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First Chern class of lattice magneto-Bloch bundles
Vol. 38 (1996)
FIRST
REPORTS
CHERN
CLASS
ON
MATHEMATIC4L
OF LATTICE
PHYSICS
MAGNETO-BLOCH
BUNDLES
V. A. GEYLER Department
of Mathematics,
Mordovian State University,
Saransk 430000,
Russia
(Received February 15. 1996)
The magneto-Bloch bundle of a lattice Hamiltonian in a uniform magnetic fic,ld is considered. It is shown that the first Chern class of the bundle vanishes.
1.
Introduction Topological
dimensional
investigations
Schrodinger
of the magneto-Bloch
operators
of S. P. Novikov [I]. In particular, associated its Chern
with a fixed Landau number
collaborators mathematical
with a uniform
point
the effect
before
level have an irregular
has its origin
In the case of a rational the fulfilment satisfy
in the paper
cell of periods
vector bundle is nontrivial
[l], K. von Klitzing
quantization
[Z].
in the equality
associated
From
the
(‘1 = 1 (see
with magnetic
If the number
and with
subbands
7 of the magnetic
flux
Al, then the numbers (i) satisfying the conservation law C c1 = 1 (see [I ~ 4, 71). number 7 (n = M/N, where M and N are coprime integers),
of an additional
the Diophantine
behaviour.
operator
the article
of the Hall conductance
of view this quantization
quanta through an elementary ci” may be arbitrary integers
for t,wo- and three-
field originated
level ~1 of a two-dimensional
[3--61). The Chern classes c1(1) , . . . , cl(nl of subbundles of a fixed Landau
bundles
Novikov showed that the magneto-Bloch
cl is equal to one. Shortly
discovered
vector magnetic
condition
equation
is equal to an integer
is required.
Namely,
the numbers
(T = c\“’ must
[3, 81:
Mo-tNm
=
1.
(1)
In the last few years the Hall conductance of lattice models become a matter of considerable interest (see e.g. [9915]). It is shown for tight-binding Hamiltonian on the square lattice that the sum of contributions from all magnetic subbands to the Hall conductance is zero [9]. The related result for the lattice Hamiltonian with next-nearest,neighbour hopping is obtained in [lo]. Our purpose is to show that these results are special cases of a general topological assertion. More precisely, we consider an arbitrary lattice Hamiltonian H which is invariant with respect to magnetic generalized eigenvectors of H which are transformed by irreducible magnetic
translation
group W, form a vector 13331
bundle
translations [16]. The representations of the
E (if W, is commmativc,
then
E
334
V. A. GEYLER
is precisely the magneto-Bloch bundle analysed in [6-91. We prove that the first Chern class cl of E vanishes. Some of physical applications of this statement are discussed in 1171. 2.
Preliminaries
Let us introduce the basic notation. We shall denote by A a two-dimensional lattice with basis vectors al, a2 (al, a2 E R2), thus (1 = {Xlal+ &as : X1, X2 E 25). We denote by Q the elementary cell of A: Q = {tlal + t2az : 0 < tl, t2 < I}. Let us consider a discrete n-invariant subset I’ of the plane IR2; we shall suppose without loss of generality that 0 E r. Thus r has the form r = ASK, where K is a finite subset of Q containing 0; we denote by k the number of elements of K. The state space we consider is the sequence space ‘FI = 12(r). Let 77 E R, v > 0; we denote by IV, the discrete group of magnetic translations [16]. The group IV, consists of all the pairs (X,5), where X E n and < is a number of the form exp (ring) , n E Z. The multiplication in W, is defined as follows: = (A + X’, cc’ exp (&5X A X’)) Here the symbol A denotes the standard (al A az)-% We define a representation on I’ as follows [18, 191:
symplectic
multiplication
(2) in lR2, and 6 =
D of the group W, in the space of complex functions
D(h C)$(r) = Sexp(~0 A Y)~(Y- A).
4
(3)
The representation D is in some sense an analogue of the continuous Zak representation [16]; the parameter 77plays the role of the number of magnetic flux quanta through the cell Q. It is evident that Eq. (3) defines a faithful unitary representation of W, in the space Ft. The group W, is a group of type I (see [20]), if and only if 77is a rational number [21]. Furthermore, W, is a commutative group if and only if q is an integer. In connection with this we shall consider rational values of the flux 77only: 77= M/N. We recall that a unitary representation T of the group W, is called the physical one if T(0, <) = [I. Obviously, D is a physical representation. All irreducible physical representations of the group WV are described as fo!lows [16]: Such representations of W,, are N-dimensional and are parameterized in a unique way by points of the torus Tz = [0, N-l) x [0,1). The operators DP(X,<) of these representations
in the standard
basis of the space CN on the generators (al,
1) and (a2, 1)
are given by the matrices e-2ripl
0 .
Dp(al,1)= L
0
... 0 e-wPl+17) .,.
0 0 0
0i
.... .
e-24~1+(N--lh)
(4)
FIRST
CHERN
CLASS OF LATTICE
(here
and below I,
o
the n x n-identity
denotes
integral
of physical
irreducible
335
BUNDLES
>
matrix).
the group W, is of type I, we can decompose
Because direct
IN-1 e-Ztp2 (
1) =
D&2,
MAGNETO-BLOCH
representations
D into the
the representation
[22]:
6
IFi =
‘FIY
Each fibre g(p) representation kN).
D-L?
%(p)dp:
J’ T2,
in (6) is isomorphic
.I’ T%
&dp.
(6)
to the space @” @ CN @ @” and is a carrier
of W, which is a multiple
The transformation
=
.Fq which realizes
of a
D, (with the multiplicity
of the representation the isomorphism
of the spaces
3-t and G in
(6) has the form
x exp[7ri
of the natural
s T2,
pz~[O,l),
Statement
3.
of the direct
j,mE{O,l,...,
Let H be a self-adjoint integral
@ @” @ C” @
integral N-l},
fi
C” ,
as functions
(8)
of five variables:
KEK.
of results operator
D.
of the representation direct
7?(p) dp = L2(T;)
here the elements
pi~[0,N-‘),
+ m + 2j))].
isomorphism $
we consider
+ X2p2 + (r]/2)Xi(NX2
Then
in ‘l-i which is invariant
[22] HZ
with respect
I? = F,,H.F;l
the operator
to the operators
is decomposable
into the
@ s
G(P)
dP >
(9)
Tf “;l(P_), and G(P) where every fibre H(p) is an operator in the finite dimensional-space is invariant with respect to the operators of the representation D,. Thus N(p) has kN eigenvalues: El(P)
each of which is N-fold continuous
functions
I
degenerate.
&2(P) i
. ‘. 5 &V(P)
We shall suppose
that the dispersion
of p. Let El-l(P)
< &I(P)
>
< &1+1(P)
(10) laws EL(P) are
336
V.A.GEYLER
The corresponding eigenspace El(p) is an N-dimensional subspace of 7?(p). In virtue of (7), to the eigenspace El(p) there corresponds an N-dimensional vector space El(p) of generalized eigenvectors of the operator H. It is easy to show that El(p) c l""(F),and El(p) is invariant with respect to the representation D. The elements of El(p) are called magneto-Bloch eigenfunctions of the quasimomentum p for the I-th band of the spectrum a(H). The space El = U{El(p); p E T:} admits in an obvious way the structure of a vector bundle over the torus TG. If all the vector bundles El are defined, then the direct sum E = $ El is independent on the operator H. Formally, the fibre E(p) of the bundle E over the point p E Tg is the subspace Ftl
G(p) of the space l”(r). We shall call ( > bundle. It is self-evident that the correct definition of the
E the lattice magneto-Bloch
fibre E(p) requires to replace the map J=q in the expression Fql
by its extension > onto an appropriate space of distributions. We omit the tedious details; the scrupulous reader may accept the result of formal calculations by formula (11)as the definition of the fibre E(p). THEOREM. COROLLARY.
(
e(p)
The first Chern class cl of the vector bundle E vanishes. Let the bundle E be represented as a direct sum of subbundles El
l,..., n < AN), and let c$l) be the first Chern number of the bundle El. Then cl’) +
(l= ...+
CI”’= 0.
Sketch of the proof of the theorem: It is a matter of direct verification to prove that for a function f Eti = L2(T;)@CN@@“@C” the vector C$= .F;‘f
has the form
qb(Alal + (NX2 + m)a2 + +niMA~b]
n) = exp
x Nc exp (2riAl{vj}) j=o
[ - 7ri<(lf.+ ma2) A (Ala1 + (X2N + m)a2)+ / f (p,j, m, K) exp[2ni(Ml+
~zpz)] dp,
(11)
T:,
where {z} denotes the fractional part of a number Z. Using (11)we can obtain that the sequences $j,,,,,,, (p) (j’, m’ E (0, 1, . . , N - l},K' E K), where ti.g~,m~,n~(p): (Alal t-+
Lrz~&K
I
+
(NA2
exp [-nit
+
m)a2
+
K)
(K’ + m’a2) A (Ala1 + (&IV + m’)az) + dbfX1A~] x x exp Pri (Xl (PI + {17j’)) +
~2~2)1
,
(12)
form a basis in the fibre over the point p E Ti. Fix m’ E (0, 1, . . , N - l}, n’ E K and p E Tt. Then the vectors q!~~,~~,~l(p)(j runs from 0 to N - 1) span the subspace Em,+!(p) of the fibre E(p) over p. In this manner we obtain a vector subbundle E,!,,! of the bundle E. Relation (12) shows that all these subbundles are mutually isomorphic and their direct sum coincides with E. We denote for simplicity Eo = Eo,o. To prove the
FIRST
theorem,
CHERN
it remains
CLASS
OF LATTICE
to show that
MAGNETO-BLOCH
the first Chern
class cl(&)
337
BUNDLES
vanishes.
Let, us introduce
the notation N-l
([uo,
,~Lv-1];Pl~P2)
“’
=
[13)
UjE@. a,ti'j.o.o(P) 1
c
j=o As can be seen from (la),
the gluing laws of the bundle
([(co. “’ .Q-1l;m ([ao. ..’
fllN,Pz)
,aN-1];Pl,P2+1)
where B is the permutation
Let us consider
if
an N-sheeted
covering
([UO,
4.
([a07
=
ran-~l;m
+
.aA-l]:pl,p2)
(14)
:
N from the relation
= {rU1+
(1:i)
l/N.
(l(i)
permutation.
Hence from (14) and (16) we
over T2 is defined by the trivial gluing functions
l/N,p2)
g
(Lao,
”
([a07
.~N-I]:P~,P~)
.
(17)
. raN-l];PlrP2
vanishes.
(g*(EO))
‘..
({NP~)IN,P~).
(15) implies that crN IS the identity
([ao. .
~1
”
9 : T2 4 Tz given by the formula
see that the induced vector bundle g*Ee
Hence
([am(o), ‘.. >%(,V~1)l;Pl,P2) 1
{r/j’)
dm,~2)
Formula
”
which is defined modulo
cr(j) = j’
Ee have the form
+
1)
Since cl (g*(Ee))
.
= Nci(&)
>a,V-l];pl.p2).
[23], we have cl(&)
= 0.
•I
Remarks (1) The magneto-Bloch
different
bundle
the sublattice form
of A generated
where
A by A’ and K by K’ we obtain
E and E’ are different.
in [9; lo] (we denote
Moreover,
it by E’)
is rather
E and E’ is as follows. Consider al and Nap. Then r is represented in the between
by the elements
r = A’ + K’ , Replacing
considered
E. The relationship
from the bundle
K’ = K + (0.1,
, N - 1).
(13)
E’ as above. If n # A’. the bundles E’ is always isomorphic to a t,rivial one
the bundle
the bundle
[241’ (2) Although
the bundle E’ is trivial, we can obviously decompose it into a direct For example! let 77 = l/3 and let H he the tightsum of nontrivial vector bundles. binding Hamiltonian H = C cIcp exp idxP (the summation is taken over all the nearest,neighbour sites); the phase factor 0x,, is defined on a link and represents the magnetic field ~1, i.e., c
o+
plaquette
= 27q
and
HA,, = -0,x
338
V.A. GEYLER
The spectrum of H consists of three isolated magnetic subbands and each subband Bj defines a subbundle Ei of the magneto-Bloch bundle E’. It may be shown by the straightforward calculation that the Chern numbers cl(Ei) of the corresponding subbundles are as follows: cl (E;) = cl (E;) = 1, cl (Ei) = -2 (see also numerical calculations in [9]).
Acknowledgements I am grateful to V. A. Margulis and I. Yu. Popov for useful remarks. The work is partially supported by RFFR and the Ministry of Higher Education of Russian Federation. REFERENCES [l] Novikov S.P.: Sov. Math. Dokl. 23 (1981), 298. [2] von Klitzing K., Dorda G. and Pepper M.: Phys. Rev. LeU. 45 (1980), 494. [3] Thouless D.J., Kohmoto M., Nightingale M.P. and den Nijs M.: Phys. Rev. Lett. 49 (1982), 405. [4] Avron J.E., Seiler R. and Simon B.: Phys. Rev. Lett. 51 (1983), 51. [5] Thouless D.J.: J. Math. Phys. 35 (1994), 5362. [6] [7] [8] [9] [lo] [ll] [12] [13] [14] [15] [16] [17] [18] [19] [20]
Bellissard J., van Elst A. and Schulz-Baldes H.: J. Math. Phys. 35 (1994), 5373. Lyskova A.S.: Theor. Math. Phys. (USSR) 65 (1986), 1218. Dana I., Avron Y. and Zak J.: J. Phys. Cl8 (1985), L679. Kohmoto M.: Phys. Rev. B39 (1989), 11943. Hatsugai Y. and Kohmoto M.: Phys. Rev. B42 (1990), 8282. Bellissard J., Kreft C. and Seiler R.: J. Phys. Math. Gen. A24 (1991), 2329. Barelli A. and Fleckinger R.: Phys. Rev. B46 (1992), 11559. Hatsugai Y., Kohmoto M. and Wu Y.-S.: Phys. Rev. Lett. 73 (1994), 1134. Geyler V.A. and Popov I.Yu.: Zeikchr. Phys. B93 (1994), 437. Geyler V.A. and Popov I.Yu.: Zeitschr. Phys. B98 (1995), 473. Zak J.: Phys. Rev. 134 (1964), A1602. Geyler V.A. and Popov I.Yu.: JETP Lett. 63 (1996), 381. Geyler V.A.: St. Petersburg Math. J. 3 (1992), 489. Geyler V.A. and Popov I.Yu.: Phys. Lett. A201 (1995), 359. Mackey G.W.: UnitanJ Group Representations in Physics, Probability, and Number Theory, Benjamin, Boston 1978. [21] Boon M.H.: J. Math. Phys. 13 (1972), 1268. [22] Maurin K.: General Eigenfunction Expansions and Unitary Representations of Topological Groups, PWN, Warszawa 1968. [23] Bott R. and Wu L.W.: Differential Forms in Algebraic Topology, Springer, Berlin 1982. [24] Geyler V.A. and Popov I.Yu.: paper submitted to J. Phys. A.
FIRST
REPORTS
CHERN
CLASS
ON
MATHEMATIC4L
OF LATTICE
PHYSICS
MAGNETO-BLOCH
BUNDLES
V. A. GEYLER Department
of Mathematics,
Mordovian State University,
Saransk 430000,
Russia
(Received February 15. 1996)
The magneto-Bloch bundle of a lattice Hamiltonian in a uniform magnetic fic,ld is considered. It is shown that the first Chern class of the bundle vanishes.
1.
Introduction Topological
dimensional
investigations
Schrodinger
of the magneto-Bloch
operators
of S. P. Novikov [I]. In particular, associated its Chern
with a fixed Landau number
collaborators mathematical
with a uniform
point
the effect
before
level have an irregular
has its origin
In the case of a rational the fulfilment satisfy
in the paper
cell of periods
vector bundle is nontrivial
[l], K. von Klitzing
quantization
[Z].
in the equality
associated
From
the
(‘1 = 1 (see
with magnetic
If the number
and with
subbands
7 of the magnetic
flux
Al, then the numbers (i) satisfying the conservation law C c1 = 1 (see [I ~ 4, 71). number 7 (n = M/N, where M and N are coprime integers),
of an additional
the Diophantine
behaviour.
operator
the article
of the Hall conductance
of view this quantization
quanta through an elementary ci” may be arbitrary integers
for t,wo- and three-
field originated
level ~1 of a two-dimensional
[3--61). The Chern classes c1(1) , . . . , cl(nl of subbundles of a fixed Landau
bundles
Novikov showed that the magneto-Bloch
cl is equal to one. Shortly
discovered
vector magnetic
condition
equation
is equal to an integer
is required.
Namely,
the numbers
(T = c\“’ must
[3, 81:
Mo-tNm
=
1.
(1)
In the last few years the Hall conductance of lattice models become a matter of considerable interest (see e.g. [9915]). It is shown for tight-binding Hamiltonian on the square lattice that the sum of contributions from all magnetic subbands to the Hall conductance is zero [9]. The related result for the lattice Hamiltonian with next-nearest,neighbour hopping is obtained in [lo]. Our purpose is to show that these results are special cases of a general topological assertion. More precisely, we consider an arbitrary lattice Hamiltonian H which is invariant with respect to magnetic generalized eigenvectors of H which are transformed by irreducible magnetic
translation
group W, form a vector 13331
bundle
translations [16]. The representations of the
E (if W, is commmativc,
then
E
334
V. A. GEYLER
is precisely the magneto-Bloch bundle analysed in [6-91. We prove that the first Chern class cl of E vanishes. Some of physical applications of this statement are discussed in 1171. 2.
Preliminaries
Let us introduce the basic notation. We shall denote by A a two-dimensional lattice with basis vectors al, a2 (al, a2 E R2), thus (1 = {Xlal+ &as : X1, X2 E 25). We denote by Q the elementary cell of A: Q = {tlal + t2az : 0 < tl, t2 < I}. Let us consider a discrete n-invariant subset I’ of the plane IR2; we shall suppose without loss of generality that 0 E r. Thus r has the form r = ASK, where K is a finite subset of Q containing 0; we denote by k the number of elements of K. The state space we consider is the sequence space ‘FI = 12(r). Let 77 E R, v > 0; we denote by IV, the discrete group of magnetic translations [16]. The group IV, consists of all the pairs (X,5), where X E n and < is a number of the form exp (ring) , n E Z. The multiplication in W, is defined as follows: = (A + X’, cc’ exp (&5X A X’)) Here the symbol A denotes the standard (al A az)-% We define a representation on I’ as follows [18, 191:
symplectic
multiplication
(2) in lR2, and 6 =
D of the group W, in the space of complex functions
D(h C)$(r) = Sexp(~0 A Y)~(Y- A).
4
(3)
The representation D is in some sense an analogue of the continuous Zak representation [16]; the parameter 77plays the role of the number of magnetic flux quanta through the cell Q. It is evident that Eq. (3) defines a faithful unitary representation of W, in the space Ft. The group W, is a group of type I (see [20]), if and only if 77is a rational number [21]. Furthermore, W, is a commutative group if and only if q is an integer. In connection with this we shall consider rational values of the flux 77only: 77= M/N. We recall that a unitary representation T of the group W, is called the physical one if T(0, <) = [I. Obviously, D is a physical representation. All irreducible physical representations of the group WV are described as fo!lows [16]: Such representations of W,, are N-dimensional and are parameterized in a unique way by points of the torus Tz = [0, N-l) x [0,1). The operators DP(X,<) of these representations
in the standard
basis of the space CN on the generators (al,
1) and (a2, 1)
are given by the matrices e-2ripl
0 .
Dp(al,1)= L
0
... 0 e-wPl+17) .,.
0 0 0
0i
.... .
e-24~1+(N--lh)
(4)
FIRST
CHERN
CLASS OF LATTICE
(here
and below I,
o
the n x n-identity
denotes
integral
of physical
irreducible
335
BUNDLES
>
matrix).
the group W, is of type I, we can decompose
Because direct
IN-1 e-Ztp2 (
1) =
D&2,
MAGNETO-BLOCH
representations
D into the
the representation
[22]:
6
IFi =
‘FIY
Each fibre g(p) representation kN).
D-L?
%(p)dp:
J’ T2,
in (6) is isomorphic
.I’ T%
&dp.
(6)
to the space @” @ CN @ @” and is a carrier
of W, which is a multiple
The transformation
=
.Fq which realizes
of a
D, (with the multiplicity
of the representation the isomorphism
of the spaces
3-t and G in
(6) has the form
x exp[7ri
of the natural
s T2,
pz~[O,l),
Statement
3.
of the direct
j,mE{O,l,...,
Let H be a self-adjoint integral
@ @” @ C” @
integral N-l},
fi
C” ,
as functions
(8)
of five variables:
KEK.
of results operator
D.
of the representation direct
7?(p) dp = L2(T;)
here the elements
pi~[0,N-‘),
+ m + 2j))].
isomorphism $
we consider
+ X2p2 + (r]/2)Xi(NX2
Then
in ‘l-i which is invariant
[22] HZ
with respect
I? = F,,H.F;l
the operator
to the operators
is decomposable
into the
@ s
G(P)
dP >
(9)
Tf “;l(P_), and G(P) where every fibre H(p) is an operator in the finite dimensional-space is invariant with respect to the operators of the representation D,. Thus N(p) has kN eigenvalues: El(P)
each of which is N-fold continuous
functions
I
degenerate.
&2(P) i
. ‘. 5 &V(P)
We shall suppose
that the dispersion
of p. Let El-l(P)
< &I(P)
>
< &1+1(P)
(10) laws EL(P) are
336
V.A.GEYLER
The corresponding eigenspace El(p) is an N-dimensional subspace of 7?(p). In virtue of (7), to the eigenspace El(p) there corresponds an N-dimensional vector space El(p) of generalized eigenvectors of the operator H. It is easy to show that El(p) c l""(F),and El(p) is invariant with respect to the representation D. The elements of El(p) are called magneto-Bloch eigenfunctions of the quasimomentum p for the I-th band of the spectrum a(H). The space El = U{El(p); p E T:} admits in an obvious way the structure of a vector bundle over the torus TG. If all the vector bundles El are defined, then the direct sum E = $ El is independent on the operator H. Formally, the fibre E(p) of the bundle E over the point p E Tg is the subspace Ftl
G(p) of the space l”(r). We shall call ( > bundle. It is self-evident that the correct definition of the
E the lattice magneto-Bloch
fibre E(p) requires to replace the map J=q in the expression Fql
by its extension > onto an appropriate space of distributions. We omit the tedious details; the scrupulous reader may accept the result of formal calculations by formula (11)as the definition of the fibre E(p). THEOREM. COROLLARY.
(
e(p)
The first Chern class cl of the vector bundle E vanishes. Let the bundle E be represented as a direct sum of subbundles El
l,..., n < AN), and let c$l) be the first Chern number of the bundle El. Then cl’) +
(l= ...+
CI”’= 0.
Sketch of the proof of the theorem: It is a matter of direct verification to prove that for a function f Eti = L2(T;)@CN@@“@C” the vector C$= .F;‘f
has the form
qb(Alal + (NX2 + m)a2 + +niMA~b]
n) = exp
x Nc exp (2riAl{vj}) j=o
[ - 7ri<(lf.+ ma2) A (Ala1 + (X2N + m)a2)+ / f (p,j, m, K) exp[2ni(Ml+
~zpz)] dp,
(11)
T:,
where {z} denotes the fractional part of a number Z. Using (11)we can obtain that the sequences $j,,,,,,, (p) (j’, m’ E (0, 1, . . , N - l},K' E K), where ti.g~,m~,n~(p): (Alal t-+
Lrz~&K
I
+
(NA2
exp [-nit
+
m)a2
+
K)
(K’ + m’a2) A (Ala1 + (&IV + m’)az) + dbfX1A~] x x exp Pri (Xl (PI + {17j’)) +
~2~2)1
,
(12)
form a basis in the fibre over the point p E Ti. Fix m’ E (0, 1, . . , N - l}, n’ E K and p E Tt. Then the vectors q!~~,~~,~l(p)(j runs from 0 to N - 1) span the subspace Em,+!(p) of the fibre E(p) over p. In this manner we obtain a vector subbundle E,!,,! of the bundle E. Relation (12) shows that all these subbundles are mutually isomorphic and their direct sum coincides with E. We denote for simplicity Eo = Eo,o. To prove the
FIRST
theorem,
CHERN
it remains
CLASS
OF LATTICE
to show that
MAGNETO-BLOCH
the first Chern
class cl(&)
337
BUNDLES
vanishes.
Let, us introduce
the notation N-l
([uo,
,~Lv-1];Pl~P2)
“’
=
[13)
UjE@. a,ti'j.o.o(P) 1
c
j=o As can be seen from (la),
the gluing laws of the bundle
([(co. “’ .Q-1l;m ([ao. ..’
fllN,Pz)
,aN-1];Pl,P2+1)
where B is the permutation
Let us consider
if
an N-sheeted
covering
([UO,
4.
([a07
=
ran-~l;m
+
.aA-l]:pl,p2)
(14)
:
N from the relation
= {rU1+
(1:i)
l/N.
(l(i)
permutation.
Hence from (14) and (16) we
over T2 is defined by the trivial gluing functions
l/N,p2)
g
(Lao,
”
([a07
.~N-I]:P~,P~)
.
(17)
. raN-l];PlrP2
vanishes.
(g*(EO))
‘..
({NP~)IN,P~).
(15) implies that crN IS the identity
([ao. .
~1
”
9 : T2 4 Tz given by the formula
see that the induced vector bundle g*Ee
Hence
([am(o), ‘.. >%(,V~1)l;Pl,P2) 1
{r/j’)
dm,~2)
Formula
”
which is defined modulo
cr(j) = j’
Ee have the form
+
1)
Since cl (g*(Ee))
.
= Nci(&)
>a,V-l];pl.p2).
[23], we have cl(&)
= 0.
•I
Remarks (1) The magneto-Bloch
different
bundle
the sublattice form
of A generated
where
A by A’ and K by K’ we obtain
E and E’ are different.
in [9; lo] (we denote
Moreover,
it by E’)
is rather
E and E’ is as follows. Consider al and Nap. Then r is represented in the between
by the elements
r = A’ + K’ , Replacing
considered
E. The relationship
from the bundle
K’ = K + (0.1,
, N - 1).
(13)
E’ as above. If n # A’. the bundles E’ is always isomorphic to a t,rivial one
the bundle
the bundle
[241’ (2) Although
the bundle E’ is trivial, we can obviously decompose it into a direct For example! let 77 = l/3 and let H he the tightsum of nontrivial vector bundles. binding Hamiltonian H = C cIcp exp idxP (the summation is taken over all the nearest,neighbour sites); the phase factor 0x,, is defined on a link and represents the magnetic field ~1, i.e., c
o+
plaquette
= 27q
and
HA,, = -0,x
338
V.A. GEYLER
The spectrum of H consists of three isolated magnetic subbands and each subband Bj defines a subbundle Ei of the magneto-Bloch bundle E’. It may be shown by the straightforward calculation that the Chern numbers cl(Ei) of the corresponding subbundles are as follows: cl (E;) = cl (E;) = 1, cl (Ei) = -2 (see also numerical calculations in [9]).
Acknowledgements I am grateful to V. A. Margulis and I. Yu. Popov for useful remarks. The work is partially supported by RFFR and the Ministry of Higher Education of Russian Federation. REFERENCES [l] Novikov S.P.: Sov. Math. Dokl. 23 (1981), 298. [2] von Klitzing K., Dorda G. and Pepper M.: Phys. Rev. LeU. 45 (1980), 494. [3] Thouless D.J., Kohmoto M., Nightingale M.P. and den Nijs M.: Phys. Rev. Lett. 49 (1982), 405. [4] Avron J.E., Seiler R. and Simon B.: Phys. Rev. Lett. 51 (1983), 51. [5] Thouless D.J.: J. Math. Phys. 35 (1994), 5362. [6] [7] [8] [9] [lo] [ll] [12] [13] [14] [15] [16] [17] [18] [19] [20]
Bellissard J., van Elst A. and Schulz-Baldes H.: J. Math. Phys. 35 (1994), 5373. Lyskova A.S.: Theor. Math. Phys. (USSR) 65 (1986), 1218. Dana I., Avron Y. and Zak J.: J. Phys. Cl8 (1985), L679. Kohmoto M.: Phys. Rev. B39 (1989), 11943. Hatsugai Y. and Kohmoto M.: Phys. Rev. B42 (1990), 8282. Bellissard J., Kreft C. and Seiler R.: J. Phys. Math. Gen. A24 (1991), 2329. Barelli A. and Fleckinger R.: Phys. Rev. B46 (1992), 11559. Hatsugai Y., Kohmoto M. and Wu Y.-S.: Phys. Rev. Lett. 73 (1994), 1134. Geyler V.A. and Popov I.Yu.: Zeikchr. Phys. B93 (1994), 437. Geyler V.A. and Popov I.Yu.: Zeitschr. Phys. B98 (1995), 473. Zak J.: Phys. Rev. 134 (1964), A1602. Geyler V.A. and Popov I.Yu.: JETP Lett. 63 (1996), 381. Geyler V.A.: St. Petersburg Math. J. 3 (1992), 489. Geyler V.A. and Popov I.Yu.: Phys. Lett. A201 (1995), 359. Mackey G.W.: UnitanJ Group Representations in Physics, Probability, and Number Theory, Benjamin, Boston 1978. [21] Boon M.H.: J. Math. Phys. 13 (1972), 1268. [22] Maurin K.: General Eigenfunction Expansions and Unitary Representations of Topological Groups, PWN, Warszawa 1968. [23] Bott R. and Wu L.W.: Differential Forms in Algebraic Topology, Springer, Berlin 1982. [24] Geyler V.A. and Popov I.Yu.: paper submitted to J. Phys. A.