On fluctuations about non-equilibrium steady states near Gunn instability

Physica 135A (1986) 180-199 North-Holland, Amsterdam

ON FLUCTUATIONS

ABOUT NON-EQUILIBRIUM

STEADY STATES NEAR

GUNN INSTABILITY 1. DENSITY

AND ELECTRIC

A. DiAZ-GUILERA Departamenr de Termologia.

FIELD

FLUCTUATIONS

and J.M.

RUBi

Universitar Autcinoma de Barcelona.

Received

24 June

Bellurerrrr (Barcelona),

Spuirl

1985

Fluctuations about homogeneous and inhomogeneous non-equilibrium steady states near Gunn instability arc studied. Density and electric field autocorrelation functions in Fourier and real spaces are calculated in the framework of generalized Landau-Lifshitz fluctuating hydrodynamics. Some properties of correlation functions as critical slowing down and long-range bchaviour, common for systems away from equilibrium, are obtained. Critical behaviour is also investigated.

1. Introduction Fluctuation theory concerning equilibrium states’) step in its establishment is the Onsager regression fluctuations

decay,

on the average,

following

laws. Correlation functions can be computed tion theorems. They reduce to the value Einstein’s

fluctuation

theory

when

the

is well founded. A crucial hypothesis in which local

non-equilibrium

thermodynamic

starting from fluctuation-dissipaof the moments calculated from

continuum

limit

is removed

(delta

functions are replaced by (AV) ‘, AV being the volume of the cell in which fluctuations take place). On the other hand, light scattering experiments show the validity of the assumptions made because the measured intensity of scattered light agrees with the intensity computed from density correlation functions. As a matter of fact the essential feature leading to the compactness of the theory is the existence of well founded equilibrium ensembles. The situation changes drastically when fluctuations around non-equilibrium steady states occur’). Although non-equilibrium ensembles are not so well established, a generalized Onsager regression law and a generalized Einstein relation can be formulated. However, some properties valid at equilibrium, as time reversal symmetry or translational invariance, are in general lost. Moreover some other properties, as long-range behaviour of correlation functions, appear. In the 0378-4371/86/$03.50

0

Elsevier

Science

Publishers

B.V.

FLUCTUATIONS

NEAR

GUNN

INSTABILITY

181

vicinity of critical points some correlation functions diverge, moreover they show critical slowing down behaviour. This common feature holds in some physical problems as Binard instability3), ballast resistor4) or Gunn instability5-7), for example. The Gunn instability is characterized by the appearance of a negative differential conductivity. When energy is supplied to a n-type GaAs sample, in the form of an increasing electric field, electrons go from a state with lower energy and high mobility to a state with higher energy but lower mobility. This fact is visualized in the velocity-field characteristic (fig. 1); at the extrema, the differential mobility becomes zero and the region between them is an unstable region of negative differential conductivity. Therefore it is expected that at these points the system presents critical behaviour, since a transition occurs from a state with a field distribution that is essentially uniform to a state which is highly non-uniform. Physical interest on Gunn diodes comes from the appearance of microwave oscillations when the voltage applied to the sample reaches a critical value, observed initially by Gunn8). It is important to note that the threshold voltage for the appearance of microwave oscillations coincides with the threshold value for negative differential conductivity under special conditions only’). In this paper we are not interested in discussing this fact. Our attention will be focussed to the behaviour of fluctuations near the threshold for negative differential conductivity.

v(E)

Fig. 1. Velocity-field

characteristic

(schematic).

182

A. DiAZ-GUILERA

Fluctuations

around

exhibiting

negative

Thomas’)

generalizing

by Buttiker stochastic

non-equilibrium

differential

Special

formula

who introduce attention

J.M.

steady

conductivity

the Nyquist

and Thomas”), forces.

AND

RUBi

states

in GaAs

have been

semiconductors

analyzed

to a non-equilibrium free parameters

by Pytte

and

situation,

and

in the variance

has been paid by Keizer’)

to explain

of

critical

fluctuations at the threshold for the appearance of microwave oscillations observed experimentally by Kabashima et al.“‘). Other measurements were made by Matsuno”), whereas Nakamura”) studied statistical properties of the Gunn instability in terms of mode-coupling Our aim in this paper is to analyze

theory. electron

density

and

electric

field

fluctuations around homogeneous and inhomogeneous steady states. In section 2 inhomogeneous steady state distributions are obtained by linearizing around homogeneous

steady

states.

Hysteresis

behaviour,

typical

of a first order

phase

transition, is observed. Correlation functions of fluctuations around nonequilibrium steady states and their critical behaviour are extensively analyzed in sections 3 and 4.

2. Fluctuations

around steady states

Our aim in non-equilibrium

this section is to introduce basic equations derived from thermodynamics”) as well as fluctuations around non-equilib-

rium steady states following tuating hydrodynamicslJ). 2.1.

an

extension

of

Landau-Lifshitz

fhtc-

Basic equations

Let us first formulate density

$

of the electrons,

the basic equations n, obeys

governing

the diffusion

the system.

+V.J=O,

where the total diffusion J=nv-DVn.

The number

equation

(2.1) flux J splits in convective

and diffusive

parts in the form (2.7-j

with v the velocity of the electrons and D the diffusion coefficient. This coefficient is in principle a function of the field, but usually it is assumed to be constant and equal to an effective value. This fact simplifies largely the treatment

FLUCKJATIONS NEAR GUNN INSTABILITY

and agrees with experimental the Poisson equation

183

results. The electric field E evolves according to

V*E=z(n-n,),

(2.3)

where e is the charge of the electrons, E the dielectric constant and ~~ the density of ionized donors, asumed to be constant along the wire. Taking the time derivative of (2.3) and employing (2.1) and (2.2) one arrives, after integration in space, to C?E = DVV. E - ; qlu(E)

at

- u(E)V.

E + i $ ,

(2.4)

where Z/A is an external current per unit area which appears as an integration constant and therefore may depend on time. In (2.4) we have written the velocity of the electrons as a function of the electric field only. The justification of this assumption lies in the fact that the intra- and inter-valley transfer relaxation times are very small and therefore electrons follow immediately any change of the field. By means of (2.1) and (2.3) it is also possible to arrive to Z

-

A

= en,u(E)

- V(eDn) + E $

,

(2.5)

which reflects the fact that the sum of convection, diffusion and displacement currents is precisely Z/A. Eq. (2.4) describes the evolution of the electric field when an electrodiffusive process takes place. In order to be complete one should specify the dependence of the velocity on the field. Since the differential mobility is the first derivative of the velocity with respect to the field, it is obvious to conclude that the stability of the stationary states is linked to the form of the velocity-field characteristic. In order to analyze briefly the stability of the system we can define a potential function 4(E) that plays the same role as the potential energy of a particle in 15.16 classical mechanics ), 4(E) = i 1 (s

- en,,u(E))

dE .

(2.6)

From (2.4) it can be seen that fD(V. E)* IS ’ analogue to the kinetic energy whereas u(E)V* E is a “dissipative” term. The potential defined above has an extremum when en,u(E) = Z/A. Thus depending on the value of Z and due to the form of the velocity-field

184

A. DiAZ-GUILERA

characteristic potential corresponds state.

when

to an unstable

Finally

this state

the potential

appears

has one, the

two or three

differential mobility

to the instability

extrema.

mobility

state while a positive

when the differential

corresponds

AND J.M. RUBi

A minimum

is negative;

thus

value is associated

vanishes

of the this case

to a stable

the state is metastable

and

point.

Steady states

2.2.

Homogeneous steady state solutions are obtained from (2.3) and (2.4) in the case II, = n,,. Such solutions are generated from the equation

(2.7)

which ignores the boundary conditions we will introduce below. As we will see later on, E, is related to the voltage externally applied to the sample (bias voltage). Inhomogeneous solutions are obtained from (2.4) setting the left-hand side zero. Then one obtains a non-linear differential equation which can be solved only by numerical methods. In this paper and for simplicity’s sake we will consider steady states which are close to the homogeneous solution E,, obtained directly from the external current through (2.7). The velocity can be developed in powers of the difference E, - E,, in the form

4%) = 4E,,) + (E, - 4,) - V,@) h-E,,+ . . where only terms linear in the difference Inserting (2.8) in (2.4) one arrives to

of (2.9)

- EU(E,,)V. E

(2.9)

is

4 = 4, + A exp(w) + B exp(w) , where

(2.8)

E, - E,, have been kept.

0 = EDVV. E - en,(E, - E,,) * VEu(E)j,=,,, In 1 - d the solution

3

(2.10)

we have introduced

(2.11)

and the definitions

FLUCTUATIONS

NEAR

GUNN

INSTABILITY

(2.12)

’

E=E,,

185

In (2.10) A and B are integration constants which can be computed from boundary conditions. In this paper we will consider Dirichlet* boundary conditions for the field. Using the “virtual cathode” assumption”“) the field is taken to be zero at x = -L/2. At the other end the field is also taken to be zero usually9~18), due to charge conservation. However, some authors”) consider that the field takes a higher value at the anode than at the cathode. Although this is not a very important question both possibilities can be considered. In the case of zero field at the anode (ZFA) the integration constants are written

A

1 - exp(dJ ZFA= exp( p2L) - exp( pu,L) exp(I-G/~) , (2.13a)

B

exp( hL)

- 1

ZFA = exp(CL2L) - exp(piL)

exp( pzL12) ,

and assuming a finite value, equal to E,,, of the field at the anode (FFA) one obtains

A FFA

exP(kLL)w-G4~4 =

exrh4

-

exp(kL)

’

(2.13b) exp( kL)

exp( hL/2) B FFA = exp( pu,L) - exp( pi L)

’

At the steady state the density of electrons is easily obtained from (2.3) and (2.10). One has

n, = no +

z[E”,Aexp(w)

+ 1-4

exp(w)l

y

(2.14)

where no is also an homogeneous solution of the steady state density, independent of E,. In figs. 2 and 3 we plot the field distribution along the sample with respect to the homogeneous field for the boundary conditions (2.13). It can be seen that those boundary conditions are responsible for the fact that the steady state electric

* Notice that due to Poisson equation (2.3) Dirichlet boundary conditions for the density are Neumann for the field. In the same way, and due to the definition of the electric voltage, Dirichlet boundary conditions for the field correspond to Neumann for the voltage.

A. DiAZ-GUILERA

186

AND

J.M.

RUBi

W” \ W” I W”

0 distance Fig. 2. Steady of the

state electric

homogeneous

field

field distribution

when the field vanishes

E,,. (a) E,, = 1 V/cm;

(b)

E,, =2kV/cm;

at each end for different (C) E,, =3kVicm;

3.1 kV/cm.

0

0

\” 4 I W”

-:

0 dLstance Fig. 3. The same

as in fig. 2 but now the field is equal

to E, at the anode.

values

Cd) EC1=

FLUCTUATIONS NEAR GUNN INSTABILITY

187

field differs from the value E,, the solution of (2.7). At equilibrium the intensity I is equal to zero and the electric field is homogeneous and equal to zero too. In a state that is close to it (for example, E, = 1 V/cm, curves a in figs. 2 and 3) the field is not homogeneous but it can be practically considered as homogeneous, since the difference is only important in the ends of the wire. When E, increases, the stationary solution goes away from the homogeneous one until it reaches the instability point (E, = 3.11 kV/cm, in our model (2.15)) where the steady state field has a nonsensical distribution, since it is identically equal to zero for (2.13a) and equal to zero almost everywhere for (2.13b). This fact shows the importance of considering inhomogeneous solutions of the steady state electric field distribution, although at the instability point our linearization (2.8) breaks up. As will be seen in the next section, in order to compute correlation functions, we need the electron density distribution instead of the electric field. With the boundary conditions (2.13) the steady state electron density differs from its homogeneous solution n, only in a few per cent, although the electric field holds of the homogeneous value, and in particular one has at the instability point n, = it,, identically, for the ZFA boundary conditions (2.13a). It does not mean that near the instability point the electron distribution can be taken strictly homogeneous since in this case the linearization (2.8) is not correct. If other boundary conditions were considered, the result should be quite different. For example, assuming the electron density to be zero at each end the distribution would lead to a solution similar to that of the field given in fig. 2, or if one assumes 11,(x = -L/2) = 0 and 11,(x = L/2) = n,,, it should correspond to fig. 3. In these cases the electron density differs appreciably from the homogeneous solution. For this reason, when fluctuations are studied, the integration constants will be considered in general. The results plotted in figs. 2 and 3 have been calculated with the expression proposed by Kroemer”) for the GaAs velocity-field characteristic u(E) =

PoE[l+ w4Yl 1+ (EIE,)k

’

(2.15)

where p0 is the lower valley mobility and B is the ratio of upper valley mobility to lower valley mobility. The values of the parameters involved in (2.15) that show the best agreement with the experimental results are taken from ref. 12 and they are cc, = 8000 cm2/Vs, E, = 4000 V/cm, k = 4 and B = 0.05. Other parameters used in the calculation of the electric field distribution are, for GaAs, D = 200 cm2/s and E = 12 12). On the other hand there are parameters which characterize the sample as the length and the donor density. Acccording to usual samples on which experiments are performed”‘,~‘) we consider L = 10 microns and n0 = 1Or5cmm3.

188

A. DiAZ-GUILERA

A large number Gunn

devices

of papers have

been

on exact solutions publishedlX).

calculations,

but we need an analytical

the electron

density

states.

distributions

This is the reason

AND J.M. RUBi

of the electric

However, expression

in order

of either

to analyze

of our linearization

they

field distribution involve

the electric

fluctuations

in

numerical

around

field or steady

(2.8).

We have described the steady state variables, as electric field and electron density, in terms of an homogeneous field E,, related to the intensity through (2.7). Sometimes an electrical system is described externally. In our problem we can define the voltage

by the voltage applied across the sample as

I. / 2

Es(x)dx

U=

(2.16)

1

mf.!2 which is a function defined in (2.11).

u,FA

=

E

.

of the homogeneous electric field E,, only through Using (2.10) and (2.13) in (2.16) one arrives at

L

+

(cxp(/*,L)

0

- l)(exP(@zl)

exp(pzL)

- 1)

-ev(kL)

1 _ 1 E,) ) 1, ? PI 1

11, and ~~

(2 ITa)

(2.17b)

Eqs. (2.17) are slightly different but they can be analyzed in general since they lead to the same physical result. The first term on their right-hand side is linear in the field and corresponds to the voltage due to an homogeneous electric field. The second

terms come from the inhomogeneous

corrections

of the steady

state electric field. These terms are small enough unless near the instability point where they become dominant, in such a way that just at this point the voltage across the sample

(2.17)

is equal

to zero.

In order

to clarify this fact we plot in

fig. 4 the voltage for ZFA boundary conditions in terms of the homogeneous electric field E,,. The voltage in the unstable region has not been plotted since (2.17) has negative values and our treatment is not correct in this region. Within our linearized analysis of the steady state some physical information can be gained from fig. 4. An increase from equilibrium of the bias voltage produces a linear increase in the homogeneous field, E,, = U/L. But when the bias voltage reaches a critical value, the field E,, changes abruptly to a higher value lying on the high field stable branch of the velocity-field characteristic. If this process is reversed, a similar fact occurs, but now the change in the field is from the minimum of the velocity-field characteristic to a lower field. The process represents an hysteresis cycle, typical of a first order phase transition

FLUCTUATIONS

NEAR GUNN INSTABILITY

189

/ UZFA

Fig. 4. Representation of the voltage along the sample versus homogeneous electric field for ZFA boundary conditions. The hysteresis cycle is denoted by arrows.

that has been analyzed by Nakamura”) and observed by Kabashima et al.“). Nakamura’*) obtained a non-linear Langevin equation for the unstable mode responsible for the critical behaviour and it enables him to obtain a thermodynamic potential, over which hysteresis behaviour was analyzed. Although this potential appears in a natural form in an equation identical to the rotating-wave van der Pol equation for a laser oscillator, it has a very complicated structure in contrast to that expressed in (2.6) from which the hysteresis behaviour can also be inferred. 2.3. Fluctuations We will incorporate fluctuations in former scheme by adding a stochastic current JR to (2.3). Then the total fluctuation diffusion flux writes J=nv(E)-DVnf

JR.

(2.18)

Therefore and as we outlined above, from (2.1), (2.3), (2.9) and (2.18) one arrives at SE -=DVV.6E-y8E-fWiE-~JR, at

(2.19)

A. DiAZ-GUILERA

190

where

electric

extension following

field fluctuations

of fluctuating

AND J.M. RUBi

as 6E = E - E,. According to the the stochastic current satisfies the

are defined

hydrodynamics,

properties:

(JYr, t)),, = 0 ,

(2.20)

(Jy(r, t)JT(r’,t’))., = 2Dn,(r)6,,6(r where

( . . ),,

the symbol

stands

-

for non-equilibrium

r’)tS(t

-

t’) ,

averages.

(2.21)

Henceforth

we will omit

NE.

Eq. (2.19)

can be Fourier

in (k, co). Then

transformed

if we define

6E(k, w) = j dr 1 dt e’(w’mk’r)i5E(r, t) one arrives

(2.22)

at

6E(k, w) = - f [(y - iw)l + Dkk + $k]-‘JR(k,

(2.23)

w)

where p is the three-dimensional counterpart of (2.12a), y = en,,p/e and 1 is the unit matrix. Assuming the system to be isotropic, one has rlu,(E)/aE,I, =t,, = @,, , I_Lbeing the differential mobility. Notice that in order to introduce integrals in the Fourier infinite. This

transformation can be done

(2.22) we have tacitly if collective excitations

assumed that our system decay within a distance

is 1

shorter than the dimension of the system L 14). Since I is of the order of a characteristic velocity times a characteristic time the condition is v(E,,)/y < L, where v(E,,) - lo7 cm/s is not only the velocity at which electrons move but it also represents the velocity of propagation of fluctuations as will be shown later time’7,“‘) on. Moreover y - 10” s --’ is the inverse of the dielectric relaxation and will be also interpreted as the relaxation time of fluctuations. Therefore the condition is L 9 1O-5 cm and in Gunn devices the typical length is around 10-‘-10-7 Density

cm, as was outlined fluctuations

around

above;

therefore

the homogeneous

our

assumption

solution

is justified.

can be studied

also

from the equation a&? -=DV26n-P.Vn-ySn-V.JK, at where Sn = n - no. Eq. (2.24) is derived transforming (2.24) one arrives at 6n(k, w) = -i

(2.24) from (2.1),

km JR@, w> Dk’ + y - i(w - /3 - k) ’

(2.3)

and (2.18).

Fourier

(2.25)

FLUCTUATIONS NEAR GUNN INSTABILITY

191

Instead of transforming over k - owe can only transform in k. One arrives at the following equation: dSn(k, t) at

= -(Dk*

+ y + i/3 *k)Sn(k, t) - ik. JR.

Taking the non-equilibrium (Sn(k, t)) = exp[-(ip

(2.26)

average in (2.26) and using (2.20) one arrives at - k + Dk’ + y)t](Sn(k,

t = 0)) .

(2.27)

In view of this last expression, the k = 0 mode grows exponentially in time when the differential mobility is negative. Then (2.27) shows the enhancement of fluctuations in the unstable branch. The parameter y -’ represents the relaxation time of fluctuations. This parameter is also defined by some authors”,*‘) as the dielectric relaxation time or the time in which the charge redistributes in the semiconductor. Then when it is negative, the system goes away from its equilibrium state.

3. Density correlation

functions

The equations derived in the previous section are now applied to compute correlation functions for fluctuations around homogeneous and inhomogeneous steady states. At a first step we are going to analyze the density correlation function for an arbitrary dimension. From (2.25) and the Fourier transformation of (2.21) one arrives at (Sn(k, w)Sn(k’, w’))

= -(2r)df’

2Dn,ka k’6(k + k’)S(w + w’) [Dk* + y _ if@ _ p. k)][Dk” + y _ i(w’ - p. k’)]

’

(3’1)

where we have assumed that the steady state is homogeneous and its density equal to no. Fourier inversion of (3.1) leads, at equal time, to ,

(Sn(t, t)Sn(r’, t)) = n,6(r - r’) - “$$)

1 k2e~‘~~~~)

dk .

(3.2)

Now it is easily seen that the behaviour of the second term in the right-hand side of (3.2) depends strongly on the dimension of the system. Then one has for each

192

A. DiAZ-GUILERA

AND

J.M.

RUBi

dimension*

(Srr(x, t)Sn(x’, r)) = n,,qx -

x’)

5

-

e

-(‘\ -k”,c’ ,

d=

1, (3.3)

(Sn(r, t)Sn(r’, f)) = n,,6(r - r’) - f+

K,,( (r - r’( is) ,

d=2, (3.4)

(Sn(r,

t)) = n,,6(r-

t)Sn(r’,

4Tcl;l:‘_ em”r-r”‘t’-

r’) -

r,l

ci=3. (3.5)

where

K,, is the modified

Bessel function

of zero order.

Eqs. (3.3)-(3.5)

involve

the correlation length 5 = (D/y)“’ which is nothing but the Debye length. This length is also the length in which the charge rearranges through diffusion. At equilibrium this length becomes infinite and the non-equilibrium correlation functions tend to the equilibrium value n,,6(r - r’). Moreover non-equilibrium corrections exhibit Ornstein-Zernike behaviour and are of the same type to those encountered in the Debye model of plasmas”). the difference arising from the fact that for plasmas the correlation length 5 appears always as a finite parameter and therefore has a different meaning. At the instability point. where y is equal to zero, the correlation length diverges but non-equilibrium corrections to the correlation functions vanish. Minus signs in non-equilibrium corrections charge conservation, if at time r a positive fluctuation fluctuations

should, on the are correlated.

It is important evaluated appearing

to note

average,

take

that the correlation

correspond fluctuation place

at

to the fact that due to occurs at r, a negative any

functions

point

(3.3)-(3.5)

r’

in which have been

assuming y to be positive since in the opposite case the integral in (3.2) diverges. The same will be assumed in the calculation of

correlation

functions

A quantity

in the r-t

representation.

that is also interesting to analyze is the correlation function in the It can be obtained from (3.1) by Fourier inversion over w has

k-t representation.

and o ‘. One

(Sn(k, t)Sn(k’.

r’)) = (2+%,,6(k x exp{ -i/3

* Densities

appearing

in the correlation

+ k')

Dy; y

* k(t - t’) - (Dk’ + y)lf - t’l} ,

functions

must be interpreted

in each dimension

(3.6)

FLUCTUATIONS

NEAR

GUNN

INSTABILITY

193

where we can see that j3 plays the role of a velocity of the propagation of density fluctuations. It can be also observed that the relaxation time of the k = 0 mode diverges as y -’ when the field approaches the instability point: critical slowing down behaviour. These results were also obtained in refs. 5 and 6. From (3.6) one can also see that the density correlation function in the k-f representation vanishes in the k = 0 limit, unless at the instability point, y = 0, in which (3.6) does not vanish and the density fluctuations are delta correlated as we saw in (3.3)-(3.5). In the k = 0 case both the relaxation time and the correlation function (3.6) are finite if the system is at the stable branch (y > 0). But if y is negative there will always exist one mode, in our continuum representation, such that its correlation time diverges and makes the density correlation function be divergent. Notice that in a discrete representation, imposing periodic boundary conditions on the fluctuations, the wave number k is given by k = (27rlL)m, where m is an integer different from zero. In that case the density correlation function (3.6) does not diverge at y = 0 but it does at y = -(27rlL)“D. This fact gives a criterion of stability of the fluctuations, as Butcher’) and Ridley22) do for a perturbation from the steady state, showing that diffusion stabilizes waves with sufficiently short wavelength. A stability criterion relating the differential mobility and the length of the sample appears commonly in the literature about the Gunn effect7’9”7 ). For GaAs the stability criterion of the waves involving the diffusion coefficient is most important for very short devices (0.5 microns) with a donor density around 1016cm-3 ” ), whereas in other cases different criteria should be used. Density fluctuations around inhomogeneous stready states (2.14) can be analyzed also. In k-o representation and in 1 - d one has @n(k,

w)&z(k’, co’)) = -47r

Dkk’G(w + w’)n,(k [Dk2 + y - i(w - @k)][Dk’*

+ k’)

+ y - i(w’ - pk’)]

’

(3.7) where n,(k) is the k-Fourier transform of the steady state electron density (2.14) that follows from the n,(x) appearing in the covariance of the random current (2.21). By inverse Fourier transform of (3.7) and integrating over w and w’ the equal-time correlation function is (sn(x, t)sn(x’, t)) =

& j-j-dk dk’ D(k -cc

-2Dkkrn,(k

+

kf)ei(kx+k’x’)

+ k’)’ - 2Dkk’ + 2y + iP(k + k’) ’ (3.8)

194

A. DiAZ-GUILERA

These

integrals

(%2(x, t)6n(x’,

are evaluated

t)) = n,(x)s(x

AND

J.M.

in the appendix

- x’) - n,,

RUBi

and its final result

is

em“ -““’ 25

(3.9) 4 being

a dummy

variable

and F(x, x’, 4) an auxiliary

function

defined

in the

appendix. Notice that the first term in the right-hand the corresponding term in eqs. (3.3)-(3.S), that now long-range

the coefficient contributions

of the to (3.9)

delta come

side of (3.9) is of the same kind as the difference arising from the fact

function depends on position. The from F(x, x’, q) and from the term

corresponding to the homogeneous but non-equilibrium correction studied in (3.3). In view of the definition of F(x, x’, q), (A.9), one concludes that in l-d the contribution is exponential. Moreover it is possible to see that translational invariance valid at equilibrium is not satisfied now since a transformation x+ x + a implies a change n,(x) + 11,(x + a) and F(x, x’, CJ)-+ exp(iqa)F(x, x’, 4). In eqs. (3.3)-(3.5) we saw that at the instability point (y = 0) the nonequilibrium corrections of the density correlation functions vanish in an homogeneous steady state. A detailed analysis of (3.9) shows that the inhomogeneous part of the steady state solution (2.14) makes the nonequilibrium density correlation function diverge. Although this result is independent of the integration conditions the divergence the instability

4. Electric

point

constants is slightly

A.,,

tends

field correlation

A and different

B obtained from the boundary in the two cases (2.13) since near

to zero as y whereas

AFFA remains

finite.

functions

Apart from the density correlation functions we are also interested in the expression of the electric field correlation function. It can be obtained in a way similar to that employed in the derivation of the density correlation function. Hence from (2.23) one obtains the electric field correlation function in the k-w representation in l-d: (6E(k, w)GE(k’, w’)) 4nDe2

S(w + w’)ns(k

= T[Dk2

y - i(o - /3k)][Dk”

+ k’) + y - i(w’ - pk’)]

t

(4.1)

195

FLUCTUATIONS NEAR GUNN INSTABILITY

By inverse Fourier transform, integrating over w and w’ and inserting the value of n,(k + k’) obtained in the appendix, the first contribution to the equal-time correlation function reads

(SE(x, t)SE(x', t))l =

$ [+jdk dk’

‘(’ +k;$,+;+^”

.

(4.2)

--m When the integral is performed one must take into account that y has a positive value in order the integral be convergent. One arrives at (%5(x, t)SE(x’,

t))

1

=

$

5 e-‘xpx”‘s .

Second contribution gives, following the same procedure the calculation of the density correlation function, (SE(x,

t)SE(x’,

t)), = %

e-icllJ’JqF(x, x’, q)lqzo .

Adding the three contributions

(Slqx, t)SE(x’, t)) =

1-

+ wIA 2E

emiplJiJq

$ +

(4.3) as that employed in

(4.4)

one finally arrives at 5

-w2B 2E

e-Ix-x’l/5

e-ir2J’Jq F(x, x’, q)lqzo .

1

(4.5)

This last expression can be written in a more compact form observing the dependence of n,(x) on the spatial coordinate (2.14) and the value of F(x, x’, q) at q = 0 from (A.9),

(S-W, t)SE(x’, t)) =

$ n, (4 +-)F(x, x’, q)lqzo.

(4.6)

From (4.3) one can notice that the homogeneous part of the electric field correlation function diverges as the correlation length 5 does when the system approaches the instability point. In that limit the density correlation functions (3.3)-(3.5) re d uce to the term containing the delta function. This is not a new result since Pytte and Thomas5) and Buttiker and Thomas6) arrived at a similar conclusion for long times. But when fluctuations around inhomogeneous steady states are studied both density and electric field correlation functions diverge at the instability point, although they do it in a different way.

196

A. DiAZ-GUILERA

In the k - t representation contribution

(E(k,

and taking

in a one-dimensional

t)GE(k’, t’)) =

AND J.M. RUBi

into

analysis

2n-Dn,,e’ E2

account

only the homogeneous

the field correlation

exp{ -ipk(t

function

looks

- t’) - (Dk’ + r)lt - t’l} Dk’ + y

x 6(k + k’) ,

(4.7)

where we can see that it is finite for the k = 0 mode, i.e. it has a finite range and diverges at the instability point in contrast to the density-density correlation function (3.6). From electric field fluctuations one can study voltage fluctuations that can be compared

with experiments.

This will be the subject

of a forthcoming

paper”).

Acknowledgements This paper has been partially supported by a grant of the Comision Investigation Cientifica y Ticnica of the Spanish Government.

Asesora

de

Appendix Fourier

transforming

equation

(2.14)

at ti

+r

+L

P,AE

th\ e e"' dx + ~

e A’ dx + p

n,(k) = n,,

one arrives

e"?‘dx

~7

-x

(A.1) The first integral is a delta function same structure and for this reason exponential

is Taylor

expanded

6(k). The second and third integral have the they are evaluated in a general form. If the

we get

(A .2)

FLUCI-UATIONS

Thus (A.l)

NEAR

GUNN

INSTABILITY

197

becomes

n,(k) = 2~,6(k)

n$O $

+ ?

a(k)(Ap;+’

$

+ I$;+‘)}.

(A.3)

For the sake of clarity we will analyze separately the three different contributions to n,(k). The first one corresponds to the homogeneous steady state electron density n,, and has been obtained in eq. (3.3). Inserting the second contribution into (3.8) one obtains

c@$ /+f

(6n(x, t)&z(x’, t))2 = g

dk dk’

n-0

_ ’

D(k

+

Ic’)~

2~kk -

--m

eWx+k’x’)

.

(A.4)

6(q)

(A.5)

Dq2 + 2D( q’ - q)q’ + 2y + iPq ’

G4.6)

a”

2Dkk’ + 2y + iP(k + k’) d(k + k’)”

6(k + k')

After a change of variables, k + k’ = q, k’ = q’, it reads

(Sn(x, t)&z(x’, t))2 =

$$ ; @$ l+f dq dq' no

.

_qq

X

and integrating

_

--ic

qt)qt

ei(q-q’b

eiq’*’

d”

Dq2 - 2D( q - q’)q’

+ 2y + i@q aq”

by parts 12times in q,

(&2(x, t)ifin(x’, t)), =

nzo v $6

E

eiqx

+oC 2D(q!

X i

dq’

-cc

_

q)q’

e-iq’(x-x’)

The integral appearing in (A.6) is +-= 2D(q!

i -m

dq’

_

q)qt

e-iq’(x-x’)

Dq2 + 2D( q’ - q)q’ + 2y + ipq eidx’-x)/2

_

= 27rS(x - x’)

1 (; +$ +g”2,x_xI,)

exp

_

n(Dq’+ 2~ + i&l 20 (

64.7)

A. DiAZ-GUILERA

198

AND

J.M.

RUBi

Then one obtains (Sn(x, t)Sn(x’, t))

2

-pifc e/*l\qx

=

-

x’)

r x,,,

(-ip,)”

P&

-

~

e

0”

,I_11

x (&I’ + 2~ + iPqJF(x, x’, 4)ly-,,,

(A.81

where F(x, x’, q) is an auxiliary function defined by lq(r*.l’)/7

F(x, x’. q) =

ez

$+%+E iPq (A.9) Rearranging

(A.B) it can be written as

(6n(x, t)Sn(x’, t)), =

-‘“lat e”“6(x x -f n-0

(-ip,)“’ n!

- x’) -

d”

j-g

F(x, x’, q)l,=,,

(A.10)

The third contribution is equal to the second one changing p, by pz and A by B. Adding the three contributions to the equal-time density correlation function, taking into account the expression of the steady state electron density (2.14) and the values of p, and pI (2.11), one finally obtains e~~‘H’1/5 (&2(x, t)tin(x’, t)) = n,(x)ti(x

- & xe

which corresponds

- x’) - n,,

25

{ /_L,A(y + 2&,)

-“zb’dq}F(x,

x’, q&:,,

e~‘F1”!a’ + /+B(Y + 2pp.z) ,

(A.ll)

to (3.9)

References 1) J.M. Rubi, Fluctuations Around Equilibrium, in: Recent Developements in Non-equilibrium Thermodynamics, J. Casas-Vazquez, D. Jou and G. Lebon, eds., Lecture Notes in Physics (Springer, Berlin, 1984). 2) A.-M.S. Tremblay, Theories of Fluctuations in Non equilibrium systems, in: Recent Developements in Non-equilibrium Thermodynamics, J. Casas-Vazquez, D. Jou and Q. Lebon, eds. Lecture Notes in Physics (Springer, Berlin, 1984).

FLUCTUATIONS

NEAR GUNN INSTABILITY

199

3) V.M. Zaitsev and MI. Shliomis, Soviet Physics JETP 32 (1971) 866. T.R. Kirkpatrick and E.G.D. Cohen, J. Stat. Phys. 33 (1983) 639. 4) R.A. Pasmanter, D. Bedeaux and P. Mazur, Physica WA (1978) 151. 5) E. Pytte and H. Thomas, Phys. Rev. 179 (1969) 431. 6) M. Buttiker and H. Thomas, Solid-State Electron. 21 (1978) 95. 7) J. Keizer, J. Chem. Phys. 74 (1981) 1350. 8) J.B. Gunn, Solid State Commun. 1 (1963) 88. 9) P.N. Butcher, Rep. Prog. Phys. 30 (1967) 97. 10) S. Kabashima, H. Yamazaki and T. Kawakubo, J. Phys. Sot. Jpn. 40 (1976) 921. 11) K. Matsuno, Phys. Lett. 31A (1970) 335. 12) K. Nakamura, J. Phys. Sot. Jpn. 38 (1975) 46. 13) S.R. de Groot and P. Mazur, Non-Equilibrium Thermodynamics (North-Holland, Amsterdam, 1962). 14) A.-M.S. Tremblay, M. Arai and E.D. Siggia, Phys. Rev. A23 (1978) 1451. 15) D. Bedeaux, P. Mazur and R.A. Pasmanter, Physica 86A (1977) 355. 16) B. Kadomtsev, Phenomenes Collectifs dans les Plasmas (Mir, Moscow, 1979). 17) J.E. Carroll, Hot Electron Microwave Generators (Elsevier, New York, 1970). 18) CM. Snowden, Rep. Prog. Phys. 48 (1985) 223; and references quoted therein. 19) H. Kroemer, IEEE Trans. Electron Devices ED13 (1966) 27. 20) B. Knight and G.A. Peterson, Phys. Rev. 147 (1966) 617. 21) N.G. van Kampen, Statistical Mechanics of Classical Plasmas, in: Fundamental Problems in Statistical Mechanics, E.G.D. Cohened. (North-Holland, Amsterdam, 1968). 22) B.K. Ridley, Proc. Phys. Sot. 86 (1965) 637. 23) A. Diaz-Guilera and J.M. Rubi, Physica 135A (1986) 200, subsequent article.