoitons and the arrows give the positions of the expected features in the optical spectrum. Such a spectral shift arising due to the polariton effect enables the observation of the exoiton quantization in much thicker platelets than in those where quantization of carriers, i.e., of electrons and/or holes is possible.

E. Exoiton transition layers and a formal model In sections

4A and 4B we have

demonstrated

that

the simplest

model to calculate the ERL is that of the exoiton-free layer, supplemented by the ABO (usually of the Pekar's type). Yet, there exists evidence that more sophisticated descriptions of the excitonic optical response need to be incorporated. In factj we should also consider more complicated models of the near-surface transition layers and, consequently, of the exoiton transition layers (ETLs). The ETL may be of intrinsic or extrinsic origin. Intrinsic mechanisms are those stemming from the internal structure of excitons and are due to (i) the interaction of electrons and holes with their mirror images at the semiconductor surface

(see Sect. 4A) and (ii) the effect of the surface-induced

confinement

of

the

electron

and

hole

motions.

A

number

of

theorists (see, e.g., [12,16,41-47]) considered the details of intrinsic mechanisms of formation of the intrinsic ETL. They found that the mechanisms yield the exoiton-free layer of about ~Rex c. Extrinsic ETLs for excitons arise due to external, with respect to excitons, mechanisms and they are motivated by various surface (near-surface) imperfections (see Sect. 5) including the electric field (see Sect. 6). (Note, that, contr-ary to the intrinsic ETL, the extrinsic one may have macroscopic dimensions, well exceeding the exciton wavelength ~/nex o ~ 102nm). Theoretical aspects of the perturbation of exciton states near the surface were discussed in a number of papers (see, e.g., [48-54]). Most drastically excitons are perturbed by the electric field of the SOL. This issue will be

216

A.E, Cherednichenko and V.A. Kiselev

discussed in detail in Sect. 6. Whatever the origin of the ETL may be, the ERL can be calculated by formally introducing a near-surface potential for excitons. A method of calculating the exoiton reflectance in the case of an arbitrary potential has been put forward by Kiselev [55]. Assuming that the adiabatic approximation (see, e.g., [42]) holds, the elastic scattering of an exciton by a considered. A smooth adiabatic potential

surface potential was was approximated by a

step curve. The limitations on the size of the steps were as follows: the height of the step is small compared with the energy of the exciton being scattered or the width small compared with the exciton wavelength. On the other hand, the number of steps must

be

finite.

The

problem

is

thus reduced

to the problem

of

calculating the optical response of a layered medium where the potential is not dependent, within each layer, on the coordinate which enables the usage of the crystal optics of a thin slab with spatial dispersion [6,8]. Note, that it is also possible to formulate

the problem within the mechanical

exciton quantization

approximation [39,40]. Principally, one should arrive at the same results insofaras the phenomenology of the layered medium takes into account

both the above-barrier

[39] and below-barrier

[40]

solutions for the mechanical exciton. A number of different model potentials V(z) are presented in the left-hand part of Fig. 18 (see curves 1-17). The results of calculations of the reflectivity R are shown against corresponding numbers on the right. The spectra were calculated for the A(n=1) exoiton [12,18] in OdS (curves 1-16) and OdSe [37] (cuzwe 17). The analysis of the calculated spectra shows that the reversal of the ERL results from the effect of the repulsive potential experienced by longwavelength exoitons with kinetic energies from within the interval of 0 - h~LT. The reversal is exemplified by oases 1,3, and 5 for the potentials in the form of the steps of different widths. Note, that the height of the step (see 2-4) does not affect the reversal. The reversal is seen to occur also for the potentials featuring tails (6-8) and for the linear potential

(9,10).

Exc#ons at Semiconductor Surfaces

217

¢~,,6z|

Tig. 18. A number of potential s V and re 1 evant calculated refleotivity coefficients R in the vicinity of the A(n=l) exciton in OdS (I-16) and OdBe

{~7).

i~

~Y

Y]:., "-'-""

I Z

0,2

218

A.E. Cherednichenko and V.A. Kiselev

Inspection of curves 2-4 shows that the spike (in the spirit of Hopfield and Thomas [12]) occurs only for a sufficiently high step. In other words, the potential must have a hard core which is inpermeable

even for the high-energy excitons

is enough transparent to the light wave). The spike, however, appears for curves

(the surface layer

11-16

which

represent

near-surface potential wells for excitons. By insignificantly varying the depth and shape of the well (11-13) prominent spikes can be observed. Curves 14-16 show the optical response of the surface mechanical exoiton, i.e., the exoiton having the bound state in a fairly deep well. The spectra are seen to reveal the additional maximum which shifts to longer wavelengths with increasing binding energy (for the details, see [40]). The outlined method for calculating the exciton optical response has been applied by Kiselev

[56] to the Shottky barrier case at

low temperatures which is considered in detail in Sect. 6. To conclude, we note, that when finding the exoiton optical response one solves the direct problem of the exciton scattering only. The inverse problem, as is well-known, can not be solved uniquely, that is, only a family of potentials can be found. An appropriate potential can be chosen proceeding from physical mechanisms and from comparison between the calculated exciton reflectance spectra and experimental ones.

5. Crystal Defects and Localization of Exoitons A. Bound excitons Exeitons have a tendency

to forfn bound exciton complexes with

defects and these are also 0teated by the optical excitation of the crystals. This section describes shortly the properties of the bound W a n n i e ~ M o t t excitons. Lampert [57] pointed out the analogy between the hydrogen molecule and an exciton interacting with a shallow neutral donor (aoceptor) which can, like the exciton, be described by the hydrogenic model, Just as the hydrogen atoms bind

Excitons at Semiconductor Surfaces

219

to each other in the H 2 molecule, so should the exciton be bound to the neutral impurity. Since a bound exciton complex is made up of an impurity atom (or lattice defect) to which an intrinsic (free) exciton is bound and since the intrinsic exciton is a property of the crystalline host lattice, a question naturally arises concerning the relative intensities of absorption lines that derive from these two types of excitons. This is especially so when the bound exciton lines are observed to be nearly as intense as the intrinsic exciton lines, a frequent observation in both the absorption - compounds. The

theory

of

and

"impurity"

reflectivity or

defect

spectra

absorption

of

the

A2B 6

intensities

in

semiconductors has been developed by Rashba [58]. He found that if the absorption transition is direct and if the discrete level associated with the impurity approaches the conduction band, the intensity of the absorption line increases. The explanation offered for this intensity behavior is that the optical exoitatign is not localized in the impurity but encompasses a number of neighboring lattice points of the host crystal. Hence, in the absorption process, light is absorbed by the entire region of the crystal consisting of the impurity and its surroundings. As a result of an attack on the particular problem of excitons which are weakly bound to localized impurities , Rashba and Gurgenishvily [ 5 9 ] derived the following relation between the oscillator strength of the bound exciton ~ and the oscillator strength of the intrinsic exciton ~exc' using the effective-mass approximation Ig = (Eo/IEgll3/2~exo where

E0 =

(2~2/m)

(%/00)2/3,

Eg

is

the binding

(5.1) energy of

the

exoiton to the impurity, m is the effective mass of the intrinsic exoiton, and ~0 is the volume of the unit cell. Note, that the value of ~ , when substituting the parameters for the bound exoiton lines derived experimentally, may exceed ~exc by more than four orders of magnitude (the effect of the "giant" oscillator

220

strength).

A.E. Cherednichenko and V.A. Kiselev

Assuming

that

the

line

intensities

are

equal

to

a

simple product of density and oscillator strength (In ~ Nd'f~) and assuming an impurity concentration of N d ~1017cm-3~and intrisic exciton concentration of Nexc ~ 1022 one arrives at the conclusion that bound exciton intensities can be within an order of magnitude of those of the intrinsic exoiton lines, hence, they are observable in transmission and reflectance. We note, that the bound exoiton dominate the emission spectra. The emission results from the

disintegration

(radiative decay)

complexes

and

the

occurs

on

of the bound exoiton

long-wavelength

side

of

the

free

exciton transition as narrow (having half-widths of ~10-4eV) lines yielding information on the associated defects. Another important conclusion which can be drawn from equation (5.1) is that, as the intrinsic exciton becomes more tightly bound to the associated center, the oscillator strength (and, hence, the intensity of the exoiton-complex line should decrease and u~ce versa). The extensive studies of Thomas and Hopfield [60] on CdS have resulted in the development of a theory of bound exoitons. The theory is based on the band symmetry properties associated with the wurtzite structure of this compound. Several bound exciton complexes are postulated and observed experimentally. These are the exoitons bound to neutral and ionized donors. The transitions were designated as 12 and 13, respectively. The exoitons bound to neutral aooeptors, designated as 11 are also observed.

B. The effect of

keV- electron

irradiation

on

the

exciton

photoluminescenoe spectra Exciton photoluminesoence spectra are also dependent upon surface conditions of a sample. This section briefly reviews the effect on the exoiton photoluminesoenoe spectra of the electron irradiation of OdS and OdSe crystals [61,62]. Irradiation induced changes in the spectra were registered ~n s~tu at 4.2K as a function of fluenoe (or dose) of incident keV-electrons. Figure 19 shows the dependences on the irradiation dose [62]

Excitonsat SemiconductorSurfaces

I

221

ziO 20 10

1

,6~.

F~.

19. Intensities

o~

the emission lines in OdS at T=4.2K vs eleotron dose. 1- I2B; 2- I2A; 3- 11; 4- A(n=l); 5- 13 .

~'~

~+.,.--o-----I~. _+,+Z~"

-~2

~ ~~i~e.~.e..~e~ 0.6F\5

e

~i

0 0.5

4

~e~3

40 50 6O 70 8O

T

.............Iz

Pig. 20. Transmission speotra in the region of the 12bound exoiton in 0dSe exposed to inoreasing doses of 3.5 keV electron irradiation. 1initial speotrum; 2 - after 2"1015e/om2; 3- 8"1017e/om2.

681.0 ' 680.5

6B0.0

679.5 ~,,rmt

222

A.E. Cherednichenko and V.A. Kiselev

of various exciton emission lines typical ¢f CdS. With low-fluence irradiation (D ~ 1015 e/cm 2) an overall increase in the luminescence intensity was observed for the I2A-, I2B-,

Ii-, 13-

bound exciton emission lines and for the An= I- exciton emission line

as

well.

crystals

Similar

changes

occurring

seemingly results,

dose

dependences

were

found

for

0dSe

[61]. These findings indicate that the exciton emission due in

to

under a

low-fluence

surface

particular,

exoiton non-radiative

band

in

the

escape

electron

bending

irradiation

decrease.

decrease

of

probability.

a

The

The

are

latter

field-dependent in

the

amount of band bending is also evidenced by our studies of

the

reflectance spectra and surface photovoltage

reduction

[22]. Note, that the

transmission in the region of the I2-bound exciton line in OdSe crystals

shown

insignificantly,

in

Fig.

hence,

20

(curve

[61]

2)

the low-fluence EB

is

does not

changed

practically

produce defects. This conclusion is also supported by a reversible character of the exciton spectra changes. After electron irradiation to a fluence of above 1016 e/cm 2 the emission

lines

intensities

show

different

behavior

(Fig.

19),

which is indicative of their different origin. The most pronounced increase, about 1.5 order of magnitude, was observed to occur for the I2-1ines corresponding to excitons bound to neutral donors. A corresponding

increase

absorption

the

in

is

region

observed of

for

these

486.1-487.1

nm.

lines The

in

CdS

electron

in

beam

induced enhancement of the I2-feature in CdSe is seen in Fig. 20. These observations

indicate an increase

in the

intrinsic defect

(neutral donor) content in the near-surface region after EB. Figure 19 shows a sharp

drop

in the intensity of

the I3-1ine

(the Is-line, see below) which is due to the exciton bound to the charged

(ionized) donor. The anticorrelation between the 12- and

13- line behavior (also see [60,63,64]) and a reversible character of the changes show that a neutralization of ionized donors occurs under EB. At the same time the intensity of the It-line, which is due to the exciton, bound to a neutral acceptor is less dependent on the dose,

probably

because

a

major

part

of

acceptors

in

n-type

Excitons at Semiconductor Surfaces

223

semiconductors is charged and, hence, not influenced by EB. With increasing irradiation dose the effects due to long-lived defects become dominant which is evidenced by an overall bound exciton emission intensity drop (Fig. 19), an increase in the absorption in the region of the I2-I2"-lines (Fig. 20), the emergence of the electron irradiation induced Ie-lines (see below). Electron irradiation as well as other treatments were found to strongly affect the broad-line structure observed to occur in CdS crystals in the spectral range of 486.1-486.5nm. Initially this feature has been ascribed to the emission of the exciton bound to the ionized donor (the so-called 13- line). The reason for this assignment was the observed anticorrelation between the intensities of the 12 - and 13-1ines. Typical of this feature is its dependence on surface-sensitive electron irradiation, excitation light intensity. This surface-sensitive structure was labelled I s [65]. Travnikov [66] studied the exciton spectra from as-cleaved and air-exposed surfaces of OdS and found two lines in the spectral o -line (A = 486.4nm) may vary in region under consideration. The Isl intensity whereas the I°2-1ine may as well change the spectral position within the spectral range 486.4-486.2nm. One of the lines was ascribed to surface defects involving oxygen adsorbed at the surface, while the other one was claimed to originate from the space charge layer. The observed disappearance of the Is-feature under low-dose electron irradiation, resulting in the oxygen desorption [67] points to the fact that oxygen is involved in the centers yielding the Is-feature. A surface-sensitive Is-feature was likewise revealed in the reflectance and photolumin.escence spectI~a of 0dSe crystals,- see Figs. I0,2!, The Is-line appears in t~e initial spectrum as broad line with the maximum at k = 679.9nm, slightly varyir~ its spectral position from sample to sample within 0.1-0.2nm, With minimal amount of e l @ c t r ~ i~r~iation a short-wavelength shift (Fig. 21, OU~-'ve 2) ~ d subSeQuent quenohin~g of the Is-line (curve 3) were revealed. These observations indicate that the I s - feature is most likely associated with the excitons bound to ionized

224

A.E. Cherednichenko and V.A. Kiselev

15

Fig. 21. Exciton photoluminescence spectra of CdSe at 4.2K. (1)- initial spectrum, (2 4)- after exposure to increasing doses

(1.1016; 5.1016; 3.1017e/cm2)

of 2 keV electron irradiation.

680

679 j,nm

donor-type centers at the surface. The Is-line in CdS is seemingly a surface counterpart of the I3-type line in the bulk. It features a

large

half-width

electric

which

may

be

field value affecting

assigned

this

to

variation

exciton-impurity

in

the

complex at

the surface. The authors of ref.

[61 ] claimed that the Is-line in

CdSe

field-dependent

may

be

associated

with

a

localization

of

excitons in near-surface quantum wells. As

the

electron

irradiation

dose

is

raised

a

new

feature

designated as I e s arises in the spectrum. (i) This new feature is observed both in luminescence and reflectance spectra of CdSe (Figs.

10,21 )

and

CdS

(Fig.

9)

single

crystals

following

Excitons at Semiconductor Surfaces

high-fluence

EB.

In fairly

thin

samples

it

225

can be

observed

in

transmission as well (Pig. 20). (ii) Contrast to the Is-feature, the spectral position of this line is practically fixed and makes 485.9 and 679.6nm in CdS and CdSe, respectively. (iii) Following a repeated high-fluence EB, some samples reveal a reversal (rotation) of the ERL corresponding to this transition (see Sect. 5E). These findings suggest that long-lived defects produced by electron irradiation yield the I~-lines. The defects are located in the near-surface region whose width is governed by the electron irradiation dose and incident electron energy. A reversal of the ERL corresponding to the I~-feature proceeds much in the same manner as in the case of the intrinsic exciton although in the former case the centers responsible for the I~-feature are located in the near-surface region and are absent in the bulk (Sect. 5E).

C

Surface and near-surface excitons

Surface states and resonances for excitons are predicted by both dielectric and microscopic theories [6]. For ideal surfaces and interfaces, specific long-wavelength solutions, with the electric field localized within thin layers adjacent to the surface, can be obtained using a macroscopic dielectric treatment provided the dielectric function and the ABCs are specified (both, however, should be derived using microscopic models). The results of experimental studies of this type reviewed, for instance, in [68].

of

excitations

have

been

Conclusions of microscopic theories depend on the assumptions about the electronic structure of the surface. For example, in the case of molecular crystals the surface-site-shift model has been proposed [69] which leads to the exciton localization within one or two subsurface monolayers characterized by exciton resonance frequencies shifted with respect to the bulk value. The theory explains the fine structure observed in the reflectivity spectra of antracene. For interfaces, the excitons may be attracted to the surface by the image potential [70] provided the dielectric

226

A.E. Cherednichenko and V.A. Kiselev

constant of the overlayer is higher than that of the medium. Of

particular

carriers are

interest

is

the

case

in surface electronic

when

one

or

both

states or bands,

of

the

formed,

for

instance, from dangling-bond states [71]. Experimental aspects of the problem have been discussed in [72,73]. Theoretical aspects of 2D

surface

have

been

excitons

excitons

and,

discussed

in

with

surface

in particular, [71,74,75].

impurity

their optical

The

centers

response

interaction and

of

initiation

these of

2D

exciton - impurity complexes have been discussed in [76]. This

short

effort

of

review

shows

(for more,

see

[77])

that

those engaged in the problem of surface

the

main

excitons has

been concentrated on the mechanisms of surface excitons formation for

the

case

of

ideal

crystals.

New mechanisms

of

the

exciton

localization at the surface and within near-surface regions arise if we take into account the interaction of excitons with defects and impurities in semiconductors are

listed

below.

Note,

that

[78]. These

the

"defect" mechanisms

best-developed

model

for

the

interaction of excitons and near-surface charged imperfections is based on the Stark effect in an inhomogeneous electric field. The latter,

under normal

circumtanoes,

surface of semiconductors. excitons

are

localized

is always

present

below

the

It is important that quite frequently within

extended

layers

(102-

103nm)

exceeding in value those typical of the ideal surfaces by orders of

magnitude.

These

layer

thio~2qesses

are

close

to

polariton

wavelengths near resonance and also to the penetration depth of light in a crystal. Hence, exoiton spectra appear to be sensitive functions of near-surface exciton transition layers are

strongly

dependent

on

the

physical

(ETLs) which

conditions

at

the

defects

and

semiconductor near-surface layers. Actually,

the

interaction

of

excitons

with

impurities is always present both in the bulk and at the surface of semiconductors. However,

the defects and impurities themselves

may acquire new properties near the surface, and that may be the reason

for

the modified

or even new mechanisms

of

localization

(see [78)]. Some variants, discussed below, are displayed in Fig. 22.

Excitons at Semiconductor Surfaces

227

W w0

3,4r ~@@

Fig. 22. A s c h e m e for "defe c t" mechanisms of the excit o n localization near semiconductor surfaces (see text).

• 1

~

I@ @@ @@@ @@ @

@@@ •

@@ @@ •

• • @@@

..-- ".. @ .-.-~... .

;@41@ D @

I.

It

is well

known

that

defects

and

impurities

yield under

optical excitation various excitonic complexes whose radii are of the order of IO nm or more (see Sect. 5A). It is natural to assume that

within

magnitude

surface

new

layers

excitonic

with

thicknesses

complexes

may

of

arise

this with

frequencies other than in the crystal bulk. Moreover, may

be

even

thicker

if

the

effect

on

the

order

of

resonance the layers

complexes

of

the

near-surface electric field (see point 4 of our list) is strong. This influence is twofold. Firstly, it may change charge states of imperfections, and, secondly, to

the

Stark

responsible

effect.

for

the

In

the

binding

it may shift the energy levels due other of

limiting

excitons

are

case

the

centers

localized

on

the

surface of a semiconductor,- see, e.g., [66]. Provided

the

complexes

are

independent

(see variant

I)

their

contribution to the dielectric constant of the medium may be taken into

account

by

adding

oscillator

terms.

These

terms

should

include the Rashba enhancement of the oscillator strength [58,59] and inhomogeneous dependences of the parameters of the complexes along

the

z-axis

normal

optical properties of

to

the

surface.

Calculations

of

the

the media characterized by the dielectric

constant varying in one dimension may be performed exploiting the approach outlined in Sect. 4E [55].

228

A.E. Cherednichenko and V.A. Kiselev

2. Another mechanism of localization may result from an increase in

the

imperfection

qualitatively

concentration

new feature appears

that an exciton-defect thickness

of defects.

a nonstoichiometric surface

band

resonance resonance point

(or exciton-impurity)

of the localization

the distribution may

term

layer be

typical

oscillator

may be not of great

A

is so high The

this layer may coincide with

a

shown

into

free in Fig.

However,

the

importance

the

The exciton-defect

theory

exciton, 22,

term should be z-dependent

strength.

surface.

band is created.

(see the next point). of

as

the

layer in this case should depend on Actually

incorporated

frequency,

I this

towards

if the concentration

but

effects

2.

include of

for this band,

adding

for

variant

and

by

a

a

lower

Just

as

in

the enhanced

spatial

dispersion

and formally case 2

may be reduced to case I. 3. A semiconductor the surface,

crystal may have a nonstoichiometric

for example,

layer at

a layer enriched with Cd in the case of

CdS. Also real crystals may be characterized by chemically reacted layers

or/and

layers

one-dimensional gap

of

normal

the material The some

the surface

[55,79,29].

continuum deformation well

for

vanishing

exciton may

be

excitons into

described,

case

3

states,

discrete

importance

of

interaction layer

to

the

refer

may

crystal.

the

direction

be

treated

frequency,

~O'

to modifications the

variant

that

in

the energy

3

in

it will This

Fig.

cause

and

situation

near the

of

22. a

wave

by

of

deformation

of

a The

quantum

functions has

been

[29]. for near-surface

it also provides due

gap

eigenstates,

the

predominantly

to the localization

resonance

see

significant

is the charge of imperfections. 3 and 5, but

-

so

the bulk

lead

concerns

with

in, e.g., ref.

4. Of great

the

I and 2 which

states

of

in a graded

of

(a

which may change

semiconductor

variation

to cases

exciton

solutions

This may also

graded-gap

introducing Contrary

solid

is expected)

resulting

to the surface.

excitons.

bound

of

disorder

localization

of excitons

It is true for variants a specific

electric

field

(SCL). The latter acts on excitons

additional within

the

from I to

mechanism space

of

charge

through the Stark effect

Excitons at Semiconductor Surfaces

229

(see Sect. 6). The coordinate dependence of the field may be subdivided into regular

(averaged over fluctuations)

and irregular contributions

In Sect. 6 we shall show that the macroscopic electric field may cause exciton localization in the SOL. Note, that the width of the SCL, w, depends on the surface charge, Qs' and on the net space charge density, N + - N-. magnitudes.

The

highest

It may vary in a very broad range of sensitivity

should be observed for w ~ ~exc

of

the

exciton

reflectance

~ I0-I02nm where kexc

is some

characteristic wavelength of the exciton. Another mechanism may also be operating, when only one of the carriers, comprising the exciton is l o c a l i z e d b y the field with a subsequent

attraction

of

the

other

carrier.

This

claimed to be revealed experimentally (see, e.g.,

mechanism

is

[80]), but its

consideration is beyond the scope of the present review. 5. At last we wish to mention highly disordered surface layers (amorphous, sputtered layers of solid solutions, etc.) that may be represented

by

random

spatial

oscillators,

- see variant

5

and

energy

in Fig.

22.

distributions

This

variant will

of be

illustrated in what follows.

D. Localization of excitons in rectangular potential wells To account for some features in the ERLs of semiconductors appeared

appropriate

to

make

use

of

the

model

it

involving

near-surface potential wells for excitons with fairly sharp edges. It is evident

that the diffusion of the well's

exceed the exciton wavelength (~102nm). the exciton reflectance lineshape described

in

circumventing

[55] the

(see,

difficult

edge should not

A method for calculating

(ERL) for a given potential was

Sect. problem

4E). of

This

method

finding

the

permits

levels

of

mechanical excitons in the well and then taking into account the photon-exciton interaction, and it makes it possible to directly calculate the optical spectra of exoitons.

230

A.E. Cherednichenko and V.A. Kise ev

0

2

#

6

8

N 10 tZ

-/I /"

1 I

0

-5

T

.

111 e

1 0

250

2

$

6

2,rim

8

I0 I2 "~$ 02 0

iz '

R

Fig. 23. A scheme showing the fine structure o f t h e EP~ o f a CdS crystal (on the right) arising due to the potential well with hard edges (on the left).

Consider, well,

for

the

shown in Fig.

sake 23.

of

simplicity,

We note,

the

that the

right-angle

shaped

particular case of a

well with infinite walls has been presented in Sect. 4D. Here, inner wall of the well

is of finite height,

levels

finite.

in

the

well

is

These

levels

hence, are

the

the number of plotted

in

the

left-hand part of Fig. 23. From the figure we note that there are resonant

states

quantum-mechanical Bound spectral

and

above

the

well

which

are

dominated

by

interference of excitons above the well.

resonant

states

both

lead

density of states of mechanical

to

oscillations

exoitons.

in

The maxima

the in

the density of states are indicated on the dispersion curve by the dots plotted

in the middle part of the figure.

They indicate

positions of the bottoms of N = 1,2... 2D-subbands plane). Such a plot is

made

by

analogy

with

the

(in the surface

the

case

of

an

Excitorl~ at Semiconductor Surfaces

231

O.5

0.~ 0.5 0.2 0.1

f

I

0

0

0

w o

wj.

w

Fig. 24. The calculated ERL of a CdS crystal for different parameters of the rectangular near-surface potential well of Fig. 23 (see text).

infinite-wall well (see Fig. 17a) and, is, It has been pointed out in Sect. 4D that polariton effect the singularities in density of states do not coincide with corresponding to them in the optical

therefore, qualitative. in the presence of the the mechanical exciton the spectral features spectra, e.g., exciton

232

A.E. Cherednichenko and V.A. Kiselev

J /

!!

P~Jf

~03

k

Fig. 25. Schematic illustration of the origin of the spike features due to the near-surface potential well with hard edges (see text).

reflectance spectra

[40]. The singularities are shown in Fig.

to be related by means of upward and downward arrows

17

(see Fig.

17a), i.e., by means of projecting the dots onto the two polariton branches. Similar plot was made in Fig. 23. The right-hand part of the figure shows the fine structure of the calculated reflectance spectrum which is seen to be dominated by the exciton levels in the well, as well as by the above-well resonant states. The width of the well w was taken to be 250 nm, the depth of the well being given

as

the resonance

frequency

shift

A~O=

-5cm-~

Henceforth,

where necessary (see, e.g., Sect. 6), these two parameters will be given as put in parentheses without (250,-5), denoting the width and respectively. The spectra calculated for several shown

in

Fig.

24.

By

varying

w

one

units of dimensions, the depth of the different arrives

values at

the

e.g., well,

of w are following

Excitons at Semiconductor Surfaces

conclusions interference

(i)

With

features

the

increase

marked

in

1,2,3...

the begin

233

value to

of

appear.

w

the They

originate from the above-well resonant states which are subsequently captured by the well with increasing w. ( i i ) The interference structure shifts to long wavelengths away from the main reflectivity peak. (iii) The structure is spread out and, eventually, disappears with a new short-wavelength feature arising in the region of the spike. Such a modification of the spectra are easy to follow in Fig. 17 and Fig. 23. In fact, similar interference features can likewise be obtaind with a right-angled step (see, e.g., Fig. 18, variant 17) and this circumstance need to be taken into account when performing the analysis of experimental data. Still, the models involving potential wells quite often give a more close fit to the features revealed in the experimental spectra. Quite often, one may observe a long-wavelength shift of the main refleotivity maximum and minimum, stretching of the spectrum along the frequency scale, and appearance of a more pronounced spike as compared with that normally observed in the region of ~L (see Fig. 24 and text below). These observations are readily explained within the framework of the polariton approach, see Fig. 25. Lowering of the exciton resonance frequency in the near-surface layer (~OV ~ ~OS ) brings about the spectral shift of the polariton branches below the surface. As a result, the polaritons of the upper branch in this layer (shown by horizontal smrows) fall into the region of the longitudinal-transverse splitting for bulk polaritons, hence, they are reflected from the bulk of the crystal back to the surface. Actually,

the crystal bulk serves as a metal

mirror for near-surface exciton polaritons. As regards the origin of the wells in question, we note, that, at least, two mechanisms should be considered. The first one is due to a random field of charged centers in the SCL, where a sharp drop in the frequency ~0 below the surface is associated with the fluctuation part of the electric field of charged defects (donors) of high concentration. This case is exemplified by the spectra of Fig. 12 [29]. Relevant theoretical treatments are now in progress,

234

A.E. Cherednichenko and V.A. Kiselev

and a detailed

account

of the problem

is beyond

the scope

of the

present review. Another mechanism crystals [81].

The

crystal

experimental

is

spectrum

shown

in

features

compared

with

experimental about

a a

stretched along 13.4om -I

exciton

part

normal also

spectral

note,

that

the frequency

6.4cm -1

(which

shift

of

the

properties,

perturbation

is

of

spectra

as

the

that

of the surface.

a whole

Another

spectra

of the ERLs are value

used

of

the

[37]).

(A)

is is

associated a

X-ray analysis

with

result

of

Both of the shifts are assumed

due to one and the same reason.

are

to a commonly the

(A~L)

stretching

The

IOcm -I , as

[37].

"widths"

splitting of 7.7 cm -1

while

a.

a

curve a, is shifted by

compared

less

in

such

curve

experimental

The

of

about

position

the

scale.

26(I),

shift

of CdSe

observed

spectrum

of Fig.

short-wavelength

in some

solution

reflectance

and 25.5cm -1 , respectively,

of

The

to the occurrence

layer of a solid

the upper

longitudinal-transverse bulk

due

spectrum shown in Fig. 26(II),

49cm -I . We

value

arises

of a near-surface

indicates

a

to be

that the

crystals in question were heavily doped with S to a concentration of 1019-I020cm -3 . Actually, the samples represented solid solutions

of

CdSe1_xS x

Corresponding 1.5%

for

of

second

one

the

extrapolating

involving extended and

can

a fairly tail,

IIb,

deep well with

only

be

by

the

the of

order

first S

emploing

sharp

27. The upper

to calculate (Note,

6).

of

I%.

spectrum

was

accounted

regards for

edges shown in Fig. 27.

by

the

a

and

estimated

by

spectra and the model

that

the

potential

supplemented

(I) and lower of Fig.

see curve

feature

long-wavelength a

ERLs

are

is seemingly due to

by the inhomogeneous

incorporating

by an

(2) curves of 26,

theoretical

The tail of the potential

exerted on excitons As

edges

the ERLs

field which yields a multy-spike

Sect.

of

for

percentage

achieved

respectively.

the Stark effect electric

be

see Fig.

given as unshifted).

also,

(the

being

0.3%

agreement between the experimental

ones

the figure were used Ib

x

x were

the data of [82]).

A qualitative calculated

with

values

deep

surface

in the ERL feature, well

with

(see,

it

can

sharp

Ex¢itons at Semiconductor Surfaces

235

T R OL

0.#0.3- / 0.20.10 ! , I~720 , R

I

I

I

I

14700

I

14720

1"[ b

0.5-

0,#0.~- /

m

0.2o,1-

u~,cm 1 0

i

I

1#?~0

I

I

I

!

1#760 1~780

ua~c,m-t i

~

i

I~700

I

I

I

1#720

Pig. 26. (a) Experimental exciton reflectance spectra of OdSe(1-x)S(x) in the vicinity of the A(n=1) -exciton at 4.2K (see text); (b) Theoretical spectra calculated using near-surface potentials shown in Pig. 27. I corresponds to x =0.3% (see potential I in Pig. 27); II corresponds to x =1.5% (potential 2 in Pig. 27).

236

A.E. Cherednichenko and V.A. Kiselev

t" •,~ r ~ o , 4 --- .

.

.

crl, t"l

F .

"1

L,_.

0 -4 -'1 %.

0

Fig. 27. A resonant exoiton frequency shift A~ and exciton damping P vs coordinate z. (I) corresponds to curve Ib and (2) corresponds to curve IIb (see Fig. 26).

-8

-/2

z,~m

-16 I

I

I

I

0.2 0.4

0

In

i

view

of

I

0.6

I

I

these

(one-dimensional)

I

0.8 1.0

studies

near-surface

it

seems

natural

to

assume

a

fluctuation of the composition due

to a layer of a solid solution (only a one-dimensional fluctuation is

capable

estimates,

of

producing

sharp

a characteristic

be of about ~102nm.

features).

According

to

our

linear size of the fluctuation should

Sulfur content at the surface should be less

than in the interior, which yields a potential well rather that a step.

There

is

also

an

additional

that,

from the point

excitons

in

CdS(Se)

solid

does not seem to proceed. that,

depending

surface excitons.

on

fluctuation

the may

which

of view of solid solution physics,

these findings appear to be rather surprising, of

evidence

[81].

supports our suggestions Note,

experimental

solutions

Probably, growth arise

with

low

sulfur

content

the effect of surface is such

conditions,

which

since localization

allows

a for

one-dimensional localization

of

Excitons at Semiconductor Surfaces

237

E. Localization of excitons in defect-rich surface layers In

the

previous

section

the

exciton

localization

in

the

near-surface potential wells has been treated. Another important mechanism

of

localization,

U~Z.,

localization

field

the

space

layer

(SOL)

of

detail

in Beet.

charge

6. In the present

by

shall

the

be

electric

considered

in

section we consider one more

type of localization which is due to the binding of exeitons by near-surface defects. Several

types

of

bound

excitons

associated

with

different

centers can be excited in a semiconductor bulk (see Sect. 5A) but we

will

concentrate

herein

on

those

which

near-surface layer (Fig. 22, variants 1,2). impurities) occur

may exist

predominantly

in as-grown

as

a

result

are

peculiar

of

a

Such centers (defects,

(untreated)

samples,

of

treatments,

various

but

they e.g.,

etching, electron or ion irradiation. In Sect. 5B we have outlined that the electron irradiation of CdS and OdSe or~jstals to a dose of

IO17e/cm 2

spectra

yields

(taken ~

irreversible

modificaton

of

the

exciton

s~t~ at 4.2K) resulting from the electron-beam

stimulated formation of long-lived defects.

This

issue has been

treated in detail by Batyrev et al. [83] and this section reviews briefly the results of these studies. In

Sect.

5B

we

have

shown

that

after

a

prolonged

electron

irradiation of CdS and OdSe crystals some new features, designated e and 12* arise in the reflectance and emission spectra (see as I s Figs. 9.10,21].

0dSe samples, may be classified, with respect to

their photolumineseence spectra, into two groups; group I concerns "perfect" or~Jstals while group II include "defect" crystals. Fig. 28 shows

the evolution of

the exciton reflectance

spectra of a

defect CdSe crystal with increasing the irradiation dose. Photolumineseence spectra of a "perfect" CdSe crystal before and after

prolonged

electron-beam

irradiation

induced

line

are Ie s

is

presented seen

to

in shift

Fig.

29.

towards

The long

wavelengths by about O.Inm (curves 2,3). The donor-bound exciton, induced by the EB (see Fig. 20) is modified into a broad line (Ak ~0.6 nm) labelled I2s which also shifts towards long wavelengths.

A.E. Cherednichenko and V.A. Kiselev

238

IS

R~2

G

I2s l 1~

0.4

I2s

jv

I I 0/3 _I I I -I I I 0.2

b

J/

2

j~

I

I .I II

L-- I

6

\

6

0.~

G81

6~

681

680

~nm Fig. 28. Exciton reflectance curves of CdSe (2-61~exposed to increasing doses of electron irradiation ( x10 "e/cm). a: (1)-initial; (2)-I; (3)-2; (4)-8; (5)-20; (6)-60. b: the magnified spectra.

Excitons at Semiconductor Surfaces

239

~l Izs

Iz

I i}

Fig. 29. Exciton pho toluminesoence spec tra of a "perfect" CdSe sample (1)-initial spectrum, (2,3) - after exposure to increasing doses of electron irradiation, (4)-initial spectrum of a "defect" crystal (see text ).

x 10

~

J

j ......

,

" ";'"

, x3 '........-2",.;

°

\

i

i

681

i

i

i

i

679

i"--.,/.i

~,nm

Eventually, the I2s-line (~ ~ 680.65nm) becomes a predominant feature of the photoluminescence spetrum. Also seen is the Ie-line (~ u 679.7nm). The observed changes were found to be irreversible. s Note that the I s - and I2S- features can be revealed in the optical spectra of as-grown samples. Curve to curve 3, indicating that a prolonged yields modification of "perfect" (group I) (group II) ones. The ERL of a "defect" CdSe sample versus

4 is almost identical electron irradiation crystals to "defect" the electron dose is

shown in Fig. 28. Initially, a distinct structure associated with An=l-, I2S-, and I s- excitons is observed. Electron irradiation brings about the "rotation" of the ERL of the An= I- exoiton, which is indicative of an initiation of the exciton-free layer.

240

A.E. Cherednichenko and V.A. Kiselev

It

oi.;

° Fig. 30. Calculated ERLs of CdSe vs the width of the near-surface layer with an additional resonance, a 20nm; b - 50nm; c - 100nm; d lO00nm.

14710' "/4720

The reflectivity are

of

a

14730

e transitions features associated with 12S- and I s-

typical

dispersion

"rotation".

Furthermore,

the feature

associated

with

the

accompanied by an enhancement The

reflectivity

irradiation centers

dose

(defects)

that a defect-rich

features

point

character

and

also

reveal

the

curves 4-6 indicate a strong quenching of

to

capable

intrinsic

An= I- exciton

which

is

of the I2S- feature. and

the

their fact

of binding

reversal

that

the

excitons.

with

EB

increasing

produces

From

layer arises below the surface

local

this we infer

(the penetration

depth of keV electrons

is about ~102nm) whose width is governed by

the

energy

incident

Contrary excitons

to

electron the

and

conventional

the

electron

dead-layer

irradiation

(see

Sect.

excited at the centers of the near-surface

close to the surface and are essentially absent Relevant

calculations

in this case. The model

indicate

is considered

the

that the ERL can also be reversed

in question suggests to be

4A),

layer do exist

in the bulk.

the existence

layer of a finite width within and beyond of which constant

dose.

equal

to

of the

the dielectric

the background

dielectric

Excitons at Semiconductor Surfaces

241

constant ~0(~)" Within the layer, the dielectric constant is contributed by an oscillator term of the type: ~/(~I~0 + 47), where ~I is the excitation frequency of the e exciton (e.g., I2S and Is). The calculated 30, reproduce the effect of rotation of the in the width of the layer. The rotation is

relevant near-surface spectra shown in Fig. ERL with the increase observed for both the

intrinsic exciton and additional resonance outlined above. As regards the origin of the electron-beam-induced defects, latter seem to involve

the anion vacancies

Vse(V S)

the

and the I2s

line is a counterpart of the bulk 12 line. The I e s - and I2sfeatures show similar dependence on the irradiation dose and, in heavily treated samples they rather than local centers.

F. Localization of exoitons

are

by

associated

fluctuations

with

of

a

defect

bands

near-surface

random potential Low-temperature photoluminescence spectra also demonstrate the feasibility of surface localization of excitons (carriers) by fluctuations of a random potential. There is a variety of reasons for the occurrence of a random potential and corresponding in the density of states (see, Fig. 22, variant 5).

tails

In Sect. 5B we have indicated that the exciton photoluminescence spectra of CdS and CdSe crystals were modified by electron bombardment (EB). This section shortly reports a study of a broad band observed in the emission spectra of some CdSe crystals which was attributed to the luminescence of excitons localized at surface fluctuations of the potential (or charge) [84]. Figure 31 shows the photoluminescence spectrum of one of OdSe samples at T=4.2K typical of those reported in [84]. In the short-wavelength part of the spectrum (on the right of the figure) there

are

observed

luminescence

features

due

to

free

excitons

An=l, surface exciton I s (see Sect. 5B), and a strong line 12 due to exoitons bound to neutral donors. In the long-wavelength part of the spectrum ( on the left of the figure ) a very broad band

242

A.E. Cherednichenko and V.A, Kiselev

Zs

1

A .=Z

/jlAI:/ "i ')

~"=' (,=~)

/~

,l

/ilz~ ~. /:i~!):

/

21 ~,

[, I"

!.~x30

r 679 ~n.t

Fig. 31. Photoluminescence spectrum of a CdSe sample at T=4.2K (see ref.[84]). 1) initial spectrtun; 2),3) after low-dose electron irradiation (see text).

labelled X is revealed and against its background one can see oneand two-phonon replicas of the An= I- exciton. Several new ~eatures were observed for the new band. I ) The band

is wide with a halfwidth of at

least 20 meV.

The

spectral position of the band maximum varied from sample to samle within 6830-6850 ~. The intensity of the band was anticorrelated with the intensity of the exciton photoluminescence. 2)

The

band

X was

extremely

sensitive

to

surface

treatments.

Excitons at Semiconductor Surfaces

243

Figure 31 shows the photoluminescence spectra before (curve i) and after 1 sec ( ~2 1015e/cm 2) and 3 sec (~ 6 1015e/cm 2) of 3.5 keV electron

irradiation.

It

is

clear

from

the

figure

that

the

electron irradiation resulted in a marked quenching of the band and

in

a

characteristic

wavelengths.

The

shift

observed

of

its

quenching

maximum was

toward

shorter

accompanied

considerable increase in the exciton luminescence

by

intensity

a

(see

the right-hand part of the figure). 3) The band X depended on temperature in a complex mam~cr.

It

markedly shifted toward long wavelengths and reduced in intensity disappearing at about 20K [84]. These findings

(for more, see [84,85]) suggest that the X band

results from the radiative recombination of excitons localized at fluctuations of the random potential relief at the semiconductor surface.

The

fluctuations centers

fluctuations of

the

(defects,

result,

charge

due

impurities)

most

to

a

likely, random

from

spatial

distribution

of

in the surface layer. The presence

of these centers may give rise to wells

in the potential relief

and these wells may have localized (exciton) states similar to the exciton states in solid solutions of semiconductors. Small Sect.

electron 4B)

initially

and

doses also

reduce

reduce

localized

the

surface

charge

states

electric

fluctuations,

disappear.

This

efficiency of other luminescent channels, ~ Z . , and bound excitons, 31).

The

field

so

temperature

the

increases

the

those due to free

which is evidenced experimentally

influence of

(see

that

can be attributed

(see ~'ig. to thermal

delocalization of excitons. This results in a gradual quenching of the

band,

starting

from

its

short-wavelength

edge,

and

by

a

relative shift of its maximum toward longer wavelengths. To conclude, we note that surface fluctuations of the potential do not necessarily result in localization of excitons as a whole but

only

one

of

the

carriers

in

an

exciton

can

be

localized

instead. As an alternative to the model

in question we can also

consider

electrons

recombination

with

holes

of

localized

at

surface centers. This model is also popular and ft~ther studies are needed to identify the origin of the broad emission bands.

244

A.E. Cherednichenko and V.A. Kiselev

6. Band Bending and Its Relevance to Excitons and Exciton Spectra In

this

section

we

shall

discuss

extrinsic mechanisms by which

one

of

the

most

obvious

the exciton transition layer (ETL)

is formed, namely, the interaction of excitons with a non-uniform electric field of a near-surface space charge layer the near-surface and

modifies

drastically.

electric

the

field that perturbs

exciton

This

is

reflectance

particularly

compounds

With

the

direct

absorption

coefficient

at

the

of

(ERL)

the

most

semiconductor

transitions,

exoiton

It is

the exciton state

lineshape

true

allowed

(SCL).

resonance

where

the

very

high

is

(I04-I05cm -I ) so that excitons are excited close to the surface. Hence,

the

aim

of

this

section

is

to

consider

the

issue

in

detail and also to demonstrate the sensitivity of the ETL to the changes

in the SOL.

Many anomalies

of

the

exciton reflectance

spectra can be explained by this mechanism. The influence of the SOL

may

be

extremely

varied

depending

on

the

electric

field

strength at the surface F s and the field penetration depth into a crystal w which is related to the screening length. For calculations of the reflectance

the approach developed in

[55] has been employed (see Sect. 4E). The SCL was devided into a set of thin Pekar's slabs [8]. By means of this approximation the problem is reduced to the calculation of the optical properties of a layered medium. The effect of the potential is to increment the exciton resonant frequency in each layer by an a m o u n t e q u a l to the height of the corresponding step. The fact that within each layer the potential

is

independent

of

the

coordinate

simplifies

the

problem considerably, since for each layer it becomes possible to apply the crystal optics of a slab with spatial dispersion. At the inner

boundaries

conditions

between

(ABCs)

require

the the

slabs

the

continuity

additional of

the

boundary excitonic

polarization and its normal derivatives. The set of ABCs and Maxwell boundary conditions at all boundaries, inner and outer, form

the

set

of

equations

that

are

to be

solved.

Results

of

calculations shall be compared with data by other authors as well

Excitons at Semiconductor Surfaces

as with our own results on the

245

effect of preliminary illumination

with light, of electron bombardment and externally applied field on the exciton reflectance.

Characteristic

features of the ERLs

and their response to external stimuli may provide an estimate of SCL parameters: F s, w and the charge density e(ND-NA).

A. Band bending in semiconductors Bending of energy bands in the near-surface region is considered to

be

one

of

the

most

important

features

of

semiconductor

surfaces. By depleting the near-surface layer of majority carriers the band bending builds a potential barrier for them (the Shottky barrier) devices

which based

plays on

a key

role

in operation

metal-semiconductor

or

of

metal

semiconductor -

insulator

-

semiconductor structures. The band bending near a free surface is the result of a screening of the field by the surface charge. This charge

is held by surface

electronic

states.

A great

effort

is

devoted at present to achieving an understanding of the mechanism of Shottky barrier formation on an atomic level,

i.e. to clarify

the physical nature and energy structure of the surface states. The

surface

charge

density

determines

the

electric

field

strength at the surface F s. Given the space charge density value near a semiconductor surface,

p = e(N + - N-),

concentrations

of

positively

and negatively

respectively,

one

obtains,

coordinate

dependence

of

the

using field F

the and

N + and N- being charged

Poisson of

the

centers,

equation,

a

electrostatic

potential ~ . For a depletion layer of a n-type semiconductor we have 4%e + F(z) =--~-(N -N-)

(z-

~(z) =

w),

(F(O) = F s, F(z > w) = O ) , (6.1)

2~e ~ (N+ - N-) (z - w) 2 ,

where g is the static dielectric constant.

(6.2)

246

A.E. Cherednichenko and V.A. Kiselev

Q

bIFI C

W

Fig. 32. Distribution of the charge density p (a), of the electric field F (b), and electrostatic potential @ (c) assuming complete depletion.

W These

equations

Z

will

be

reflectivity coefficient. -

N-)

is

constant

(in

used

(6.1)

equilibrium

(N+

bending of free carriers The

approximation.

last

calculate

the

exciton

,and (6.2) apply if (N+ -

N-)

is

a

difference

aoceptor concentrations, N D and only one type of donors is present

the temperature is low enough,

depletion

to

Equations

between the donor and respectively), if, then,

excitons.

below

NA, and

so that a contribution to the band

( ~ kT) will be too small to affect

condition

defines

Variations

with

the z

so-called of

the

the

complete

space

charge

density p as well as of the quantities F and 9, calculated in this approximation,

are

plotted

in

Fig.

32.

This

model

is

able

to

account for many anomalies in the exciton reflectance spectra that could not be explained in the framework of traditional approaches (see Sect. level,

4) and, as well,

modifications

(illumination, variations,

of

electron

applied

field,

to explain, at least on a qualitative the

ERL

under

external

bombardment,

etching,

oxidation

others).

and

influence temperature

On

the

model

depicted by (6.1) any two parameters out of available three: F s, N + - N- and w may be chosen to describe these modifications, w being the depth to which the field penetrates the crystal width of the SOL).

It is clear

that external

factors

(or the

(including

Excltonsat SemiconductorSurfaces

247

probing light in optical investigations) may affect not only the three parameters mentioned but also the function F(z) (as well as p(z) and ~(z)). For instance, high concentrations of the electron-hole pairs generated in SOL by intrinsic light may disturb the constancy of p(z) across SOL in such a way that the holes are accumulated near the surface and electrons near the inner SOL boundary (see, e.g., [86]). A non-uniform charging of centers across the SOL will proceed and subsequent charge redistribution will be acting so as to flatten the energy bands near the surface. Note, that the authors of refs. [87,88] used other expressions for P(z) We have also tried to modify their model by adopting F ~ (z - w)~ where n = 2, 3, or more, but no improvement on the results was found. Direct observation of flattening of the energy bands by light is possible utilizing exoitonio spectroscopy (see [89] and further). Therefore, the light intensity has to be kept very low for the photogeneration of pairs to be negligible. This is a proper way in probing with light. In other kinds of experiment the light intensity should by sufficiently high to permit the amount of band bending to be contr~lled and the model depicted by (6.1) may be used only in a qualitative consideration of the effect (Sect. 6D). Note, that illumination with light from within an appropriately chosen spectral range enables one to charge the surface states in a controllable way [89]. The model in question still applies in this case but an appropriate change in the parameter F s is required. Excitonic spectroscopy is most suocessfull at low temperatures. Besides allowing to ignore free carriers while seeking to establish the form of the barrier, low temperatures lead to long relaxation times, such that certain non-equilibrium processes (externally provoked band bending, e.g., under illumination with light [89], depletion [90], charging of a near-surface layer by irradiation with electrons [19], charging of surface states [89,33] and others) get "frozen-in" and can persist for long enough to permit measurements of optical characteristics of the exoiton at any given band bending value. The effects of this kind

248

A.E. Cherednichenko and VoA.Kiselev

include the dependence of ERL on whether a crystal is being cooled when exposed to light or in the dark. To get reproducible results, it is extremely important to take account of such effects. One

more

bending

property

of

the

of

energy

the

B0L

bands

that

is

the

may

be

observed

quantization

of

at

strong

the

carrier

movement normal to the surface resulting in the formation of a 2D exciton

(see, e.g.,E80,91]).

A detailed account of the problem of

2D excitons is beyond the scope of the present review.

B. The effect of a uniform electric field on excitons Prior field

to a

of

useful

treatment

BCL

to

on

the

consider

assumptions

of

the

effect

exciton the

to be made

and

case

of

in Beet.

of

its a

a non-uniform

optical

uniform

field

of

an

proximation)

exciton

as

it

because

is the

6C will allow us to substitute

uniform field for the non-uniform one. One assumption movement

electric

properties

a

whole

is

slow

a

is that the

(adiabatic

ap-

and the other is that field variations over distances

comparable to the exciton radius are small

(the approximation of a

point

of small

increments

in

field does not mean small absolute values of the field, which,

in

fact,

exciton). may

Note,

be

Investigations

that the assumption

very of

strong

the

effect

near on

a

semiconductor

excitons

of

have been initially prompted by observations on

excitons

e.g.,J33)

by

Gross

and later,

et

al.

the electron-hole

interaction

electric

(the

field

"solid-state"

as

by results

far

electric

field

of the Stark effect

as

the

mid-50s

(see,

of the research on the effect of

on

the absorption

Franz-Keldysh

investigations

back

the

surface.

were

effect

carried out,

of light

in the

[92,931).

These

at least

for some

time, in isolation from traditional calculations of the electronic states of the h~vd~ogen atom in the electric field

(see references

in [94,95]) that can equally be applied to a theory of an exciton. Out only

of a large number of works those

energies

that

close

deal

with

in this

theories

to the ground

state

field we

applicable

in

shall the

energy of an exciton

review

range

of

and,

in

Excitons at Semiconductor Sudaces

249

addition, cover the case of strong electric fields, up to such that ionize a hydrogen-like system in the ground state. We note, that the ranges of the Coulomb interaction and field magnitudes outlined above rule out the usage of the perturbation theory. The problem was found to permit analytical treatment if either some special form of potential distribution is used instead of the actual one (see Fig. 33) [96-98] or a limit is imposed on the magnitude of the field [99,100]. The most reliable results for a wide

range

of

field

values

have

been

obtained

by

numerical

integration of the Schrodinger equation [101-103, 94]. Characteristic scales of energy, length and field strength are defined in this model as follows [103]. The exciton binding energy in the ground state has the form (2.2) and the exciton radius is given by (2.4). The field required to ionize a system is found by equating an increment in electrostatic energy binding energy:

over

the

exciton

radius

F I = IEll/(eRexc) = (~/mo)2. g-3Fi H

to

,

hydrogen-like the electron the

exciton

(6.3)

where FIH = 2.57"109 V/cm is the ionization field for the ground state of the hydrogen atom. Factors in (2.2), (2.4), and (6.3) containing the reduced mass ~ and the static dielectric permeability diminish

IEll and F I by several orders of magnitude

and increase Rex c compared to the CorTesponding quantities for the free hydrogen atom so that fields as high as F I (and even stronger) seem quite feasible in semiconductors. Some examples are given in Table I (for more see [103,102]). Major results obtained for the hydrogen-like system in an electric field may be summed up as follows. In weak fields, F/F I ~ f << I, the exoiton level is shifted to long wavelengths (the quadratic Stark effect ) by (9/8)f 2 in units of the exciton Rydberg: IEl(f = 0)I. This shift is due to some broadening of the Coulomb well under applied field, see Fig. 33 [103]. The field creates a potential barrier, such that the energy needed to pass it over would have dissociated the exciton. As the field is increased, the top of the barrier lowers

250

A.E. Cherednichenko and V.A. Kiselev

Fig. 33. A potential of the electron hole interaction in the presence of an extez*nally applied uniform electric field (solid curve) and without field (dashed curve).

TABLE

1

Rexc, nm

IEII, meV

F I, V/cm

GaAs

13.6

4.2

) -103

InP

12.5

4.9

4"103

OdSe

5 •I

16

3.104

OdS

2.8

28

1 • 105

Excitons at Semiconductor Surfaces

faster

than

the

ground

state

level

and

at

251

f

=

fc

~

0.13

a

classical transition of the barrier becomes possible (if the Stark shift is neglected,

then fc = 1/8 [1021). The finite probability

of the exciton dissociation (both tunnel and classical) the

exciton

fulfilled,

level. i.e.,

When

if

f

a

condition

<<

fc

the

for

density

deep

broadens

tunnelling

of

states

in

is the

resulting band is described by the Lorentzian distribution with a halfwidth (in units of IEll)

r/2

=

(6.4)

(81f) exp [-4/(3f)]

Despite the fact that the resonance happens to occur above the barrier for f > fc the

shift of the

level to long wavelengths is

nearly quadratic up to field strengths of about f ~ 0.25

[1031,

and the density of states distribution still retains the maximum, which can be followed up to f ~ I [101-103] (Pig. 34), i.e., up to the field value at which the bandwidth exceeds the exoiton binding energy (P =fEll for f ~ 0.75 [94]). The occurrence of the maximum in the spectrum of unbound states is due to quantum interference that an electron wave experience when passing over the well [102] (this effect for the case of a rectangular well has been discussed in Sect.

5).

It seems that few of those engaged in research on

excitons are aware of the fact that they often deal, in fact, with the unbound state at the above-barrier resonance rather than with the bound exciton state. The situation when in the semiconductor near surface region f ~ fc ~ 0.13 is met rather frequently. this

field value

the

shift

to

long wavelengths

and

broadening

amounts to a merely ~ 0.O2.1Eli and O.003.1EII, respectively, example, for the An= I exciton in 0dS

At (for

the respective values are

0.6 and 0.09 meV). As the field f ~ 0.4 is reached, the energy of the resonant exciton state assumes a value of ~ 1.1.E1(f = O) and with further field increase the resonance shifts in reverse, i.e., towards short wavelengths, - see Fig. 35 [103]. Hence, the maximum possible value

of

macroscopic field

the exciton resonance can produce

exoiton binding energy.

frequency

shift

that a

amounts to about one tenth of the

252

A.E. Cherednichenko and V.A. Kiselev

Eg.-ILll

Lg

Fig. 34. Profiles of the'density of states ~2(0) (relative units) of a hydrogen-like system for different values of the uniform electric field [101].

E,(,f)/IE,(O)I -0.2.

-0.6 -'1.0 O.q

0.5

2.0

Fig. 35. Variation with eleotrio field f of the ground state energ~y of a hydrogen-like system relative to the unperturbed oontlnuum [103]; dashed curve - perturbation theory.

Excitons at SemiconductorSurfaces

253

For the excited exciton states with the quantum number n above unity the exciton dissociation is possible at substantially lower fields, e.g., at fc(n) = fc(1)/n4 [102]. Therefore, at f ~ 0.2 essentially no peaks remain in the density of states spectrum except the one with n = I. This peak becomes broader and merges into the continuum, loosing its symmetry, longer be described by the Lorentz formula. At

stronger

fields

the 0oulomb

that

interaction gets

is,

it

can

no

progressively

less effective and for f ~ 10 the density of states calculations are but little influenced by an account of this interaction [103]. Most convenient for treating the effect of a non-uniform field on excitons happen to be the expressions, derived for the hydrogen atom using the results of ref° [94]. The calculations include strong fields and resonant energies, with the energy and broadening as major parameters of resonances. The field and energy values can be given in units of F I and IEII, respectively, of atomic units. To

solve

the

Schr8dinger

equation

for

the

instead

hydrogen

atom

subjected to the electric field the variables were separated by employing special "quadratic" pax~abolic coordinates and the problem thus reduced to solving a system of two differential equations. Numerical integration of the equations was performed using the method of series reexpansion. If a condition is imposed on one of the two equations that the wave function be finite at zero and decay exponentially to infinity, then a discrete spectrum of

eigenvalues

is

obtained

(with

the

energy

E and

field F

as

parameters). In our calculations, though, the demand of exponential decay was replaced by that of the wavefunction be zero at some point sufficiently remote from the origin of coordinate system. The other equation which depicts the transition through a barrier leads, in fact, to a problem on quasi-stationary states. Its solution was made to matah with an asymptote of the wavefunction also in a enough remote point, which yielded the asymptote parameters, the amplitude and phase, as functions of the energy E and field F. By analogy with the scattering problems, from the analysis of dependences on energy of the phase and

254

A.E. Cherednichenko and V.A. Kiselev

amplitude value.

the

The

EI

and

r

values

calculations

were

can

be

deduced

carried

out

for

along

every

the

field

lines

of

Breit-Wigner theory. The values of E I were deduced under condition that the squared asymptotic divergent

wave

is present)

parametrization phase

shift

Generally

amplitude

of

in

the

the

the P values

dependence

proximity

speaking,

parametrization

and

the

be minimum

on

of

obtained using

of

the

of

the

asymptotic state.

Breit-Wigner

is open to question.

of the ground state band [101-103]

only the

quasi-stationary

applicability

at high fields

were

energy

the

(i.e.,

An asymmetry

is indicative of a necessity to

go beyond the bounds of this theory.

However,

the probability

of

exciton dissociation for the noticable asymmetry of the band is so great,

that

the

bandshape

effects considered.

is

not

of

much

importance

Still, we intend to discuss,

for

the

on a qualitative

level, deviations from the Lorentzian lineshape evident in the ERL rotation above

(Sect.

deal

6G).

To conclude,

exclusively

calculations

to

Generalization

follow

we note

with

simple

will

be

of the results

that

the works

electronic

restricted

cited

bands.

to

to cover non-uniform

Our

this

case.

fields

can by

performed using the method discussed in Sect. 4.

C. The effect of a non-uniform electric field on excitons As

indicated

semiconductor considered

in

above,

the

may

strong

be

the previous

electric

field

enough

section.

to

within cause

all

Inhomogeneity

makes the density of states distribution

the of

SCL

the

of

a

effects

this

field

(Fig. 35) vary from point

to point along z. The effect on excitons of a non-uniform electric field near

the

crystal

surface

Gribnikov and Rashba

[104].

that

pulled

an

exciton

interaction result,

of

is

the

induced

was

first

In particular, into

the

dipole

treated

by

they have demonstrated

high-field

moment

in a paper

with

the quadratic Stark effect takes place,

region

this

due

field.

to

As

a

i.e., the resonant

frequency of the exciton near the surface gets lower. In ref.[IO4] the

influence

of

this

effect

on

the

exciton

diffusion

was

Excitons at Semiconductor Surfaces

analysed.

The analisys was later continued in

255

[105], emphasizing

the role the near-surface field plays in exciton dissociation. The possibility that the near-surface field might pull in and ionize the exciton was also suggested by Allen [106]. In the most definite manner the influence of the space-charge field on the exciton states in semiconductors was established in experiments o n reflectance and electroreflectance. For some crystals interference of light has been observed in the region of the exciton resonance. An additional reflection of light from the inner SOL boundary where an abrupt change of the dielectric permeability occurs was observed on CdS crystals at 273K [107] and 4.2K [121] as well as on GaAs [25,108,109] and InP [17] at liquid helium temperatures. At low temperature this interference could be observed without modulating the applied voltage, as a rotation of the ERL following alteration of the contact bias or under electron bombardment of the surface (see Sect. 4B). At room temperatures when the exciton peak in reflectance does not appear, voltage modulation is indispensible. (Analogous rotation can also be caused by an "excitonless" Franz-Keldysh effect in the SOL of a semiconductor [110], present review).

but

The ERL rotation was

this issue obtained

is beyond

the scope of

in terms of a theory

the

[17, 18]

which simulated the high-field region (F a F I ) by a uniform dead layer [12] of varying thickness (Sect. 4A). A m o r e adequate description based on adoption of the actual variation of the electric field with coordinate z (Sect. 6A) and assuming a gradual variation of the resonant frequency and of exciton damping with Z was proposed in [56,111], the calculation method has been given in Sect. 4E). In these studies an account was taken of the fact that the layer free of excitons is formed near the surface due to high probability of the field dissociation of the exciton (and not to an abrupt change of the exciton resonant frequency ~0 [17,18] ). Besides providing a reprodution of the effect of the ERLrotation, these calculations have also predicted or confirmed a variety of effects in the exciton reflectance spectra (see below). Other models were proposed to describe the exciton behavior

256

A.E. Cherednichenko and V.A. Kiselev

the near-surface field. In ref. [53] the field dissociation of the exciton

was

assumed

to depend

exponentially

on

coordinate.

The

probability of the field dissociation was found to decrease with flattening

of

the bands

near

the

surface.

Lagois

[54] using

a

three-layer approximation has derived the exciton potential, again relating Balslev

this

to a

strong near-surface

[87] used the exponential

screening

length,

to

describe

field.

Schultheis

term exp(-z/d),

the

coordinate

and

d - being the

dependence

of

the

field strength. Intrinsic mechanisms of the transition layer formation were

taken into consideration and variational method was

used to specify the adiabatic potential. Eleotrodynamic equations including

those

for

the

exciton

polarization

have

been

solved

numerically. The calculation has confirmed the possibility of the ERL

enhancement

and,

as

well,

Besides,

the

with the

variation

of

alternative

calculations

the near-surface

mechanism

performed

in

of

field

spike

[87]

formation.

yielded

structure typical of very wide and shallow wells

[111]

the

ERL

(see Sect. 6G),

the result to be expected in view of the assumptions made: d ~ 400 nm

and the field at

Sect.

6B).

near-surface

The

increase

excitons

essentially affect was

the surface not by

in

the

such

justifiably neglected

value

fields

the ERL, hence, [87].

in excess of 0 . 3 F I of

damping

is not

yet

(see

of

the

sufficient

to

to a first approximation,

it

Schultheis and Lagois

[88]

took

account of both the resonant frequency shift in the field, varying with coordinate as

(z - w) 2 and the damping, which,

was assumed exponential. The way in which the

as in [53],

ERL is affected by

the parameters of the SOL in GaAs crystals has been considered. Lowering of the exciton resonant frequency near the surface due to the Stark effect may lead to localization of the exciton as a whole in the potential well thus formed [78,29] (manifestations of the

exciton

localization

in

the

photoluminescence

spectra

have

been discussed i n s e c t . 5). Apart from field effects an impact ionization of excitons near the

surface

structures

can (see,

be e.g.,

scope of the review.

observed [53])

due but

to these

current effects

flow are

in

contact

beyond

the

Excitons at Semiconductor Surfaces

D.

257

Exoiton refleotivity in the case of thin SOLs In

this

section

calculations

the

results

will

for the An= I exciton

in a

[56,33]. The calculation procedure, proceeds the

from defining

exciton

resonant

presented

of

ERL

CdS crystal with a SOL

that has been outlined above

the functions

frequency

be

shift

A~o(Z) and

and r(z)

damping,

Outside the SOL, i.e., at z ~ w , one has A~ 0 = 0

which are

respectively.

and P = F O, the

latter being the exciton damping in the bulk of the crystal. If a field variation near the surface F(z) is known (see Sect. 6A) then the functions A~o(Z) and r(z) may be readily determined (see Sect. 6B). For a linear field variation two

values

of

w

the

resonant

(6.1), N D - N A = I016cm -3 and

frequency

shift

and

damping

as

functions of z are shown in Fig. 36 [56]. It is seen from this figure that A~o(Z)

forms a potential well

and r(z) increases towards the surface producing a physically dead layer

for

excitons.

For

larger

surface

fields

Ps

(which

is

proportional to w) the curves for A~ 0 and P are shifted as a whole along

the

surface

z-axis.

(Fig.

36b)

Eventually, where

A~ 0

a

layer may

and

r

are

adiabatic conditions are not warranted.

develop

not

adjacent

definable

However,

and

the the

this region is

inaccessible to the exciton and various attempts to determine A~ 0 and

r

there

have

had

little

effect

on

the

result

of

ERL

calculations. In calculating the ERL the following parameter values were used [38]: ~0 = 20590.2 cm -1 ~LT 15 cm -I ~0 9.5, M 0.78 mo, 9.3 [112], where ~0 is the resonant frequency of the An=1-exciton , ~LT' the longitudinal-transverse splitting, dielectric permeability in a region of translational optical

axis

mass O

of

, m O,

the

electron

the free

moving

~0' the background resonance, M, the at

electron mass,

a

normal

and ~,

to

the

the static

dielectric permeability. For the given parameter values the result of ERL calculation is defined by any two of the three SOL parameters: F s,

the SOL

thickness w,

and

the centers

the surface field

concentration N + - N-

258

A.E. Cherednichenko and V.A, Kiselev

r c~ t i

Z00 a

b

Z,~m

° V,.7°., -10 ~ I~

I

I"%1

I

-20 -,.Jx.L/ AUJO ~rlz "1

Fig. 36. Damping and resonant frequency shift A(0 of the exciton in the Shottky barrier on a CdS crystal; a -IV, b - 2.8V. which

defines

the

space

charge

density.

ERLs for a variety of combinations

of

We

have

(N +- N-,

calculated w) values,

the some

examples are given in Fig. 37 (for N D - N A equal to 2-1017cm-3(a), 5.1016cm-3(b), and 1 . 1 0 16cm-3(c)), more will be presented in Sect. 6G. With respect to their peculiar features all ERLs may be divided into types plane, Fig.

I, II, III, and IV. If mapped on the

38 by

bold

curves.

origin of coordinates (N+ - N-). certain of

(F s- w)

each ERL type is confined to a well-defined area shown in

Of

the

Thin

("rays")

sets

straight

lines

coming

out

of

the

correspond to different values of

of ERLs

in Fig.

37

each

corresponds

(Fs, w) points on a particular ray which means

to

constancy

(N+ - N-). The numbers at each curve indicate the values of w

in nanometers. fine structure,

Area I in Fig.

38 contains

spectra

exhibiting no

the examples are the spectra for w = 0.12

in the

first row, w = 10, 27 in the second and w = 20, 50 and 70 third row in Fig. spike

37. Area

II

contains

the ERLs with

in the the left

(see Sect. 4 ) i.e., the one to the left of the reflectance

minimum

( for the chosen direction of wavelength increase).

These

Excitons at Semiconductor Surfaces

259

a

ioI ? 0.6

0.4

Iz

0,2 0

0.~

Fig. 37. 0alculated ERLs for the A(n=l) - exciton in a CdS crystal calculated using a model of the Shottky barrier for different w values and at three values of N D - N A (see text).

are exemplified

in Fig.

the first row and

37 by the lineshapes

for w = 17,

18

in

w = 30, 31 in the second one.

It is important to note that the left spike is accounted for in our calculations assuming reasonable values for the bulk damping, say, ~

= 0.Scm -I ~ 0.1 meV

(the value used in

computing

all

of

260

A.E. Cherednichenko and V.A. Kiselev

F0 / 0.5_

05

0

,*5

5O

75 -~

w, nrn

Fig. 38. Contour plots of constant Rma x value (thin curves) and areas

(I, II,

III) of characteristic ERL behavior on

the (Fs-W) plane. Straight lines correspond to constant values of N +- N- in units of 1017 cm-3; ~F O = 10 -4 eV.

the

spectra

in

measurements

Fig.

of

37).

the

Close

forbidden

value

has

exciton

been

obtained

linewidth

from

[12],

and

longitudinal exciton linewidth [27] at liquid helium temperatures. On

the other hand,

the

spike

of

such a

shape

explain within the uniform dead-layer model substantially [19,22].

lower

values

In addition,

(~ 10-5eV)

in our model

of

damping r increases towards the surface very

high

values,

for

instance,

190

for the

respectively,

in Fig.

37.

The

difficult

the

exciton

to

damping

transition layer

the

(see Fig. 36) and reaches cm -1

linesh~pes with w = 18 nm in the first row and second,

is

[12] as it requires

and

30

cm -1

for

w = 31 nm in the

observation

that

for

the

Excitons at Semiconductor Surfaces

left spike to appear the damping should

261

not at all be too

low

attests

the mechanism under consideration as more realistic

than

the one

discussed

in

[12].

In particular,

a serious

discrepancy

between the values obtained from experiments on reflectance and on luminescence Area

III

[19] gets an explanation. in the F s- w plane plane

right spike

contains

the ERLs with

the

(see w = 20, 22 in the first, w = 33, 40 in the second

and w = 75, 80 and 90 in the third row of Fig. 37)

as well as the

"reversed" ERL. The effect of the ERL reversal (or rotation) demonstrated in Fig. 39 for N + - N- = 1016 cm -3. The effect

is is

seen to start with an appearance of the right spike and follows in its major features the predictions of the uniform dead layer model [18], though detailed agreement

is lacking. Area III, as well as

area IV, featuring small F s and large w values shall be discussed at length in Sect. 6G. Here we will concentrate on areas I and II, i.e.,

restrict

ourselves

to

fields F s around 104 V/cm

the and

cases

of

w

w ~ 25 nm

~

10 nm

with

with

the

F s around 105

V/cm, in conformity with this section's title. Besides

producing

the left

and right

spikes,

the near-surface

field changes reflectivity coefficients at the ERL extrema and Rmin)

stretches

the spectrum over greater

Fig. 37. These changes may be mapped on the F s-

w

drawing

values

curves,

parameters. constant

corresponding

As an illustration,

reflectivity values

to

(Rma x

energy range, s e e

constant

we show in Pig.

plane too, by of

ERL

38 contours of

at Rma x with a spacing between

the

curves ARma x = 0.05 . It is seen that Rm~ x as a function of F s and w has a peak value of 0.82 at F s = 0.25.105 V/cm and w = 27 nm, that is, Note,

the ERL is enhanced at these values

that at the values of F s and w close

of the parameters. to the above

quoted

there also occurs peak in R m n i (see Pig. 37). In the next section we demonstrate that the most likely cause of the ERL enhancement is the quasilocalization

of

the exciton at a near-surface

Stark

well. The presence

in the spectrum of

the anomalies mentioned above

(enhancement, left and right spikes) sets the following limits on SCL parameter values (for CdS):

262

A.E. Cherednichenko and V.A. Kiselev

Ri

~_

0.3 0.2 0.1 0 L~550

!i -

20600 20550

f

2060O oJ ~ C1~ t

Fig. 39. Reflectance of a CdS crystal in the vicinity of the A(n=1) -exciton for different values of the surface potential ~s V: a)- O, b)- 0.065, c)- 0.1, d)- 0.2, e)- 0.5, f)- 0.75.

104 <~ F s ~< 105 V/cm , 10 <~ w ~< 102 nm , 1016 ~< N + - N- ~< 5-I017cm -3

(6.5)

Many of the results of experimental investigations on exciton reflectance discussed in Sect. 4 can be understood in terms of the effect of SCL. For instance, two very similar F~Ls for w = 70 and 80 mm in the third row of Fig. 37, the latter featuring the spike and the former having none, may be compared to the spectra from the paper by Permogorov et al. [32]. In that stud~ the spectrum with the spike has been obtained umder intense illumination of the sample, which could, for example, produce charging of surface states [113] or cause a slow (frozen-in at low temperatures) recharging of the centers in the SOL. Below, we consider at some length the effect of preliminary illumination described in [33J. Short exposure to light also makes w somewhat larger but changes

Excitons at SemiconductorSurfaces

263

of the ERL will be different in cha1~aoter and similar to those in the first row of Fig. 37. It is natural to suppose that these different kinds of behavior arise from differences between the (ND - N A) values in the crpstals under study. Evangelisti et al. [18] and, especially, Patella et al. [15] stressed that the intensity of the spike is not rigidly related to that of the main reflectivity peak Rma x as the uniform DL model would have implied [12,18]. This subSect has been already discussed in Seat. 4, and a new mechanism of spike formation should be suggested, namely, the one that assumes the existence of a potential well for the exciton near the surface. In the model of the transition layer for the exciton considered here the above well apRears as the S~ark well produced by the nea~-surface field (see Pig. 36). Indeed, as seen f ~ m Pig. 37, with variation of the SOL pa1~ameters the relationship between Rma x and spike intensity might be most diverse. AS indicated in Sect. 4, by subjecting the surface to electron bombardment a varied and complex influence is exerted on the near-surface region and, consequently, on the exciton reflectance, It seems, though, that in some cases chauges in the ERL are q u i t e definite in character and ma~v be related to o h ~ e s in SOL parameters. So, after small (undestructive) doses of electron irradiation there is observed a conversion of the right spike into the left one and back, the ERL enhancement and at greater doses the ERL rotation is revealed (see Pigs. 9,10). The values of Rma x and Rmi n may also be changed by varying temperature (see Pig. 14). it is of special interest that as the temperature is raised from 2 to 30 K the value of R m i n may drop to practically zero, as reported by Pevtsov et al. [27]. This is contrary to the result of the calculations assuming an increase in PO provided no transition layer at the surface is taken into account, Bearing in mind that the SOL may undergo changes with temperature variation the outlined behavior is no longer surprising. For example, for w = 70 and 50 nm, in the third row in Pig. 37, the value of R m i n drops frc~n 4.6% down to 0.24% while the lineshape remains essentially the same. Another, more definite

264

A.E. Cherednichenko and V.A. Kiselev

interpretation of such behavior will be put forward in

Sect. 6E

where the dependence of the reflectance spectrum on the damping in the bulk PO is considered. There was investigated the influence on reflectance spectra [33] of preliminary exposure Fig.

to light with k ~ 51Ohm

(see Sect.

40,

15). Reversibility and reproducibility of the results prove

that

the major

various

effect

electronic

parameters.

These

of

states

illumination was with

experiments

that

resultant have

given

of

recharging

changes

in

evidence

SOL

of

a

quasilocalization of the 3D exciton revealed through reflectance spectra. Modifications of the ERLs with increasing amount of preliminary illumination Fig.

40.

The

(time of illumination in minutes) illumination-induced

changes

are displayed in

persisted

at

liquid

helium temperature for long enough, so that in the course of the reflectivity measurements, with the use of a probing light of very low

intensity,

the

SOL

configuration

remained

essentially

unchanged. As seen in the figure, the experimental spectra display all the major features

that appear in the calculated spectra of

Fig. 37, namely, the ERL enhancement followed by the emergence of the left spike, with an accompanying decrease (Rmin)

and by stretching of

the ERL along

(increase) of Rma x

the frequency scale.

Then the ERL is again enhanced and the reflectance damped. Such a complicated behavior of the ERL under illumination indicates that the corresponding trajectory in the

F s- w plane (Fig. 38) must be

very intricate as it should pass twice the area of high values of Rma x at exposures of 5 and 15 minutes. Modifications of the ERL at fairly low exposures to light

(0.5

and 10 rain) correspond best to a set of lineshapes seen in the upper row in Fig. 37 for which N +- N- = 2.1017 cm -3 and w = O, 12, 17 n m , though, of course, the trajectory might be, as well, both more steep (like the one for N + - N- = 5"1017 om -3 and more sloping

(as for F s ~ 105 V/cm).

trajectory starts

from Area

I,

Still,

it is certain that this

then passes

through a region of

fairly high Rma x values and finally enters region II where F s 105 V/cm. From here variations of SOL assume different character.

Excitons at Semiconductor Surfaces

R

0.3

F fO~n

265

f 2O

o.2[

/

p

Fig. 40. Modifications of the ERL of a CdS crystal at T=4.2K caused by preliminary illumination (of. Fig. 15).

One of the most likely reasons for the growth of F s and w at low doses of illumination is charging of surface states [113]. This seems

to be

minutes,

also

the reason

times of relaxation

for fairly

long,

to the initial

of

state.

the order

of

A 10 minute

exposure completely fills the surface states. Longer exposures lead to flattening of the bands, with the band bending region receding towards the surface. Flattening is effected by photogenerated pairs of carriers when these get separated in the near-surface field and driven toward the low field region (electrons) or the high field region (holes). The electrons will be captured by ionized donors thus decreasing the space charge density in the low-field region while the holes will be captured

266

A.E. Cherednichenko and V.A. Kiselev

R 0.5

0"3

n

0.2-

V 0.1

--

0 Fig. 41. Modifications of the ERL in the vicinity of the A(n=1)- exciton induced by various doses of 3.5 keV electron irradiation.

by charged aeeeptors, surface.

The holes,

increasing the space charge density near the in addition,

might be captured on the levels

of the 2D quantum well on the surface, acceptors

are

completely

filled.

As

both during and after the

calculations

show,

10 5 V/cm and w of the order of tens of nanometers series of two-dimensional To

establish

circumstances self-consistent

the is

a

subbands separated by

spatial

distribution

difficult

task

that

of

manner and requires knowledge

Therefore,

a

calculated

on the model

comparision

of

the

assuming

may turn out to be inadequate.

the

must

Nevertheless,

Fs ~

there exists a

~ 10 -2 eV. field be

in

solved

these in

a

of many parameters.

experimental a linear

at

ERLs

decrease

with of

those

the field

it is clear that the

Excitons at Semiconductor Surfaces

exposures average,

of

interesting control,

15,

hence

20

the

that

and

30 min

repeated

in

some

make

the

enhancement

267

field weaker of

experiments,

the

where

on

ERL.

situation

is

evade

this enhancement is accompanied by transformation,

that the left spike gives place to the right one,

the

It

such

see Fig.

40,

which implies that the descending part of the trajectory on the F s- w

plane transverse Area II in Fig. 38.

Very much doses

of

irradiation

crystals. this

similar modifications with

These are shown

case

the

of

the ERL result

electrons

of

the

surface

(for the same sample)

experimental

ERLs

compare

from of

in Fig.

best

to

a

small CdS

41. set

In of

lineshapes calculated for N + - N-= 5-1016 cm -3. It is evident that these lineshapes belong to Areas II and III of the F s - w plane as they

display

demonstrates

all that

the

typical

the surface

anomalies. is being

The

ERL

modification

charged negatively when

subjected to electron irradiation.

E.

Quasilocalization of excitons in the SCL field and the effect

of damping In the preceeding Section we have shown that for thin

SCLs ( w

~< 102 nm for CdS) the reflectivity in the vicinity of the An= 1exciton

might

be

expected

to

enhance.

An

anomalously

high

reflectivity may occur both in as-grown crystals and after some external

factor

has

been

applied.

The

reflectivity has been actually observed,

enhancement

of

the

some examples have been

given in Sect. 4, more will be discussed below. The effect under consideration was

found to be related to a feasibility for the

exciton to be localized by the SOL [78]. Fig. 42a shows grafs of A(~o(Z) and r(z) for N + - N- = 5.1016 cm -3 and w = 31 nm. A corresponding ERL in Fig. 37 is strongly enhanced and features the left spike. We note Fig.

that the lower part of the curve A~00(z) in

42b may be approximated with a triangular and show in this

figure two lowermost levels of the calculated using a known formula:

triangular well

gO

and £1'

268

A.E. Cherednichenko and V.A. Kiselev

r , cm -t

20~

a b

gl

f

/

0

/

-10 -2D

!

0

10 ,~U.)o~Cm-t

20

30

Z,~

Fig. 42. (a) The resonant energy shift A~ and damping F(z) for the first ERL of Fig. 46. (b) A~(z) for the potential approximated with a triangular. C O and C I are the bound states.

[

3~e

e~ =

Fs

3 ] 2/3

(~ + ~)

(6.6)

,

2v' 2M

where F s is not the electric field at the surface but a quantity defined as

~ o (z) i Fs : B ~-~ Iz=O

(6.7)

As seen in the figure, with the parameters as indicated,

the gO

level occurs somewhat below the edge of the real potential well. In

other

words,

an

enhanced

ERL

points

to

the

presence

of

potential well, sufficient to localize the exoiton. Simulation of a real potential with a triangular one gives, course, Yet,

only a crude estimate of the level position

a more

the magnitude

accurate of

calculation

P(z)

near

seems unnecessary.

the surface,

this

a of

in the well. To

level,

judge by due

to a

Excitons at Semiconductor Surfaces

269

high probability of the field dissociation of the exciton, spreads over the energy

interval

that exceeds

the binding energy of

the

exciton in the well. We have, in fact, dealt with the ERL enhancement due a single level. At concentrations N +- N- greater than 5.1016 cm -3 the enhancement looses in strength (see Fig. 38) as the potential well gets narrower while its depth is limited to a value ~ O.IIEII

(or

about

the

3

meV

contrary, of

for

CdS).

For

lower

values

of

N +-

N-,

on

the wells become wider and more levels for localization

excitons

may

arise.

At N +- N- = 5"1016

cm -3

the

levels

are

separated by more than I meV (see Fig. 42) and at N +- N - = I016cm -3 the separation between the levels is estimated at a few tens of a millielectronvolt. ERL

enhancement,

as

seen

With several levels in the well

in

Fig.

37,

is

less

pronounced

arises at larger w values. At still lower N + - N- values cm -3)

the levels

in the well

form a continuous

the and

( ~ 1015

spectrum and the

effect of enhancement is no longer observed. A

conclusion

to

be

drawn,

that

is

very

important

for

interpreting the ERL anomalies observed,

is that because of large

r

does

values

the

near-surface

detectable structure

field

not

produce

of the main reflectivity peak whatever

any the

value of N + - N- . Still, we may expect that some structure could be detected using differential technique. This hope finds support in the results of calculations

[56]

the behavior of reflectivity at

(for

N + - N- = 1016 cm -3) of

some fixed frequency from within

the resonance range as a function of the surface potential width,

w

oscillatory

).

The rather

reflectivity than

measured at a fixed frequency It is natural

has

monotonous

been

found

character.

The

to

(or SCL have

(20600 cm -I ) are shown in Fig.

to relate each successive peak

an

pulsations

to an emergence

43. of

one more level in the Stark well. This conclusion is oozu~oborated by estimates of the strength of the corresponding potential well. Experimentally,

the

ERL pulsations have been observed on a CdSe

crystal subjected to small irradiation

that

produced,

(and increasing) primarily,

exposures of electron

alteration

charge. The variation of R is presented in Fig. 44.

of

surface

270

A.E. Cherednichenko and V.A. Kiselev

R 0.4

0.2 I

I

0.1

0.2

I

0.3 )llZvllz $ 1w

Fig. 43. Pulsations of the reflectance in CdS at a fixed frequency with varying ~s (calculated).

R

0.6-

0.¢ 0.~ 0.2I

I

I

I

I

5

I

I

1 I

I~1

fd'fO

I

I

ZO JO

I

4O

Fig. 44. Variations of the reflectance at a fixed frequency in a CdSe crystal with increasing electron irradiation dose at T=4.2K.

Excitonsat SemiconductorSurfaces

271

A feasibility for the exoiton to be localized by the space-charge field settles one of the long-standing problems of excitonic spectroscopy. Quite often, reflectance spectra exhibit strongly enhanced structure for the An= I- exciton, including the spike and an unusually high value of Rmi n, whereas the structure for the Bn= I - exciton retains its usual appearance. This seems strange as the intrinsic properties of the A- and B- excitons are very similar. Differences

in the ERL for these excitons were observed

on virgin high-quality CdS surfaces [12,18] oriented both along and normal to the OdS optical axis. We have observed these differing

ERLs

upon

small

doses

of

electron

irradiation

(Figs.

9,10).

R

Ot

An=l 8n=I

/

/

/

b

An-1

,/~ Bn,,,t

F

0.1I I I I I I I

I

I

I

I~,I

6?9 "

I

i

I

670

I

669

~, n m Fig. 45. ERL of CdS (a) and CdSe crystals (b) after small dose of electron irradiation at T=4.2K.

272

A.E. Cherednichenko and V.A. Kiselev

Characteristic low-fluence

spectra

electron

can be made

is much more sensitive

has

localization

on

the

and

CdSe

are given

crystals in Fig.

conditions

45.

From

the

than that of the

consider the effect the damping in the

reflectance

spectrum

which

of the exciton by the SOL field

the calculation

following

that the ERL of the An= I- exciton

to the surface

Bn= I - exciton. To explain this behavior, r0

OdS

bombardment

figure a conclusion

bulk

of

are presented

in Fig.

case of N + - N- = 5-1016 cm -3 and

corresponds

[78]. The results

46 for the above

w = 31 n m .

to of

considered

With tO= I cm -I the

ERL displays anomalously high Rma x and R m in values and the presence of the left spike, with P = 2 and 5 cm -I there is no spike and Rma x and Rmi n are less. At F = 10 cm -I ERL responds no

transition

that

layer

were

the B- exciton

exoiton.

and 20 cm -I the

to the increased damping in a classical manner,

Hence,

present.

is damped

the

first

to the A- exciton and, the spectra in Fig.

So,

several

lineshape

e.g.,

the

it

is

times

in Fig.

third one

natural

stronger 46 should

to

suppose

than

to the B- exciton

R

0.6 0.4

0

2 =lC

5

10

the A-

correspond

45 get explanation.

O.Z

as if

?.0 ~-~

Fig. 46. Modification of the ERL of a CdS crystal with increasing the exciton damping PC in the bulk.

and

Excitons at Semiconductor Surfaces

273

The same reasoning may be used to interpret a drastic decrease of

R mn i

with

rise

Pevtsov et al. increased

of

temperature

from

2

to

30 K

observed

[27], - see Pig. 14 (at higher temperatures

in

a

usual

way,

same

as

in

Fig.

46).

by

R mn i

Analogous

explanation may be given to a non-monotonic dependence of Rmi n

on

excitation intensity [114].

F. The effect of SCL on the phase of reflected light So far, we have been coefficient R

, which

concerned only with

is an

the reflectivity

intensity ratio

of reflected and

incident light: R = Ir/al 2 Yet,

r/a

is

a

complex

quantity

(6.8)

characterized,

alongside

the

module, with a phase: r/a = Ir/a i e(~ where ~ has

the

sense

of

a phase

,

shift

(6.9)

of

the reflected wave

relative to the incident wave. Frequency dependence of 9, as well as

of

E,

resonance

exhibits and,

in

peculiarities essence,

in

should

the

also

be

region

of

exciton

sensitive

to

the

transition layer at the semiconductor surface. A "non-classical" phase behavior has been reported in a number of papers

[115-120,

31]. The frequency dependence of ~ in the vicinity of the exciton transition has been found to deviate markedly from the calculation that neglected both the transition layer and spatial dispersion, as seen in Fig. 47 (curve c). This dependence is either S-shaped and

shows

resonance

a

step-wise

[116]

(Fig.

change 47,

by

curve

2~ a)

in or

the

region

N-shaped

of

exciton

and

has

a

pronounced negative dip in the short waves [117] (Fig. 47, curve b). The non-classical phase variation can be adequately reproduced within a theory that considers

the uniform dead layer

(DL) and

274

A.E. Cheredniohenko and V.A. Kiselev

2~

0 =

b

Fig. 47. Types of the frequency dependence of the phase of reflected light near exciton resonance. a) non-classical S-shaped; b) non-classical N-shaped; c) classical; b and c may be derived from a if the damping F 0 is incresed.

•

I 0

5OO

I 1000 W ~ nnt

Fig. 48. Areas (I-III) of characteristic ERL behavior. Curves I to 5 correspond to an appearance of the first and subsequent spikes. + Thin ~ l i n e s correspond to constant values of N -N-(~IO'~).

Excitons at Semiconductor Surfaces

[116-119, 31]. The type of frequency dependence

spatial dispersion to

be

expected,

275

S

or N

, is governed

by

the

exciton

damping

[117,119]. An uncertainty remained, however, concerning the extent to which the DL in the spirit of the

Hopfield and Thomas model

essential

the

in

Regrettably,

accounting on

for

other m o d e l s

lacking, nevertheless,

observed

such

an

phase

[12] is

peculiarities.

exhaustive

analysis

is

the question raised may be answered right

now: the uniform DL serves a good approximation of real transition layers

as

regards

the phase,

though

this

model

should

not

be

considered as ultimate. Our results are as follows: i) with OdS crystals having N + - N- > 1016 cm -3 , which exhibit ERL rotation at

strong

bending

of

the

bands

(Sect.

6G)

and,

consequently,

possess a sharp enough DL boundary, even at small w values, sufficient for the ERL enhancement to begin,

- see Fig.

just

37,

the

S-type phase will be observed (Fig. 47, curve a). ii) In the ease of N + - N- < 1015 cm -3 when the real DL boundary is diffused and no ERL rotation occurs

(Sect. 6G) a model incorporating only the

SCL gives

differing

results

dependence - Fig. such

crystals

behavior, mechanisms considered,

not 47,

curve c. Therefore,

(not yet

their of

essentially

available)

interpretation the

iii)

exciton If,

reveal

would the

the

classical

should experiments on a non-classical

require

transition

initially,

from

that

layer

phase

is

phase

intrinsic

formation B-shaped

be (Fig.

47,curve a), then by introducing greater bulk damping ro into the SOL

model

classical

one phase

obtains (curves

the b,c).

N-shaped iiii)

and, The

subsequently,

latter

event

the

occurs

simultaneously with the disappearance of the ERL enhancement

(see

Fig. 46). At r 0 = 1 or 2 cm -I the phase is S-shaped, at r 0 near to 5 cm -1, when Rmi n turns zero, a line tangent to the phase curve at = ~L becomes vertical signifying the transition to N-type. These developments reproduce the

excitonic

Brewster

effect for normal

incidence described earlier on assumption of a uniform DL

[120]

and explain completely the results concerning the dependence of Rmi n on temperature and also the temperature dependence of ~ [27].

276

A.E. Cherednichenko and V.A. Kiselev

G.

Exciton reflectance So

far we

dealt

with

thin space charge and

II

wider

of

layers

with

w

that

at

effect

(SOLs). plane

values

these are represented noteworthy peculiar

the

the F s - w

layers,

important

in the case of wide SCLs the

in Fig.

by Areas

exciton

reflectance

Those are represented

up

larger

on

to III,

w

38.

103

Now we

nm.

On

IV and V

lower

N+

by Areas

shall

the

N-

consider

48).

values

It is

are

since just the shallow and wide potential wells to this N + - N- range produce a nontrivial

I

F s - w plane

(see Fig.

-

of

more

that are

ERL structure.

Fig. 49 shows ERLs, typical of a wide SCL, calculated for the N+-N - values of 1016 (a), 3-1015 (b), 1015cm -3 and ~ = 10 -4 eV by the method presented above. 49a and Fig. The

main

39) the ERL displays

reflectivity

peak

whereas

the minimum

a maximum,

as well

shifting

is similar

(see Fig.

to

the

surface. less the

sharp

than 10 nm) exciton

effect.

(~

is large

calculated

102

nm)

The ERL rotation

coefficient

enough

calculated

the

ERL

values

rotation. the

The

pulsations

pattern

of ERL behavior

of

curves

the

appearance

in

( ) 1016

makes

possible

Area, right

this

in

Fig. 6E

to Area

III

3 .....

spike which

reflectance peak moving to long wavelengths.

is of

interference

the reflection in the

curve will have an

Sect.

2,

layer

wavelength

the

in

I,

In the

the boundary

with

shown

corresponds

al.

near

at some fixed frequency

discussed

of a successive

of

The resultant

is

et

thickness.

cm -3)

a period corresponding

curve

this

This

of exoitons

(the spread

or measured

character with

and so on.

being the layer of a heavy

can be characterized

region of the exciton resonance. oscillating

into

to the characteristic

which

and

turns

by Evangelisti

dissociation

inner boundary

in relation

(see Fig.

wavelengths

spectrum

dead layer of variable

caused by field-induced

has a rather

long

to long wavelengths, one,

6) for a uniform

When N + - N-

to

of the initial

our case the DL is of different nature, damping

cm L~

a rotation when w is increased.

shifts

disappears picture

For N + - N- ) 1016

to one cycle of 50

(at

are

in Pig. is

small

seen).

9s

This

48. Each

related

then develops

to

an

into a

Excitons at Semiconductor Surfaces

277

c

b 0.6

0.4

w-6OOnm: to

-130Nn 900

0 ZOO

260

-"

~0520

|/I

I-~'"

20600

%..,~11,-.-I

20500

I-. 2000

20600

20560

20600

U,4 Grit"1---,,Fig. 49. Theoretical ERLs for the A(n=1)-exoiton in a CdS crystal calculated using a Shot~ky barrier model for different values of w and three values of N - N- (see text).

In contrast to published results [18]

(see Fig. 6) the amplitude

of oscillations dies out with distance from the origin of the F s w

plane. At the boundary of Area V (see a wavy curve in Fig. 48)

it is 1/10 of

the

non-uniformity

of

initial value. the SCL

field.

This

effect

However,

is related

to the

in experiment

it has

been found even stronger than our theory predicts. The ERL rotation was observed on a number of semiconductors GaAs [25,108,109], InP [17], CdS [107,19,121] was

applied,

using

[17,25,121,108,109], irradiatied

with

or

semitransparent the

electrons

metal

semiconductor [19]

(see

:

. Either the voltage surface

Sect.

4B).

electrode (CdS)

was

With

the

metal/OdS structure [121] it was possible to observe just a little

278

A.E. Cherednichenko and V.A. Kiselev

0./~ 0.3 0.2 0.1 0 B

I

o

I

0.5

,,I

1.0

1

1.5

2.0

Fig. 50. Variation of the reflectivity coefficient R of a CdS crystal at a fixed frequency in the v i c i n i t ~ of resonance of the A(n=1)- exciton (20600 cm ").

more than one ERL reversal

and the peak-to-peak

amplitude

of ERL

decayed noticably faster than it follows from our calculations. least

two factors may be responsible

of the resonant

structure

of the density of states electric

field,

use

of

the

band

the

symmetrical

arises

from

in reflectance.

One is the asymmetry

distribution which appears under

see Sect.

6B.

It is to be recalled

Lorentzian large

parametrization.

spreading

At

for the rapid disappearance

of

the

strong

that we made Asymmetry

levels

of

of

excited

states under applied field and their merging into the continuum of states.

With

increasing

field

the

continuum

encroaches

band of the exciton ground state as well,

see Fig.

physical

getting

DL

can

transparent.

The

not

the excitonic structure less conspicuous. The

second

structures

cause

of (see,

considered

as

(unstructured)

at

the the

more

hig~

and

fields

more makes

in the density of states of deeper layers

This conclusion is confirmed by the experimental

data on absorption occurrence

be

absorption

upon

34. Hence,

[121]. of

impact

the

rapid

ionization

e.g.,[63,53]),

decay of

of

the

ERL

the

exciton

the process

largely

may in

be

an

barrier

dependent

on

Excitons at Semiconductor Surfaces

279

the physical nature of a metal-semiconductor contact and on the intensity of incident light. Essentially different ERL behavior is obtained values,

around 1015

corresponding

cm -3,

as seen

in Fig.

at low N + - N-

49o.

In Fig.

48 the

area is Area IV . At large enough w , same as for

high N + - N-

levels,

after another,

there appears

a sequence of spikes,

represented by curves I , 2, 3,

... in

one

Area IV.

But, in contrast to the former case, the spikes may accumulate in the reflectance spectrum giving rise to a multi-spike structure. With further increase in the value of w the spikes are vanishing in order of appearance. Area IV encompasses ERLs which display no rotation but are characterized by the shift of the main peak to long

wavelengths

and

rotation does not

by

reduced

peak-to-peak

take place because

amplitudes.

The

the function r(z) has

the

form of a gradually sloping tail whose characteristic dimension by far exceeds kex c (kexc ~ 10 nm), i.e. the field is nearly uniform in this case. The shift of the ERL maximum to long wavelengths is a

consequence

of

a

field-induced

lowering

of

the

resonant

frequency. The boundary separating Areas III (rotation) and IV (multi-spike structure)

is not

transition between illustrated by spectra

is

the

In

two

w

intermediate of

spectra

structure further

the types

reflectance

the

increasing

sharp.

to

to

the

region

behavior

in Fig. red

long

ERL of

49b. ~L

wavelengths

a

is Seen

which

smooth

observed, in

these

moves

and

with

gradually

disappears. When crossing o v e r from Area III to IV the role of the damping

P(z) gets appreciably reduced whilst that of the lowering

of

resonant

the

frequency

A~ O(z)

near

the

surface

becomes

dominant. This has a bearing on the structure produced which may be

interpreted

quantization structure

in

of

excitons)

arises

dispersion is

terms

of in

interference the SOL

irrespective

taken into account,

of the

of

of polaritons a

(or of

semiconductor.

whether

or

two cases

not

The

spatial

differing only

quantitatively. As regions of shallower and wider potential wells are entered (Area IV), the excitons of progressively longer wavelengths get involved in quantization, so that the additional

280

A.E. Cherednichenko and V.A. Kiselev

structure Fig.

becomes more closely spaced and moves nearer

The

ERL

region

features

have

structure may,

pertaining

been

to Area

observed

observed

across

in a number

spectra

the

of

observed

transition

CdS

crystals

. Often,

the main

multiple

reflectance

IV

and

experimentally. of

in the first approximation,

light

on

CdSe

SCL

macroscopic

intermediate [88].

be attributed

layer a

assumed

two-spike

spikes

peak

region

These

spectra

(see Fig.

49b)

have

fitted

Evolution

of

the

ERL

typical

of

Au-CdS

barrier structures with a

reverse

bias.

excitons

Representative

are seen

in Fig.

(Figs.

[29]),

been

a

IV

can

the

increased

magnitude, On

the

(uniform)

estimated at

to dissociate

as

still

agreement cm -3,

hand,

when

for

observed

the

the SGL

more.

The

field

to

the

is non-uniform

lineshape

the

theoretical

see Fig.

490.

The shift

alteration

calculation

the

A-

and

B-

feature

is

peak shifts

amplitude crystal,

to about

to a value calculated for w = 2000 nm. and the

= 2000 nm.

The

above value of N + - Ndisappearance

also adequately described.

of

the

for by as

its

is insufficient

SOL

of

a

observed

for

N +-

~IO-4cm (f ~ I).

the ERL

of the reflectivity

at a 4V bias amounts

on

6B).

confined

with

wavelengths 4V

that

can not be accounted

within

(see Sect.

GaAs

the field may be an order of magnitude higher,

In addition, smeared

field

on

distinctive

F < 104 V/cm or f < O.1,

the exciton

other

thickness

the

This behavior

the

electrode under

peak-to-peak

with

diminishing.

of

theory

be

semitransparent

Their major

besides

similar to ours.

to

wavelengths,

be

indicating

obtained

using

The main reflectance

long

also

typical

the absence of the ERL rotation. lineshape

the

other factors

well

Area

may

of

In

by a structure

spectra

have

12,13)

to interference

12 and

modifications

51.

multi-spike

structure

Reflectance

been

intermediate

are accompanied

(see Fig.

field.

the

transparent.

assumed wide SOLs and a calculation procedure

of

(see

The

samples

that a theory is needed that would consider the

to ~L

17a).

N-

will

be

is

in

=

1015

peak

to long

40 cm -I which

is close

Assuming the one actually

of the structure

band bending obtains

w

in reflectance

is

Excitons at Semiconductor Surfaces

281

/

A B

2~

~ U : 0 V

I0 20

Fig. 51. ERLs for the A(n=l)and B(n=1)- exoitons as functions of the reverse bias applied via a semitransparent Au-film.

10-

m

Io

1o

~88.0 ~8~.0 x,nm The theory and experiment ~iffer in that the latter provides the evidence of the interference structure located between the A- and B- excitons (see Fig. 51, U = O and 1V). We regard this as one more argument in favor of the necessity to take into account other factors besides the macroscopic field near the surface. On the other hand, the experimental spectra display no multi-spike

282

A.E. Cherednichenko and V.A, Kiselev

structure.

This

fact

is

readily

exPlained

by

larger

exciton

damping to be expected in barrier structures compared to the value used in the calculation (kLF0 = 0.8 cm-1), large damping

being an

immediate cause of the spike dis~ppearance. An important and somewhat surprising conclusion to be drawn from the discussion in this section is that a more pure crystal do not necessarily possess

a more

pronounced

structure

in

the

exciton

reflectance. Let N A be either fixed or small compared to N D , so that the impurity content of an n-type material is dominated by the latter and let N D be lowered. bending

near

the

surface

If there occurs a fixed band

(which

is

typical

of

A3-B 5

semiconductors), then with N D lowering w will increase as (ND NA )-I/2 and F s will decrease in inverse proportion to the same factor.

The

increased

damping w

of

the

may happen

resonant

reflectivity

due

to

the

to outweigh the effect of the reduced

F s. Indeed, as long as F s > F I reduction in the value of F s does not lead to the enhancement of the resonant structure because the excitons in this case do not reach the surface. For example,

in

GaAs Ps does not equal F I until N D - N A is lowered to ~1013 cm -3. One has

to be

aware

yet

that

in measuring

the reflectivity

coefficient the effect of light on the band bending is inavoidable and

unless

the

light

intensity

is

kept

sufficiently

low

the

conclusions made might be in error. In conclusion we note that the exciton spectroscopy can be of great

value

in

understanding

certain

surface

properties

of

semiconductors though the problem of the exciton behavior at the surface looks very complicated. We think that future progress in the issue is intimately connected with the progress in the novel c~-ystal-growth and

surface-treatment

techniques

which

are

being

developed nowadays intensively. The

authors

wish

to

thank

Professor

B.

V.

Novikov

for

encouragement and support of the work and thank the colleages and associates for useful discussions and assistance.

Excitons at Semiconductor Surfaces

283

R E F E R E N C E S

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13.

14.

15. 16. 17. 18. 19. 20. 21. 22.

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284

A.E. Cherednichenko and V.A. Kiselev

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