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Adsorbate induced reconstruction of Ni (100)
Journal of Electron Spectroscopy and Related Phenomena, 38 (1986) 45-54 Elsevier Science Publishers B.V., Amsterdam - Printed in The Netherlands
ADSORBATE
INDUCED RECONSTRUCTION
T.S. RAHMANI,
of Physics,
lDepartment *IGV/KFA
M. ROCCA*',
JUlich,
OF Ni( 100)
S. LEHWALD',
H. IBACH'
Kansas State University,
Postfach
1913,
45
D-5170
Jijlich
Manhattan
KS 66506, USA
(F.R. Germany)
ABSTRACT We have carried out a systematic lattice dynamical study of the ~(2x2) overlayer of oxygen, sulfur and carbon (nitrogen) on Ni(lOO). The model consists of nearest neighbour interactions between all atoms and an additional (attractive) interaction between the adsorbate atoms and the second neighbour substrate atom directly below, which consequently introduces internal stresses. We show that the relative strength of the internal stress and the coupling between the first and second layer nickel atoms determine whether the Ni(lOO) surface will reconstruct. The presence of the attractive force between the adsorbate atoms and the second layer nickel atoms allows us to explain the observed anomaly in the dispersion of the Rayleigh wave for the oxygen overlayer on Ni(lOO) and leads to a natural explanation for the reconstruction pattern observed in the presence of the carbon and nitrogen overlayers via softening of a substrate phonon.
1. INTRODUCTION In the past several years a number of experimental on the structure
and dynamics of the Ni(lOO) surface,
or in the presence
of ordered overlayers
we will be concerned
with two particular
which are (i) the anomalous
low freqency
and theoretical
have become available. intriguing
aspects
of the Rayleigh
In this paper
of these studies
surface phonon at the
zone boundary when the surface is covered with a ~(2x2) overlayer (ref. 1) and (ii) the reconstruction layer of carbon ysis
(ref. 2) and nitrogen
interaction
between the adsorbate
of the adsorbate
teraction
controls
of oxygen
of the nickel surface with a ~(2x2) over(ref. 3). Using a lattice
it will be shown that both phenomena
distance
studies
either in the clean form
have a common origin
dynamical
atom and the second layer substrate
to the surface and the strength
whether the phonon spectrum displays
anal-
in an attractive atom. The
of the attractive
anomalies
in-
or the sur-
face reconstructs. In previous
lattice dynamical
face phonon branches
*Permanent
address:
0368-2048/86/$03.50
a nearest
analyses
neighbour
of the experimentally central force model
observed
sur-
(ref. 4,5) was
Dipartimento di Fisica, Universitl degli Studi di Genova, Via Dodecanso 33, I-16100 Genova, Italy
0 1986 Elsevier Science Publishers B.V.
46 used. Within this model the softening could be described
of the Rayleigh wave at the zone boundary
by making the force constant
between the nickel atoms in the
first layer and the nickel atoms in the second layer rather small, namely 30 % of the bulk force constant. the dispersion
curves was obtained.
found necessary
surface
at the X-point
a reasonable
No reduction
of this force constant was
discovered
corresponds
of the surface
that the p4g(2x2)
to the displacement Brillouin
interactions
reconstruction
of sul-
of the car-
pattern of the A2-eigenmode
zone of the unreconstructed
face (ref. 5). Within this simple lattice dynamical neighbour
overall fit of
in order to reproduce the data for a ~(2x2) overlayer
fur. It was furthermore bon covered
With this assumption
~(2x2) sur-
model involving
nearest
only, this mode would become soft when the force con-
stant between the first layer nickel atoms and the second layer nickel atoms approaches
zero. While this simple lattice dynamical
lish a connection
between
remained problematic reduction
in the force constant.
bour interactions longer
the observed
in its physical
phonon anomaly
picture
with additional
attractive
propensity struction
parameter
of the adsorbate
when the distance
The paper is organized description
Green's
the results for the dispersion
and eventually becomes
on Ni(lOO).
spectral
is described
densities
section
to the discussion of the structure
2. (2x2) STRUCTURES Ordered
sponding
dynamiFourier
In section
of the reconstruction.
of (2x2) overlayers
These overlayers
We now turn to a surface.
of 25 % and 50 % of
with ~(2x2) overlayers
may be obtained
genides Te, Se, S and 0, each being positioned
(save for an overall
vertical
in the fourfold
is that of a ~(2x2) structure.
relaxation
corre-
with the chalcohollow site as
shown in Fig. la. Since the nickel atoms remain at their positions
tion pattern
nickel sur-
study. The final
on the Ni(lOO)
on Ni(lOO) are formed with coverages
Here we will be only concerned
to 50 % coverage.
clean surface
4
ON Ni(lOO)
structures
the adsorbate.
The lattice by employing
curves for the ~(2x2) oxygen covered
and compared to results of the previous
brief description
recon-
smaller.
in the third section.
face are presented is devoted
our study
of the surface
In the next section we provide a brief
of (2x2) overlayers
functions
no
layer. As will be seen the
of the adsorbate
cal model and our method of calculating transformed
the behaviour
phonon anomalies
as follows.
of the geometry
interactions
nickel atoms and the
small. Furthermore
controlling
from the surface
of the surface to display increases
it
second nearest neigh-
(and repulsive)
between the surface
next layer nickel atoms to become unphysically
is the distance
and the reconstruction
because of the required drastic
The new model involving
requires the force constant
will show that an important
model was able to estab-
as for the
(ref. 6)) the diffrac-
The unit cell of this structure
47
L
t1001 [llOl
/ \\ //
Fi
ElII 'R '\ t /' \/
b
a
Fig. 1. a) (100) surface with a ~(2x2) overlayer. The dashed line is the surface unit cell. b) Brillouin zone for the clean and ~(2x2) surface (full and dashed line, respectively).
contains
one adsorbate
face Brillouin
the chalcogenides both adsorbates
atom and two nickel atoms in each nickel layer. The sur-
zone is depicted
in Fig. lb. Overlayers
of the same type as with
can also be formed with carbon and nitrogen.
the nickel surface
reconstructs
to form a p4g(2x2)
(ref. 2,3). The unit cell is now as with a (2x2) overlayer. tions in the diffraction dicular
pattern
glide planes oriented
ture as originally
proposed
indicate the presence
extinc-
of two mutually
perpen-
The geometric
struc-
et al. (ref. 2) is shown in Fig. 2. AS
can be seen from the figure the reconstruction and clockwise
structure
Systematic
along the [loo] direction.
by Onuferko
However with
consists
of a counter
clockwise
rotation
of the nickel atoms around the adsorbate
atoms. Experi-
mental and theoretical
studies of the surface phonon dispersion
of this struc-
ture have been performed.
These results will be reported
tion. Here we are concerned
with the lattice dynamics
and the forces which drive the surface
in a separate
publica-
of the ~(2x2) structure
into the observed
reconstruction.
48 3. THE LATTICE
DYNAMICAL
The lattice proximation
dynamics
MODEL of the nickel surface
The Hamiltonian
using pair potentials.
where uu is the ath Cartesian K in the layer arbitrarily
component
tz with the position
chosen
pair potential
origin,
is treated
in the harmonic
therefore
of the displacement
vector LI connecting
ap-
assumes the form
of the atom labeled
the unit cell with an
M is the mass of the atom and P its momentum.
The
is given by
o,,(ij) = 6ij z, Ka,(ij')
- (I-'ij) K,B(ij)
J with the effective
K,,(ij)
=
L
force constant
K as
6as + (‘Pyj -'j
Iri
I
Here oij and myj are the first and second derivations
of the pair potential
and
fi is the unit vector from atom i to atom j. As in the previous interactions
only are assumed
Equilibrium tential
conditions
vanishes,
the minimum
of the pair potential
by including
connecting
for a reasonable
the second
of the pair poposition
neighbour
interaction
bility criterion
of the bulk phonon spectrum
ferent atoms.
(ref. 7)
between the adsorbate
atom and
With such second neighbour
interac-
of the potentials
need no longer vanish.
The sta-
that the net force on each atom must vanish generates
between the first derivatives
at
the atom to its next neighbour.
representation
layer nickel atom underneath.
tions the first derivatives
neighbour
for atoms in the second nickel layer and below.
then require that the first derivative
For atoms near the surface we go beyond this simple model
the second
relations
study of this system nearest
i.e. each atom in the bulk has its equilibrium
This model suffices of nickel.
lattice dynamical
of the pair potentials
In our model we assume an attractive
interaction
a set of
connecting
dif-
between the ad-
sorbate and the second layer nickel atom (vi2 > 0). This requires a repulsive interaction
between
the adsorbate
atom and the first layer nickel atom ($2
<
0) (Fig. 3). The force on the first layer nickel atoms then needs to be balanced by a repulsive may proceed
interaction
in two different
to nickel atoms in the second layer. Now, one
ways.
In order to balance the force on the first
nickel layer atoms one could introduce layer. These would then require further
a cp'to all nickel atoms in the second 9' to atoms below and so forth. A par-
49
,,~
layer Iqa
Fig. 3. The figure illustrates the force constants which couple the adatom in layer 0 (labelled as +) among each other (p;O), to the first layer nickel atoms (qbI, cpjjl), and to the second layer nickel atoms (f&s @2)s and also-the force constants coupling the first layer nickel atoms to atoms in the second layer via as seen in sectional view AA' or as seen in sectional view BB'. further discussion.
0 1
/’
layer 2
88’
sde
9
“lew
CR\
'\
'\ ,/ '\\,/ b
titularly
hyer 1
(9
‘+ ,/' '\ /' u
layer 2
simple choice of balancing
the force is to connect
the first layer
nickel atoms with 9' only to the second layer nickel atoms below the adsorbate atom
(Fig. 3). The three equations
for having no net forces on the adsorbate,
first layer nickel atom and second layer nickel atom in z-direction
then read
4qbl n,(Ol) + 'pb2 n,(O2) = 0
(4)
2Pbl
(5)
n,(lO)
+ 2$2
Vb2 nZ(20) + 4$2
n,(12) n,(21)
= 0
(6)
= 0
where n,(ij) is the z-component three equations
which
are fulfilled
of the unit vector from atom i to atom j. These
with
leaves the force between the adsorbate
as the only free parameter x and y-direction
of the potentials.
the net forces on the atoms vanish because
choice of balancing have however
and the second layer nickel atom
for the first derivative
the forces as described
also explored
anced in the alternative
procedure
of symmetry.
above is particularly
the lattice dynamics as described
For the The
simple. We
of the system with forces balabove. No significant
differ-
50 curves were found. We note further that our model with
ences in the dispersion internal
stresses
would be compatible
sition of the nickel atoms, Since no such detailed
with adsorbate
in particular
data is available
induced shifts of the po-
with a buckling
of the second layer.
on the surface structure
we kept the
atoms at their bulk positions. The lattice Green's
dynamical
functions
model
constructed
is evaluated
with the aid of Fourier
transformed
from the eigenvectors
*
U
(eZ~;L;~‘;Q,~)
a6
=
ei(Ql;fzK)ei(Ql;f;K’)
1
2 w -
S
where ei(QII;IZ~) is the ath Cartesian s, with Q, the wave-vector the displacement eigenfrequency function
component
of the atom
K
(9)
ag(Q,) component parallel
of the eigenvector
to the surface
for the mode
associated
with
in the unit cell in the layer P.z, m,(Q,) is the
and w is the frequency.
The equation
of motion
for the Green's
is
with the dynamical
Matrix iQ,,[Ro(fraZK)-Ro(L;$KI1)]
@aB(tIEzK,g;t;K”)
Das(QI;tZ~;ll;~“)
= 1
.
a'; [M(L~K)M(~;K”)]~‘~
As can be seen the equations ed from the eigenvectors
e
of motions
couples the Green's
of the atoms in a particular
function
(11)
construct-
layer to the displacement
of atoms in layers above and below. Here we discuss sagittal
solutions
plane is a symmetry
even and odd solutions. ceeding spectral
as described
along the ry
plane the equations
The resulting
equations
separate
direction.
into two subsets for
are solved analytical
in ref. 4. Phonon dispersion
Since the
curves are obtained
by profrom the
densities
Pa&~ZK,+‘;QIW)
=g
for Q, oriented
= 1 $(Ql,‘lZK)e;(Q,f$K’) * G-w,(Q,)) S
[Uas(fz ~,Li~';Q,,w+ic)
A detailed
account
- U
aB
(!2 K,&;K';Qp,w-ie)] z
for the equations
odd modes will be presented
.
for the Green's functions
in a separate
publication.
(12) for the even and
51 4. APPLICATION
TO THE ~(2x2) OXYGEN OVERLAYER
In this section we present overlayer
obtained
tions and compare bour coupling.
with our new model which includes the results to those previously
Before we proceed
fect of the proposed layer substrate frequency
attractive
interac-
with nearest neigh-
to demonstrate
the ef-
atom and the second
with (pi*. For this purpose we calculate
the
modes of the system at 7 and at 51 as a func-
force pb2 keeping
all other parameters
of the modes for which the calculation
w IE,r)
second neighbour
obtained
it may be illuminating
of a few characteristic
Fig. 4. We take the remaining
curves for the oxygen
force between the adsorbate
atom parametrized
tion of the attractive vectors
results for the dispersion
parameters
is performed
fixed. The eigen-
are displayed
in
as: (p;;T= 2.43; g:. = 0; ml2 = 0;
‘00’013
lpamllel
w,lE.jo Iparallel adsorbate
Fig. 4. Eigenvectors for a few characteristic the high symmetry points r and X.
model
0000
modes of the ~(2x2) overlayer
in
= 1, in units of the bulk nickel force constant. The mass Ma and the vertiq1;2 cal distance R, for the adsorbate atom are taken so as to simulate oxygen (MA = 16, RI = 0.9 8). The results for frequencies lel adsorbate o(Al,x) cantly
are little affected.
The vertical
adsorbate
reduced. One has to keep in mind, however,
In a physical effect
are plotted
modes w(E,T) and u2(E,?) and the vertical
realistic
observed nonzero.
is the Rayleigh
reduction
mode o(Al,.)
which
of the frequency
wave at the zone boundary.
of the frequency
mode at 7 is signifi-
that mb2 is kept zero here.
model mi2 should increase with %2
of 'pb2 on UI(A~,T). A large reduction
w~(E,X) which
in Fig. 5. The paraladsorbate
balances
the
occurs with
This shows that the
of the mode is an indication
of q)b2 being
Fig. 5. Characteristic frequencies of the ~(2x2) surface as a function of the attractive interaction between the adsorbate and the second layer atom.
%‘a0
We now compare overlayer
the results for the dispersion
obtained
in our present
calculation,
with those in Ref. 1. The parameters bour interaction
and the attractive
layer we choose
stress included,
used in the old model with nearest
neigh-
only (Fig. 5a) are miI = 2.43; o;O = 0.23, mi2 = 0.3 in units
of the bulk force constant. teraction
curve of the ~(2x2) oxygen
with internal
For the new model with second nearest force between the adsorbate
neighbour
~6~ = 2.5; qi2 = 0.7; $jo = 0.28; gy2 = 0.8 and pi2 = 0.35a.
with a, = 2.49 R the surface models the intralayer
lattice constant
coupling
constant
of the clean surface.
between the nickel surface
For both atoms (pi1
was kept at the bulk value. As can be seen from Fig. 6 the model provides slightly
better fit to the data in tracking
closely.
Here, we have made no attempt to model the upwards
cal branch near l' by including
dipole-dipole
the vertical
interactions
tage of the new model
is that it no longer requires
the nearest
model.
neighbour
straightforward
in-
atom and the second
and physical
The main advantage appealing
served with carbon and nitrogen
branch more
shift of the verti-
(ref. 4). The advan-
my2 to be as small as with
is, however,
explanation
overlayers.
adsorbate
a
that it provides
for the reconstruction
ob-
a
53
wthoutmternal
stress
wtihmternalstress
5w~l5
- 15
500-
100
0
0.5
F
1.0
the frequencies
1.0
seen in Fig. 5 the most dramatic
is with the A2-mode
actually
to reconstruction equation
0.5
TO THE RECONSTRUCTION
As was already
the A2-mode
0
x
g=Q,ll.26 A-'
5. APPLICATION
Fig. 6. The dispersion curves for surface modes and resonances calculated in the nearest neighbour model (left) and with second nearest neighbour interaction and internal stresses.
3
of motion
is (in our model)
becomes soft and the surface
to a p4g(2x2)
structure
for the A2-mode entirely
effect
of the force '~6~ on
at y. For gb2 exceeding becomes
value
instable with respect
(compare Fig. 4 and Fig. 2). The
at x is particularly
localized
a particular
simple since the mode
to the first nickel layer.
Its frequency
is
MSu
2
which
2 = '~1;~+ 'Pi2/ao + 2~;I(a,/2
using
2 -I/2 + RI)
(I31
(7) and (8) becomes
(I41 Obviously
this mode becomes soft when
(I51
54 This is the stability the phase boundary perature
phase diagram.
bility of structures physical
picture
particular
construction
criteria
The three overlayers
interaction
tation as to why the surface the phonon anomaly
parameters
should vary in a
of sulfur, oxygen and carbon differ
is not known). As can be seen from the stahas a larger propensity
RI is, even with $,2 kept constant.
The model presented
for the sta-
which are 1.35 8; 0.9 8 and 0.1 8, respec-
(15) the ~(2x2) overlayer
the smaller
it marks
in a zero tem-
have been derived earlier
as to why particular
the distance
As an equation structure
W(100)surface (ref. 8). There, however, no
RI of the adsorbate
larger attractive surface.
Similar
was provided
(for nitrogen
bility criterion
for the ~(2x2) surface.
on the clean
direction.
in the distances tively
criterion
between the ~(2x2) and the p4g(2x2)
pi2 is expected here therefore behaves
when the adatom
provides
towards
In addition,
is closer to the
a very appealing
normal with a sulfur overlayer,
with oxygen and reconstructs
rea
interpredisplays
with carbon.
ACKNOWLEDGEMENTS The work of T.S. Rahman was partially Foundation
under Contract
from NATO Research
No. DMR-8402850.
supported
by the National
We also acknowledge
Science
travel support
Grant No. 075/84.
REFERENCES 1 2 3 4 5 6 7 8
J.M. Szeftel, S. Lehwald, H. Ibach, T.S. Rahman, J.E. Black and D.L. Mills, Phys. Rev. Lett. 51 (1983) 268 J.H. Onuferko, D.P. Woodruff, B.W. Holland, Surface Sci. 131 (1983) 245 W. Daum, to be published T.S. Rahman, D.L. Mills, J.E. Black, J.E. Szeftel, S. Lehwald and H. Ibach, Phys. Rev. B 30 (1984) 589 S. Lehwald, M. Rocca, H. Ibach and T.S. Rahman, Phys. Rev. B 31 (1985) 3477 J.W.M. Frenken, J.F. von der Veen and 6. Allan, Phys. Rev. Lett. 51 (1983) 1876 A similar model has also been proposed by S.C. Ying in these Proceedings A. Fasolino, G. Santoro and E. Tosatti, Phys. Rev. Lett. 44 (1980) 1684
ADSORBATE
INDUCED RECONSTRUCTION
T.S. RAHMANI,
of Physics,
lDepartment *IGV/KFA
M. ROCCA*',
JUlich,
OF Ni( 100)
S. LEHWALD',
H. IBACH'
Kansas State University,
Postfach
1913,
45
D-5170
Jijlich
Manhattan
KS 66506, USA
(F.R. Germany)
ABSTRACT We have carried out a systematic lattice dynamical study of the ~(2x2) overlayer of oxygen, sulfur and carbon (nitrogen) on Ni(lOO). The model consists of nearest neighbour interactions between all atoms and an additional (attractive) interaction between the adsorbate atoms and the second neighbour substrate atom directly below, which consequently introduces internal stresses. We show that the relative strength of the internal stress and the coupling between the first and second layer nickel atoms determine whether the Ni(lOO) surface will reconstruct. The presence of the attractive force between the adsorbate atoms and the second layer nickel atoms allows us to explain the observed anomaly in the dispersion of the Rayleigh wave for the oxygen overlayer on Ni(lOO) and leads to a natural explanation for the reconstruction pattern observed in the presence of the carbon and nitrogen overlayers via softening of a substrate phonon.
1. INTRODUCTION In the past several years a number of experimental on the structure
and dynamics of the Ni(lOO) surface,
or in the presence
of ordered overlayers
we will be concerned
with two particular
which are (i) the anomalous
low freqency
and theoretical
have become available. intriguing
aspects
of the Rayleigh
In this paper
of these studies
surface phonon at the
zone boundary when the surface is covered with a ~(2x2) overlayer (ref. 1) and (ii) the reconstruction layer of carbon ysis
(ref. 2) and nitrogen
interaction
between the adsorbate
of the adsorbate
teraction
controls
of oxygen
of the nickel surface with a ~(2x2) over(ref. 3). Using a lattice
it will be shown that both phenomena
distance
studies
either in the clean form
have a common origin
dynamical
atom and the second layer substrate
to the surface and the strength
whether the phonon spectrum displays
anal-
in an attractive atom. The
of the attractive
anomalies
in-
or the sur-
face reconstructs. In previous
lattice dynamical
face phonon branches
*Permanent
address:
0368-2048/86/$03.50
a nearest
analyses
neighbour
of the experimentally central force model
observed
sur-
(ref. 4,5) was
Dipartimento di Fisica, Universitl degli Studi di Genova, Via Dodecanso 33, I-16100 Genova, Italy
0 1986 Elsevier Science Publishers B.V.
46 used. Within this model the softening could be described
of the Rayleigh wave at the zone boundary
by making the force constant
between the nickel atoms in the
first layer and the nickel atoms in the second layer rather small, namely 30 % of the bulk force constant. the dispersion
curves was obtained.
found necessary
surface
at the X-point
a reasonable
No reduction
of this force constant was
discovered
corresponds
of the surface
that the p4g(2x2)
to the displacement Brillouin
interactions
reconstruction
of sul-
of the car-
pattern of the A2-eigenmode
zone of the unreconstructed
face (ref. 5). Within this simple lattice dynamical neighbour
overall fit of
in order to reproduce the data for a ~(2x2) overlayer
fur. It was furthermore bon covered
With this assumption
~(2x2) sur-
model involving
nearest
only, this mode would become soft when the force con-
stant between the first layer nickel atoms and the second layer nickel atoms approaches
zero. While this simple lattice dynamical
lish a connection
between
remained problematic reduction
in the force constant.
bour interactions longer
the observed
in its physical
phonon anomaly
picture
with additional
attractive
propensity struction
parameter
of the adsorbate
when the distance
The paper is organized description
Green's
the results for the dispersion
and eventually becomes
on Ni(lOO).
spectral
is described
densities
section
to the discussion of the structure
2. (2x2) STRUCTURES Ordered
sponding
dynamiFourier
In section
of the reconstruction.
of (2x2) overlayers
These overlayers
We now turn to a surface.
of 25 % and 50 % of
with ~(2x2) overlayers
may be obtained
genides Te, Se, S and 0, each being positioned
(save for an overall
vertical
in the fourfold
is that of a ~(2x2) structure.
relaxation
corre-
with the chalcohollow site as
shown in Fig. la. Since the nickel atoms remain at their positions
tion pattern
nickel sur-
study. The final
on the Ni(lOO)
on Ni(lOO) are formed with coverages
Here we will be only concerned
to 50 % coverage.
clean surface
4
ON Ni(lOO)
structures
the adsorbate.
The lattice by employing
curves for the ~(2x2) oxygen covered
and compared to results of the previous
brief description
recon-
smaller.
in the third section.
face are presented is devoted
our study
of the surface
In the next section we provide a brief
of (2x2) overlayers
functions
no
layer. As will be seen the
of the adsorbate
cal model and our method of calculating transformed
the behaviour
phonon anomalies
as follows.
of the geometry
interactions
nickel atoms and the
small. Furthermore
controlling
from the surface
of the surface to display increases
it
second nearest neigh-
(and repulsive)
between the surface
next layer nickel atoms to become unphysically
is the distance
and the reconstruction
because of the required drastic
The new model involving
requires the force constant
will show that an important
model was able to estab-
as for the
(ref. 6)) the diffrac-
The unit cell of this structure
47
L
t1001 [llOl
/ \\ //
Fi
ElII 'R '\ t /' \/
b
a
Fig. 1. a) (100) surface with a ~(2x2) overlayer. The dashed line is the surface unit cell. b) Brillouin zone for the clean and ~(2x2) surface (full and dashed line, respectively).
contains
one adsorbate
face Brillouin
the chalcogenides both adsorbates
atom and two nickel atoms in each nickel layer. The sur-
zone is depicted
in Fig. lb. Overlayers
of the same type as with
can also be formed with carbon and nitrogen.
the nickel surface
reconstructs
to form a p4g(2x2)
(ref. 2,3). The unit cell is now as with a (2x2) overlayer. tions in the diffraction dicular
pattern
glide planes oriented
ture as originally
proposed
indicate the presence
extinc-
of two mutually
perpen-
The geometric
struc-
et al. (ref. 2) is shown in Fig. 2. AS
can be seen from the figure the reconstruction and clockwise
structure
Systematic
along the [loo] direction.
by Onuferko
However with
consists
of a counter
clockwise
rotation
of the nickel atoms around the adsorbate
atoms. Experi-
mental and theoretical
studies of the surface phonon dispersion
of this struc-
ture have been performed.
These results will be reported
tion. Here we are concerned
with the lattice dynamics
and the forces which drive the surface
in a separate
publica-
of the ~(2x2) structure
into the observed
reconstruction.
48 3. THE LATTICE
DYNAMICAL
The lattice proximation
dynamics
MODEL of the nickel surface
The Hamiltonian
using pair potentials.
where uu is the ath Cartesian K in the layer arbitrarily
component
tz with the position
chosen
pair potential
origin,
is treated
in the harmonic
therefore
of the displacement
vector LI connecting
ap-
assumes the form
of the atom labeled
the unit cell with an
M is the mass of the atom and P its momentum.
The
is given by
o,,(ij) = 6ij z, Ka,(ij')
- (I-'ij) K,B(ij)
J with the effective
K,,(ij)
=
L
force constant
K as
6as + (‘Pyj -'j
Iri
I
Here oij and myj are the first and second derivations
of the pair potential
and
fi is the unit vector from atom i to atom j. As in the previous interactions
only are assumed
Equilibrium tential
conditions
vanishes,
the minimum
of the pair potential
by including
connecting
for a reasonable
the second
of the pair poposition
neighbour
interaction
bility criterion
of the bulk phonon spectrum
ferent atoms.
(ref. 7)
between the adsorbate
atom and
With such second neighbour
interac-
of the potentials
need no longer vanish.
The sta-
that the net force on each atom must vanish generates
between the first derivatives
at
the atom to its next neighbour.
representation
layer nickel atom underneath.
tions the first derivatives
neighbour
for atoms in the second nickel layer and below.
then require that the first derivative
For atoms near the surface we go beyond this simple model
the second
relations
study of this system nearest
i.e. each atom in the bulk has its equilibrium
This model suffices of nickel.
lattice dynamical
of the pair potentials
In our model we assume an attractive
interaction
a set of
connecting
dif-
between the ad-
sorbate and the second layer nickel atom (vi2 > 0). This requires a repulsive interaction
between
the adsorbate
atom and the first layer nickel atom ($2
<
0) (Fig. 3). The force on the first layer nickel atoms then needs to be balanced by a repulsive may proceed
interaction
in two different
to nickel atoms in the second layer. Now, one
ways.
In order to balance the force on the first
nickel layer atoms one could introduce layer. These would then require further
a cp'to all nickel atoms in the second 9' to atoms below and so forth. A par-
49
,,~
layer Iqa
Fig. 3. The figure illustrates the force constants which couple the adatom in layer 0 (labelled as +) among each other (p;O), to the first layer nickel atoms (qbI, cpjjl), and to the second layer nickel atoms (f&s @2)s and also-the force constants coupling the first layer nickel atoms to atoms in the second layer via as seen in sectional view AA' or as seen in sectional view BB'. further discussion.
0 1
/’
layer 2
88’
sde
9
“lew
CR\
'\
'\ ,/ '\\,/ b
titularly
hyer 1
(9
‘+ ,/' '\ /' u
layer 2
simple choice of balancing
the force is to connect
the first layer
nickel atoms with 9' only to the second layer nickel atoms below the adsorbate atom
(Fig. 3). The three equations
for having no net forces on the adsorbate,
first layer nickel atom and second layer nickel atom in z-direction
then read
4qbl n,(Ol) + 'pb2 n,(O2) = 0
(4)
2Pbl
(5)
n,(lO)
+ 2$2
Vb2 nZ(20) + 4$2
n,(12) n,(21)
= 0
(6)
= 0
where n,(ij) is the z-component three equations
which
are fulfilled
of the unit vector from atom i to atom j. These
with
leaves the force between the adsorbate
as the only free parameter x and y-direction
of the potentials.
the net forces on the atoms vanish because
choice of balancing have however
and the second layer nickel atom
for the first derivative
the forces as described
also explored
anced in the alternative
procedure
of symmetry.
above is particularly
the lattice dynamics as described
For the The
simple. We
of the system with forces balabove. No significant
differ-
50 curves were found. We note further that our model with
ences in the dispersion internal
stresses
would be compatible
sition of the nickel atoms, Since no such detailed
with adsorbate
in particular
data is available
induced shifts of the po-
with a buckling
of the second layer.
on the surface structure
we kept the
atoms at their bulk positions. The lattice Green's
dynamical
functions
model
constructed
is evaluated
with the aid of Fourier
transformed
from the eigenvectors
*
U
(eZ~;L;~‘;Q,~)
a6
=
ei(Ql;fzK)ei(Ql;f;K’)
1
2 w -
S
where ei(QII;IZ~) is the ath Cartesian s, with Q, the wave-vector the displacement eigenfrequency function
component
of the atom
K
(9)
ag(Q,) component parallel
of the eigenvector
to the surface
for the mode
associated
with
in the unit cell in the layer P.z, m,(Q,) is the
and w is the frequency.
The equation
of motion
for the Green's
is
with the dynamical
Matrix iQ,,[Ro(fraZK)-Ro(L;$KI1)]
@aB(tIEzK,g;t;K”)
Das(QI;tZ~;ll;~“)
= 1
.
a'; [M(L~K)M(~;K”)]~‘~
As can be seen the equations ed from the eigenvectors
e
of motions
couples the Green's
of the atoms in a particular
function
(11)
construct-
layer to the displacement
of atoms in layers above and below. Here we discuss sagittal
solutions
plane is a symmetry
even and odd solutions. ceeding spectral
as described
along the ry
plane the equations
The resulting
equations
separate
direction.
into two subsets for
are solved analytical
in ref. 4. Phonon dispersion
Since the
curves are obtained
by profrom the
densities
Pa&~ZK,+‘;QIW)
=g
for Q, oriented
= 1 $(Ql,‘lZK)e;(Q,f$K’) * G-w,(Q,)) S
[Uas(fz ~,Li~';Q,,w+ic)
A detailed
account
- U
aB
(!2 K,&;K';Qp,w-ie)] z
for the equations
odd modes will be presented
.
for the Green's functions
in a separate
publication.
(12) for the even and
51 4. APPLICATION
TO THE ~(2x2) OXYGEN OVERLAYER
In this section we present overlayer
obtained
tions and compare bour coupling.
with our new model which includes the results to those previously
Before we proceed
fect of the proposed layer substrate frequency
attractive
interac-
with nearest neigh-
to demonstrate
the ef-
atom and the second
with (pi*. For this purpose we calculate
the
modes of the system at 7 and at 51 as a func-
force pb2 keeping
all other parameters
of the modes for which the calculation
w IE,r)
second neighbour
obtained
it may be illuminating
of a few characteristic
Fig. 4. We take the remaining
curves for the oxygen
force between the adsorbate
atom parametrized
tion of the attractive vectors
results for the dispersion
parameters
is performed
fixed. The eigen-
are displayed
in
as: (p;;T= 2.43; g:. = 0; ml2 = 0;
‘00’013
lpamllel
w,lE.jo Iparallel adsorbate
Fig. 4. Eigenvectors for a few characteristic the high symmetry points r and X.
model
0000
modes of the ~(2x2) overlayer
in
= 1, in units of the bulk nickel force constant. The mass Ma and the vertiq1;2 cal distance R, for the adsorbate atom are taken so as to simulate oxygen (MA = 16, RI = 0.9 8). The results for frequencies lel adsorbate o(Al,x) cantly
are little affected.
The vertical
adsorbate
reduced. One has to keep in mind, however,
In a physical effect
are plotted
modes w(E,T) and u2(E,?) and the vertical
realistic
observed nonzero.
is the Rayleigh
reduction
mode o(Al,.)
which
of the frequency
wave at the zone boundary.
of the frequency
mode at 7 is signifi-
that mb2 is kept zero here.
model mi2 should increase with %2
of 'pb2 on UI(A~,T). A large reduction
w~(E,X) which
in Fig. 5. The paraladsorbate
balances
the
occurs with
This shows that the
of the mode is an indication
of q)b2 being
Fig. 5. Characteristic frequencies of the ~(2x2) surface as a function of the attractive interaction between the adsorbate and the second layer atom.
%‘a0
We now compare overlayer
the results for the dispersion
obtained
in our present
calculation,
with those in Ref. 1. The parameters bour interaction
and the attractive
layer we choose
stress included,
used in the old model with nearest
neigh-
only (Fig. 5a) are miI = 2.43; o;O = 0.23, mi2 = 0.3 in units
of the bulk force constant. teraction
curve of the ~(2x2) oxygen
with internal
For the new model with second nearest force between the adsorbate
neighbour
~6~ = 2.5; qi2 = 0.7; $jo = 0.28; gy2 = 0.8 and pi2 = 0.35a.
with a, = 2.49 R the surface models the intralayer
lattice constant
coupling
constant
of the clean surface.
between the nickel surface
For both atoms (pi1
was kept at the bulk value. As can be seen from Fig. 6 the model provides slightly
better fit to the data in tracking
closely.
Here, we have made no attempt to model the upwards
cal branch near l' by including
dipole-dipole
the vertical
interactions
tage of the new model
is that it no longer requires
the nearest
model.
neighbour
straightforward
in-
atom and the second
and physical
The main advantage appealing
served with carbon and nitrogen
branch more
shift of the verti-
(ref. 4). The advan-
my2 to be as small as with
is, however,
explanation
overlayers.
adsorbate
a
that it provides
for the reconstruction
ob-
a
53
wthoutmternal
stress
wtihmternalstress
5w~l5
- 15
500-
100
0
0.5
F
1.0
the frequencies
1.0
seen in Fig. 5 the most dramatic
is with the A2-mode
actually
to reconstruction equation
0.5
TO THE RECONSTRUCTION
As was already
the A2-mode
0
x
g=Q,ll.26 A-'
5. APPLICATION
Fig. 6. The dispersion curves for surface modes and resonances calculated in the nearest neighbour model (left) and with second nearest neighbour interaction and internal stresses.
3
of motion
is (in our model)
becomes soft and the surface
to a p4g(2x2)
structure
for the A2-mode entirely
effect
of the force '~6~ on
at y. For gb2 exceeding becomes
value
instable with respect
(compare Fig. 4 and Fig. 2). The
at x is particularly
localized
a particular
simple since the mode
to the first nickel layer.
Its frequency
is
MSu
2
which
2 = '~1;~+ 'Pi2/ao + 2~;I(a,/2
using
2 -I/2 + RI)
(I31
(7) and (8) becomes
(I41 Obviously
this mode becomes soft when
(I51
54 This is the stability the phase boundary perature
phase diagram.
bility of structures physical
picture
particular
construction
criteria
The three overlayers
interaction
tation as to why the surface the phonon anomaly
parameters
should vary in a
of sulfur, oxygen and carbon differ
is not known). As can be seen from the stahas a larger propensity
RI is, even with $,2 kept constant.
The model presented
for the sta-
which are 1.35 8; 0.9 8 and 0.1 8, respec-
(15) the ~(2x2) overlayer
the smaller
it marks
in a zero tem-
have been derived earlier
as to why particular
the distance
As an equation structure
W(100)surface (ref. 8). There, however, no
RI of the adsorbate
larger attractive surface.
Similar
was provided
(for nitrogen
bility criterion
for the ~(2x2) surface.
on the clean
direction.
in the distances tively
criterion
between the ~(2x2) and the p4g(2x2)
pi2 is expected here therefore behaves
when the adatom
provides
towards
In addition,
is closer to the
a very appealing
normal with a sulfur overlayer,
with oxygen and reconstructs
rea
interpredisplays
with carbon.
ACKNOWLEDGEMENTS The work of T.S. Rahman was partially Foundation
under Contract
from NATO Research
No. DMR-8402850.
supported
by the National
We also acknowledge
Science
travel support
Grant No. 075/84.
REFERENCES 1 2 3 4 5 6 7 8
J.M. Szeftel, S. Lehwald, H. Ibach, T.S. Rahman, J.E. Black and D.L. Mills, Phys. Rev. Lett. 51 (1983) 268 J.H. Onuferko, D.P. Woodruff, B.W. Holland, Surface Sci. 131 (1983) 245 W. Daum, to be published T.S. Rahman, D.L. Mills, J.E. Black, J.E. Szeftel, S. Lehwald and H. Ibach, Phys. Rev. B 30 (1984) 589 S. Lehwald, M. Rocca, H. Ibach and T.S. Rahman, Phys. Rev. B 31 (1985) 3477 J.W.M. Frenken, J.F. von der Veen and 6. Allan, Phys. Rev. Lett. 51 (1983) 1876 A similar model has also been proposed by S.C. Ying in these Proceedings A. Fasolino, G. Santoro and E. Tosatti, Phys. Rev. Lett. 44 (1980) 1684