Post on 29-Jun-2020
Topological order in
quantum matterJawaharlal Nehru University, Delhi
Subir SachdevNovember 20, 2017
HARVARD
Talk online: sachdev.physics.harvard.edu
1. Classical XY model in 2 and 3 dimensions
2. Topological order in the classical XY model in 3 dimensions
3. Topological order in the quantum XY model in 2+1 dimensions
4. Topological order in the Hubbard model
1. Classical XY model in 2 and 3 dimensions
2. Topological order in the classical XY model in 3 dimensions
3. Topological order in the quantum XY model in 2+1 dimensions
4. Topological order in the Hubbard model
ZXY =Y
i
Z 2⇡
0
d✓i
2⇡exp (�H/T )
H = �J
X
hiji
cos(✓i � ✓j)
Describes non-zero T phase transitions of superfluids,
magnets with `easy-plane’ spins,…..
T
In spatial dimension d = 3, in the low T phase, the symmetry
✓i ! ✓i + c is “spontaneously broken”. There is (o↵-diagonal)
long-range order (LRO) characterized by ( i ⌘ ei✓i)
lim|ri�rj |!1
⌦ i
⇤j
↵= | 0|2 6= 0 .
We break the symmetry by choosing an overall phase so that
h ii = 0 6= 0
Tc
h ii = 0 6= 0 h ii = 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
SRO
⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
T
In spatial dimension d = 3, in the low T phase, the symmetry
✓i ! ✓i + c is “spontaneously broken”. There is (o↵-diagonal)
long-range order (LRO) characterized by ( i ⌘ ei✓i)
lim|ri�rj |!1
⌦ i
⇤j
↵= | 0|2 6= 0 .
We break the symmetry by choosing an overall phase so that
h ii = 0 6= 0
Tc
h ii = 0 6= 0 h ii = 0
LROSRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Wilson-Fishercritical theory
(Nobel Prize, 1982)
⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
In spatial dimension d = 2, the symmetry ✓i ! ✓i + c is
preserved at all non-zero T . There is no LRO, and
h ii = 0 for all T > 0.
Nevertheless, there is a phase transition at T = TKT ,
where the nature of the correlations changes
lim|ri�rj |!1
⌦ i
⇤j
↵⇠
8<
:
|ri � rj |�↵, for T < TKT , (QLRO)
exp(�|ri � rj |/⇠), for T > TKT , (SRO)
.
The low T phase also has topological order associated
with the suppression of vortices.
T TKT
QLROTopological order SRO
Figure 3: To the left a single vortex configuration, and to the right a vortex-
antivortex pair. The angle ✓ is shown as the direction of the arrows, and the cores of
the vortex and antivortex are shaded in red and blue respectively. Note how the arrows
rotate as you follow a contour around a vortex. (Figure by Thomas Kvorning.)
by the Hamiltonian,
HXY = �JX
hiji
cos(✓i � ✓j) (3)
where hiji again denotes nearest neighbours and the angular variables, 0 ✓i < 2⇡ can denote either the direction of an XY-spin or the phase of asuperfluid. We shall discuss this model in some detail below.
Although the GL and BCS theories were very successful in describing manyaspects of superconductors, as were the theories developed by Lev Landau(Nobel Prize 1962), Nikolay Bogoliubov, Richard Feynman, Lars Onsager andothers for the Bose superfluids, not everything fit neatly into the Landauparadigm of order parameters and spontaneous symmetry breaking. Problemsoccur in low-dimensional systems, such as thin films or thin wires. Here, thethermal fluctuations become much more important and often prevent orderingeven at zero temperature [39]. The exact result of interest here is due toWegner, who showed that there cannot be any spontaneous symmetry breakingin the XY-model at finite temperature [53].
So far we have discussed phenomena that can be understood using classicalconcepts, at least as long as one accepts that superfluids are characterisedby a complex phase. There are however important macroscopic phenomenathat cannot be explained without using quantum mechanics. To find theground state of a quantum many-body problem is usually very difficult, butthere are some important examples where solutions to simplified problems givedeep physical insights. Electromagnetic response in crystalline materials is an
6
Vortices suppressed
Vortices proliferate
Kosterlitz-Thouless theory in d=2
In spatial dimension d = 2, the symmetry ✓i ! ✓i + c is
preserved at all non-zero T . There is no LRO, and
h ii = 0 for all T > 0.
Nevertheless, there is a phase transition at T = TKT ,
where the nature of the correlations changes
lim|ri�rj |!1
⌦ i
⇤j
↵⇠
8<
:
|ri � rj |�↵, for T < TKT , (QLRO)
exp(�|ri � rj |/⇠), for T > TKT , (SRO)
.
The low T phase also has topological order associated
with the suppression of vortices.
KT theory(Nobel Prize, 2016)
1. Classical XY model in 2 and 3 dimensions
2. Topological order in the classical XY model in 3 dimensions
3. Topological order in the quantum XY model in 2+1 dimensions
4. Topological order in the Hubbard model
J Jc
h ii = 0 6= 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Can we modify the XY model Hamiltonian to obtain a phase with
“topological order” in d=3 ?
SRO
h ii = 0⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
J Jc
h ii = 0 6= 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Kh ii = 0
SRONo topological
order
SROTopological
order
h ii = 0⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
SRONo topological
order
J Jc
h ii = 0 6= 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
K
SRONo topological
order
h ii = 0 SROTopological
order
h ii = 0
⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
⌦ i
⇤j
↵⇠ exp(�|ri � rj |/⇠)
Only even (±4⇡, ±8⇡ . . .)vortices proliferate
All (±2⇡, ±4⇡ . . .)vortices proliferate
Add terms which suppress single but not double vortices…..
eZXY =Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
cos(✓i � ✓j)
+X
ijk`
Jijk` cos(✓i + ✓j � ✓k � ✓`) + . . . . . .
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
�
�
�
� KS. Sachdev and N. Read, Int. J. Mod.Phys. B, 5, 219 (1991).R. Jalabert and S. Sachdev, PRB 44,686 (1991).S. Sachdev and M. Vojta, J. Phys. Soc.Jpn 69 Supp. B, 1 (2000).P. E. Lammert, D. S. Rokhsar, andJ. Toner, PRL 70, 1650 (1993).T. Senthil and M. P. A. Fisher, PRB62, 7850 (2000).R. D. Sedgewick, D. J. Scalapino, R. L. Sugar,PRB 65, 54508 (2002).K. Park and S. Sachdev, PRB 65, 220405(2002).
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
• At small K, we can explicitly sum over �ij , order-by-order in K, and the theory reduces to an ordinaryXY model with multi-site interactions. The resultinge↵ective action of the XY model is periodic in ✓i !✓i + 2⇡ (for any site i), and preserves the symmetry✓i ! ✓i + c (for all sites i).
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
• The theory has a Z2 gauge invariance: we can change
✓i ! ✓i + ⇡(1� ⌘i)
�ij ! ⌘i�ij⌘j ,
with ⌘i = ±1, and the energy remains unchanged.
• The XY order parameter i = ei✓i is gauge invari-
ant, as are all physical observables. So this is an
XY model with a modified Hamiltonian, and no ad-
ditional degrees of freedom have been introduced.<latexit 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• A single (odd) 2⇡ vortex in ✓i hasQ(ij)2⇤ cos [(✓i � ✓j)/2] < 0.
• So for J > 0, such a vortex will preferQ
(ij)2⇤ �ij = �1,i.e. a 2⇡ vortex has Z2 flux = �1 in its core.
• So a large K > 0 will suppress (odd) 2⇡ vortices.
• There is no analogous suppression of (even) 4⇡ vortices.
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
J Jc
h ii = 0 6= 0
h ii = 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Kh ii = 0
SRONo topological
order
SROTopological order
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
Only even (±4⇡, ±8⇡ . . .)vortices proliferate
All (±2⇡, ±4⇡ . . .)vortices proliferate
J Jc
h ii = 0 6= 0
h ii = 0
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Kh ii = 0
Deconfined phase of Z2 gauge theory.Z2 flux is expelled
Confined phase of Z2 gauge theory.Z2 flux flucuates
Higgs phase of Z2 gauge theory
eZXY =X
{�ij}=±1
Y
i
Z 2⇡
0
d✓i
2⇡exp
⇣� eH/T
⌘
eH = �J
X
hiji
�ij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�ij
1. Classical XY model in 2 and 3 dimensions
2. Topological order in the classical XY model in 3 dimensions
3. Topological order in the quantum XY model in 2+1 dimensions
4. Topological order in the Hubbard model
K �z
�z
�z
�z
A quantum Hamiltonian in 2+1 dimensionseH = �J
X
hiji
�zij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�zij
+U
X
i
(ni)2 � g
X
hiji
�xij ; [✓i, nj ] = i�ij
-1
• In the topological phase,the suppressed Z2 fluxesof -1 become well-definedgapped quasiparticleexcitations (‘visons’) abovethe ground state.
A quantum Hamiltonian in 2+1 dimensionseH = �J
X
hiji
�zij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�zij
+U
X
i
(ni)2 � g
X
hiji
�xij ; [✓i, nj ] = i�ij
• In the topological phase, on atorus, inserting the Z2 flux of-1 into one of the cycles of thetorus leads to an orthogonal statewhose energy cost vanishes ex-ponentially in the size of thetorus: there are 4 degenerateground states on a large torus.
A quantum Hamiltonian in 2+1 dimensionseH = �J
X
hiji
�zij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�zij
+U
X
i
(ni)2 � g
X
hiji
�xij ; [✓i, nj ] = i�ij
J Jc
h ii = 0 6= 0
h ii = 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Kh ii = 0
SRONo topological
order
SROTopological order
eH = �J
X
hiji
�zij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�zij
+U
X
i
(ni)2 � g
X
hiji
�xij ; [✓i, nj ] = i�ij
A quantum Hamiltonian in 2+1 dimensions
Only even (±4⇡, ±8⇡ . . .)vortices proliferate
All (±2⇡, ±4⇡ . . .)vortices proliferate
J Jc
h ii = 0 6= 0
h ii = 0
LRO
Figure 1: Schematic picture of ferro- and antiferromagnets. The chequerboard pat-
tern in the antiferromagnet is called a Néel state.
the role of symmetry in physics. Using new experimental techniques, hiddenpatterns of symmetry were discovered. For example, there are magnetic mate-rials where the moments form a chequerboard pattern where the neighbouringmoments are anti-parallel, see Fig. 1. In spite of not having any net magneti-zation, such antiferromagnets are nevertheless ordered states, and the patternof microscopic spins can be revealed by neutron scattering. The antiferro-magnetic order can again be understood in terms of the associated symmetrybreaking.
In a mathematical description of ferromagnetism, the important variable isthe magnetization, ~mi = µ ~Si, where µ is the magnetic moment and ~Si the spinon site i. In an ordered phase, the average value of all the spins is different fromzero, h~mii 6= 0. The magnetization is an example of an order parameter, whichis a quantity that has a non-zero average in the ordered phase. In a crystal itis natural to think of the sites as just the atomic positions, but more generallyone can define “block spins” which are averages of spins on many neighbouringatoms. The “renormalization group” techniques used to understand the theoryof such aggregate spins are crucial for understanding phase transitions, andresulted in a Nobel Prize for Ken Wilson in 1982.
It is instructive to consider a simple model, introduced by Heisenberg, thatdescribes both ferro- and antiferromagnets. The Hamiltonian is
HF = �JX
hiji
~Si · ~Sj � µX
i
~B · ~Si (1)
2
Kh ii = 0
SRONo topological
order
SROTopological order
eH = �J
X
hiji
�zij cos [(✓i � ✓j)/2]�K
X
⇤
Y
(ij)2⇤�zij
+U
X
i
(ni)2 � g
X
hiji
�xij ; [✓i, nj ] = i�ij
A quantum Hamiltonian in 2+1 dimensionsThe topological order is the same
as that of the ‘toric code’,or of the U(1)⇥U(1) Chern-Simons theory
Lcs =1
⇡✏µ⌫�aµ@⌫b�
Only even (±4⇡, ±8⇡ . . .)vortices proliferate
All (±2⇡, ±4⇡ . . .)vortices proliferate
1. Classical XY model in 2 and 3 dimensions
2. Topological order in the classical XY model in 3 dimensions
3. Topological order in the quantum XY model in 2+1 dimensions
4. Topological order in the Hubbard model
H = �X
i<j
tijc†i↵cj↵ + U
X
i
✓ni" �
1
2
◆✓ni# �
1
2
◆� µ
X
i
c†i↵ci↵
tij ! “hopping”. U ! local repulsion, µ ! chemical potential
Spin index ↵ =", #
ni↵ = c†i↵ci↵
c†i↵cj� + cj�c
†i↵ = �ij�↵�
ci↵cj� + cj�ci↵ = 0
The Hubbard Model
Will study on the square lattice
Metal with “large” Fermi surface
U/t
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
Fermi surface+antiferromagnetism
Mean-field theory with an antiferromagnetic
order parameter ~�i = (�1)ix+iyD~Si
E
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface
and topological order?
We can (exactly) transform the Hubbard model to the “spin-fermion”
model: electrons ci↵ on the square lattice with dispersion
Hc = �
X
i,⇢
t⇢⇣c†i,↵ci+v⇢,↵
+ c†i+v⇢,↵ci,↵
⌘� µ
X
i
c†i,↵ci,↵ +Hint
are coupled to an antiferromagnetic order parameter �`(i),
` = x, y, z
Hint = ��X
i
⌘i�`(i)c†i,↵�
`↵�ci,� + V�
where ⌘i = ±1 on the two sublattices. (For suitable V�, integrating
out the � yields back the Hubbard model).
When �`(i) = (non-zero constant) independent of i, we have long-
range AF order, which transforms the Fermi surfaces from large to
small.
Increasing SDW order
We can (exactly) transform the Hubbard model to the “spin-fermion”
model: electrons ci↵ on the square lattice with dispersion
Hc = �
X
i,⇢
t⇢⇣c†i,↵ci+v⇢,↵
+ c†i+v⇢,↵ci,↵
⌘� µ
X
i
c†i,↵ci,↵ +Hint
are coupled to an antiferromagnetic order parameter �`(i),
` = x, y, z
Hint = ��X
i
⌘i�`(i)c†i,↵�
`↵�ci,� + V�
where ⌘i = ±1 on the two sublattices. (For suitable V�, integrating
out the � yields back the Hubbard model).
When �`(i) = (non-zero constant) independent of i, we have long-
range AF order, which transforms the Fermi surfaces from large to
small.
Increasing SDW order
Increasing SDW order
For fluctuating antiferromagnetism, we transform to a
rotating reference frame using the SU(2) rotation Ri
✓ci"ci#
◆= Ri
✓ i,+
i,�
◆,
in terms of fermionic “chargons” s and a Higgs field Ha(i)
�`�
`(i) = Ri �
aH
a(i)R
†i
The Higgs field is the AFM order in the rotating reference frame.
Note that this representation is ambiguous up to a
SU(2) gauge transformation, Vi
✓ i,+
i,�
◆! Vi
✓ i,+
i,�
◆
Ri ! RiV†i
�aH
a(i) ! Vi �
bH
b(i)V
†i .
S. Sachdev, M. A. Metlitski, Y. Qi, and C. Xu, PRB 80, 155129 (2009)
For fluctuating antiferromagnetism, we transform to a
rotating reference frame using the SU(2) rotation Ri
✓ci"ci#
◆= Ri
✓ i,+
i,�
◆,
in terms of fermionic “chargons” s and a Higgs field Ha(i)
�`�
`(i) = Ri �
aH
a(i)R
†i
The Higgs field is the AFM order in the rotating reference frame.
Note that this representation is ambiguous up to a
SU(2) gauge transformation, Vi
✓ i,+
i,�
◆! Vi
✓ i,+
i,�
◆
Ri ! RiV†i
�aH
a(i) ! Vi �
bH
b(i)V
†i .
S. Sachdev, M. A. Metlitski, Y. Qi, and C. Xu, PRB 80, 155129 (2009)
The simplest e↵ective Hamiltonian for the fermionic chargons is
the same as that for the electrons, with the AFM order replaced
by the Higgs field.
H = �
X
i,⇢
t⇢
⇣ †i,s i+v⇢,s
+ †i+v⇢,s
i,s
⌘� µ
X
i
†i,s i,s
+Hint
Hint = ��
X
i
⌘iHa(i)
†i,s�a
ss0 i,s0 + VH
IF we can transform to a rotating reference frame in whichHa(i) =
a constant independent of i and time, THEN the fermions in the
presence of fluctuating AFM will inherit the small Fermi surfaces
of the electrons in the presence of static AFM.
Fluctuating antiferromagnetism
S. Sachdev, M. A. Metlitski, Y. Qi, and C. Xu, PRB 80, 155129 (2009)
The simplest e↵ective Hamiltonian for the fermionic chargons is
the same as that for the electrons, with the AFM order replaced
by the Higgs field.
H = �
X
i,⇢
t⇢
⇣ †i,s i+v⇢,s
+ †i+v⇢,s
i,s
⌘� µ
X
i
†i,s i,s
+Hint
Hint = ��
X
i
⌘iHa(i)
†i,s�a
ss0 i,s0 + VH
IF we can transform to a rotating reference frame in whichHa(i) =
a constant independent of i and time, THEN the fermions in the
presence of fluctuating AFM will inherit the small Fermi surfaces
of the electrons in the presence of static AFM.
Fluctuating antiferromagnetism
S. Sachdev, M. A. Metlitski, Y. Qi, and C. Xu, PRB 80, 155129 (2009)
Fluctuating antiferromagnetismWe cannot always find a single-valued SU(2) rotation Ri to make
the Higgs field Ha(i) a constant !
n-fold vortex in
AFM order
(assume easy-plane AFM for
simplicity)
A.V. Chubukov, T. Senthil and S. Sachdev, PRL 72, 2089 (1994);
S. Sachdev, E. Berg, S. Chatterjee, and Y. Schattner, PRB 94, 115147 (2016)
Fluctuating antiferromagnetismWe cannot always find a single-valued SU(2) rotation Ri to make
the Higgs field Ha(i) a constant !
n-fold vortex in
AFM order
R
(�1)nR
(assume easy-plane AFM for
simplicity)
A.V. Chubukov, T. Senthil and S. Sachdev, PRL 72, 2089 (1994);
S. Sachdev, E. Berg, S. Chatterjee, and Y. Schattner, PRB 94, 115147 (2016)
We cannot always find a single-valued SU(2) rotation Ri to make
the Higgs field Ha(i) a constant !
n-fold vortex in
AFM order
R
(�1)nR
Topological order
Vortices with n odd must be suppressed: such a metal with
“fluctuating antiferromagnetism” has BULK Z2
TOPOLOGICAL ORDER and fermions which inherit the
small Fermi surfaces of the antiferromagnetic metal.
(assume easy-plane AFM for
simplicity)
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface
and topological order?
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface;
Higgs phase of a SU(2) gauge theorywith Z2 or U(1) topological order (with suppressed Z2 vortices and
hedgehogs respectively)
S. Sachdev and D. Chowdhury, Prog. Theor. Exp. Phys. 12C102 (2016)
Topological order in the pseudogap metal
Mathias S. Scheurer,1 Shubhayu Chatterjee,1 Wei Wu,2, 3 MichelFerrero,2, 3 Antoine Georges,2, 4, 3, 5 and Subir Sachdev1, 6, 7
1Department of Physics, Harvard University, Cambridge MA 02138, USA2Centre de Physique Theorique, Ecole Polytechnique,
CNRS, Universite Paris-Saclay, 91128 Palaiseau, France3College de France, 11 place Marcelin Berthelot, 75005 Paris, France
4Center for Computational Quantum Physics, Flatiron Institute, 162 Fifth Avenue, New York, NY 10010, USA5DQMP, Universite de Geneve, 24 quai Ernest Ansermet, CH-1211 Geneve, Suisse6Perimeter Institute for Theoretical Physics, Waterloo, Ontario, Canada N2L 2Y5
7Department of Physics, Stanford University, Stanford CA 94305, USA(Dated: November 11, 2017)
We compute the electronic Green’s function of the topologically ordered Higgs phase of a SU(2)gauge theory of fluctuating antiferromagnetism on the square lattice. The results are comparedwith cluster extensions of dynamical mean field theory, and quantum Monte Carlo calculations, onthe pseudogap phase of the strongly interacting hole-doped Hubbard model. Good agreement isfound in the momentum, frequency, hopping, and doping dependencies of the spectral function andelectronic self-energy. We show that (approximate) lines of zeros of the zero-frequency electronicGreen’s function are signs of the underlying topological order of the gauge theory, and describehow these lines of zeros appear in our theory of the Hubbard model. We also derive a modified,non-perturbative version of the Luttinger theorem that holds in the Higgs phase.
The pseudogap metal is a novel state of electronic mat-ter found in the hole-doped, cuprate high temperaturesuperconductors [1]. It exhibits clear evidence of electri-cal transport with the temperature and frequency depen-dence of a conventional metal obeying Fermi liquid the-ory [2, 3]. However, a long-standing mystery in the studyof the cuprates is that photoemission experiments do notshow the ‘large’ Fermi surface that is expected from theLuttinger theorem of Fermi liquid theory [4]. (Brokensquare lattice translational symmetry can allow ‘small’Fermi surfaces, but there is no sign of it over a widerange of temperature and doping over which the pseudo-gap state is present [1, 5], and we will not discuss stateswith broken symmetry here.) There are non-perturbativearguments [6–9] that deviations from the Luttinger vol-ume are only possible in quantum states with topologicalorder. But independent evidence for the presence of topo-logical order in the pseudogap has so far been lacking.
In this paper we employ a SU(2) gauge theory of fluc-tuating antiferromagnetism (AF) in metals [10, 11] todescribe the pseudogap metal. Such a gauge theory de-scribes fluctuations in the orientation of the AF order,while preserving a local, non-zero magnitude. An alter-native, semiclassical treatment of fluctuations of the AForder parameter has been used to describe the electron-doped cuprates [12], but this remains valid at low tem-peratures (T ) only if the AF correlation length ⇠AF di-verges as T ! 0. We are interested in the case where ⇠AF
remains finite at T = 0, and then a gauge theory formu-lation is required to keep proper track of the fermionicdegrees of freedom in the background of the fluctuatingAF order. Such a gauge theory can formally be derivedfrom a lattice Hubbard model, as we will outline in thenext section. The SU(2) gauge theory yields a pseudogapmetal with only ‘small’ Fermi surfaces when the gauge
group is ‘Higgsed’ down to a smaller group. We will de-scribe examples of Higgsing down to U(1) and Z2, andthese will yield metallic states with U(1) and Z2 topolog-ical order. See Appendix A for a definition of topologicalorder in gapless systems; for the U(1) case we primarilyconsider, the topological order is associated [13, 14] withthe suppression of ‘hedgehog’ defects in the spacetimeconfiguration of the fluctuating AF order.
We will present a mean-field computation of the elec-tronic Green’s function across the entire Brillouin zonein the U(1) Higgs phase of the SU(2) gauge theory. Suchresults allow for a direct comparison with numerical com-putations on the Hubbard model. One of our main resultswill be that for a reasonable range of parameters in theSU(2) gauge theory, both the real and imaginary parts ofthe electron Green’s function of the gauge theory withtopological order closely resemble those obtained fromdynamical cluster approximation (DCA), a cluster ex-tension of dynamical mean field theory (DMFT). WhileDCA allows us to study the regime of strong correlationsdown to low temperature, it has limited momentum-space resolution. For this reason, we have also performeddeterminant quantumMonte Carlo (DQMC) calculationsand find self-energies that, in the numerically accessibletemperature range, agree well with the gauge theory com-putations. Additional results on the comparison betweenthe SU(2) gauge theory and the DCA and DQMC com-putations, as a function of doping and second-neighborhopping, appear in a companion paper [15].
In several discussions in the literature [16–22], viola-tions of the Luttinger theorem have been linked to thepresence of lines of zeros (in two spatial dimensions) inthe electron Green’s function on a “Luttinger surface”.The conventional perturbative proof of the Luttinger the-orem yields an additional contribution to the volume en-
DRAFT
Topological order in the pseudogap metalMathias S. Scheurera,*, Shubhayu Chatterjeea, Wei Wub,c, Michel Ferrerob,c, Antoine Georgesb,c,d,e, and Subir Sachdeva,f,g
aDepartment of Physics, Harvard University, Cambridge MA 02138, USA; bCentre de Physique Théorique, École Polytechnique, CNRS, Université Paris-Saclay, 91128Palaiseau, France; cCollège de France, 11 place Marcelin Berthelot, 75005 Paris, France; dCenter for Computational Quantum Physics, Flatiron Institute, 162 Fifth Avenue,New York, NY 10010, USA; eDQMP, Université de Genève, 24 quai Ernest Ansermet, CH-1211 Genève, Suisse; fPerimeter Institute for Theoretical Physics, Waterloo, Ontario,Canada N2L 2Y5; gDepartment of Physics, Stanford University, Stanford CA 94305, USA
This manuscript was compiled on November 11, 2017
We compute the electronic Green’s function of the topologically or-dered Higgs phase of a SU(2) gauge theory of fluctuating antiferro-magnetism on the square lattice. The results are compared with clus-ter extensions of dynamical mean field theory, and quantum MonteCarlo calculations, on the pseudogap phase of the strongly interact-ing hole-doped Hubbard model. Good agreement is found in the mo-mentum, frequency, hopping, and doping dependencies of the spec-tral function and electronic self-energy. We show that lines of (ap-proximate) zeros of the zero-frequency electronic Green’s functionare signs of the underlying topological order of the gauge theory,and describe how these lines of zeros appear in our theory of theHubbard model. We also derive a modified, non-perturbative versionof the Luttinger theorem that holds in the Higgs phase.
pseudogap metal | topological order | Hubbard model | DMFT | QMC
The pseudogap metal is a novel state of electronic mat-ter found in the hole-doped, cuprate high temperature
superconductors [1]. It exhibits clear evidence of electricaltransport with the temperature and frequency dependence ofa conventional metal obeying Fermi liquid theory [2, 3]. How-ever, a long-standing mystery in the study of the cuprates isthat photoemission experiments do not show the ‘large’ Fermisurface that is expected from the Luttinger theorem of Fermiliquid theory [4]. (Broken square lattice translational symme-try can allow ‘small’ Fermi surfaces, but there is no sign of itover a wide range of temperature and doping over which thepseudogap state is present [1, 5], and we will not discuss stateswith broken symmetry here.) There are non-perturbative ar-guments [6–9] that deviations from the Luttinger volume areonly possible in quantum states with topological order. Butindependent evidence for the presence of topological order inthe pseudogap has so far been lacking.
In this paper we employ a SU(2) gauge theory of fluctuatingantiferromagnetism (AF) in metals [10, 11] to describe thepseudogap metal. Such a gauge theory describes fluctuationsin the orientation of the AF order, while preserving a local,non-zero magnitude. An alternative, semiclassical treatmentof fluctuations of the AF order parameter has been used todescribe the electron-doped cuprates [12], but this remainsvalid at low temperatures (T ) only if the AF correlation length›AF diverges as T æ 0. We are interested in the case where›AF remains finite at T = 0, and then a gauge theory formula-tion is required to keep proper track of the fermionic degreesof freedom in the background of the fluctuating AF order.Such a gauge theory can formally be derived from a latticeHubbard model, as we will outline in the next section. TheSU(2) gauge theory yields a pseudogap metal with only ‘small’Fermi surfaces when the gauge group is ‘Higgsed’ down to asmaller group. We will describe examples of Higgsing downto U(1) and Z2, and these will yield metallic states with U(1)
and Z2 topological order. See SI Appendix A for a definitionof topological order in gapless systems; for the U(1) case weprimarily consider, the topological order is associated [13, 14]with the suppression of ‘hedgehog’ defects in the spacetimeconfiguration of the fluctuating AF order.
We will present a mean-field computation of the electronicGreen’s function across the entire Brillouin zone in the U(1)Higgs phase of the SU(2) gauge theory. Such results allowfor a direct comparison with numerical computations on theHubbard model. One of our main results will be that for areasonable range of parameters in the SU(2) gauge theory, boththe real and imaginary parts of the electron Green’s function ofthe gauge theory with topological order closely resemble thoseobtained from dynamical cluster approximation (DCA), a clus-ter extension of dynamical mean field theory (DMFT). WhileDCA allows us to study the regime of strong correlations downto low temperature, it has limited momentum-space resolution.For this reason, we have also performed determinant quan-tum Monte Carlo (DQMC) calculations and find self-energiesthat, in the numerically accessible temperature range, agreewell with the gauge theory computations. Additional resultson the comparison between the SU(2) gauge theory and theDCA and DQMC computations, as a function of doping andsecond-neighbor hopping, appear in a companion paper [15].
In several discussions in the literature [16–22], violationsof the Luttinger theorem have been linked to the presenceof lines of zeros (in two spatial dimensions) in the electronGreen’s function on a “Luttinger surface”. The conventionalperturbative proof of the Luttinger theorem yields an addi-tional contribution to the volume enclosed by the Fermi surfacewhen the electron Green’s function has lines of zeros: it was
Significance Statement
The copper oxide based high temperature superconductors dis-play a mysterious ‘pseudogap’ metal phase at temperatures justabove the critical temperature in a regime of low hole density.Extensive experimental and numerical studies have yieldedmuch information on the nature of the electron corrections,but a fundamental theoretical understanding has been lacking.We show that a theory of a metal with topological order andemergent gauge fields can model much of the numerical data.Our study opens up a route to a deeper understanding of thelong-range quantum entanglement in these superconductors,and to the direct detection of the topological characteristics ofthe many-body quantum state.
Author contributions.
The authors declare no conflict of interest.
*To whom correspondence should be addressed. E-mail: mscheurer@g.harvard.edu
www.pnas.org/cgi/doi/10.1073/pnas.XXXXXXXXXX PNAS | November 11, 2017 | vol. XXX | no. XX | 1–7
to appear…..
One loop computation of SU(2) gauge theory higgsed
down to U(1)
Mathias Scheurer
Full Brillouin zone spectra of chargons ( ) and electrons (c)
Shubhayu Chatterjee
Red line indicates the locusof ReG(k,! = 0) = 0
Red line indicates the locusof G(k,! = 0) = 0
One loop computation of SU(2) gauge theory higgsed
down to U(1)
Anti-nodal spectra compared to cluster DMFT
One loop computation of SU(2) gauge theory higgsed
down to U(1)
Lifshitz transition compared to cluster DMFT
One loop computation of SU(2) gauge theory higgsed
down to U(1)
Self energy compared to cluster DMFT
SM
FL
Figure: K. Fujita and J. C. Seamus Davis
YBa2Cu3O6+x
SM
FL
Figure: K. Fujita and J. C. Seamus Davis
YBa2Cu3O6+x
Insulating Antiferromagnet
A conventional metal:
the Fermi liquid with Fermi
surface of size 1+p
M. Plate, J. D. F. Mottershead, I. S. Elfimov, D. C. Peets, Ruixing Liang, D. A. Bonn, W. N. Hardy,
S. Chiuzbaian, M. Falub, M. Shi, L. Patthey, and A. Damascelli, Phys. Rev. Lett. 95, 077001 (2005)
SM
FL
SM
FL
SM
FL
Pseudogap metal
at low pMany indications that this metal behaves like a Fermi liquid, but with
Fermi surface size p and not 1+p.
If present at T=0, a metal with a size p Fermi surface (and
translational symmetry preserved) must have
topological order
T. Senthil, M. Vojta and S. Sachdev, PRB 69, 035111 (2004)
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface;
Higgs phase of a SU(2) gauge theorywith Z2 or U(1) topological order (with suppressed Z2 vortices and
hedgehogs respectively)
S. Sachdev and D. Chowdhury, Prog. Theor. Exp. Phys. 12C102 (2016)
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface;
Higgs phase of a SU(2) gauge theorywith Z2 or U(1) topological order (with suppressed Z2 vortices and
hedgehogs respectively)
n-dopedcuprates
S. Sachdev and D. Chowdhury, Prog. Theor. Exp. Phys. 12C102 (2016)
Metal with “large” Fermi surface
U/t
Fermi surface+antiferromagnetism+topological order
h~�i 6= 0 h~�i = 0
AF Metal with “small” Fermi surface
Increasing SDW order
h~�i = 0
Increasing SDW orderMetal with “small” Fermi surface;
Higgs phase of a SU(2) gauge theorywith Z2 or U(1) topological order (with suppressed Z2 vortices and
hedgehogs respectively)
p-dopedcuprates
S. Sachdev and D. Chowdhury, Prog. Theor. Exp. Phys. 12C102 (2016)
New classes of quantum states with topological order
Can be understood as: (a) defect suppression in states with fluctuating order associated with broken symmetries (b) Higgs phases of emergent gauge fields
A metal with bulk topological order (i.e. long-range quantum entanglement) can explain existing experiments in cuprates, and agrees well with cluster-DMFT
New classes of quantum states with topological order
Can be understood as: (a) defect suppression in states with fluctuating order associated with broken symmetries (b) Higgs phases of emergent gauge fields
A metal with bulk topological order (i.e. long-range quantum entanglement) can explain existing experiments in cuprates, and agrees well with cluster-DMFT
New classes of quantum states with topological order
Can be understood as: (a) defect suppression in states with fluctuating order associated with broken symmetries (b) Higgs phases of emergent gauge fields
A metal with bulk topological order (i.e. long-range quantum entanglement) can explain existing experiments in cuprates, and agrees well with cluster-DMFT