Magnetic topological insulator explained
In physics, magnetic topological insulators are three dimensional magnetic materials with a non-trivial topological index protected by a symmetry other than time-reversal.[1] [2] [3] [4] This type of material conducts electricity on its outer surface, but its volume behaves like an insulator.[5]
In contrast with a non-magnetic topological insulator, a magnetic topological insulator can have naturally gapped surface states as long as the quantizing symmetry is broken at the surface. These gapped surfaces exhibit a topologically protected half-quantized surface anomalous Hall conductivity (
) perpendicular to the surface. The sign of the half-quantized surface anomalous Hall conductivity depends on the specific surface termination.
[6] Theory
Axion coupling
The
classification of a 3D crystalline topological insulator can be understood in terms of the axion coupling
. A scalar quantity that is determined from the ground state wavefunction
[7] \theta=-
\int\rmd3k\epsilon\alphaTr[l{A}\alpha\partial\betal{A}\gamma-i
l{A}\alphal{A}\betal{A}\gamma]
.
where
is a shorthand notation for the
Berry connection matrix
(k)=\langleunk|
|umk\rangle
,
where
is the cell-periodic part of the ground state
Bloch wavefunction.
The topological nature of the axion coupling is evident if one considers gauge transformations. In this condensed matter setting a gauge transformation is a unitary transformation between states at the same
point
|\tilde{\psi}nk\rangle=Umn(k)|\psink\rangle
.
Now a gauge transformation will cause
,
. Since a gauge choice is arbitrary, this property tells us that
is only well defined in an interval of length
e.g.
.
The final ingredient we need to acquire a
classification based on the axion coupling comes from observing how crystalline symmetries act on
.
- Fractional lattice translations
, n-fold rotations
:
.
, inversion
:
.The consequence is that if time-reversal or inversion are symmetries of the crystal we need to have
and that can only be true if
(trivial),
(non-trivial) (note that
and
are identified) giving us a
classification. Furthermore, we can combine inversion or time-reversal with other symmetries that do not affect
to acquire new symmetries that quantize
. For example, mirror symmetry can always be expressed as
giving rise to crystalline topological insulators,
[8] while the first intrinsic magnetic topological insulator MnBi
Te
[9] [10] has the quantizing symmetry
.
Surface anomalous hall conductivity
So far we have discussed the mathematical properties of the axion coupling. Physically, a non-trivial axion coupling (
) will result in a half-quantized surface anomalous Hall conductivity (
) if the surface states are gapped. To see this, note that in general
has two contribution. One comes from the axion coupling
, a quantity that is determined from bulk considerations as we have seen, while the other is the
Berry phase
of the surface states at the
Fermi level and therefore depends on the surface. In summary for a given surface termination the perpendicular component of the surface anomalous Hall conductivity to the surface will be
.
The expression for
is defined
because a surface property (
) can be determined from a bulk property (
) up to a quantum. To see this, consider a block of a material with some initial
which we wrap with a 2D quantum anomalous Hall insulator with
Chern index
. As long as we do this without closing the surface gap, we are able to increase
by
without altering the bulk, and therefore without altering the axion coupling
.
One of the most dramatic effects occurs when
and time-reversal symmetry is present, i.e. non-magnetic topological insulator. Since
| surf |
\boldsymbol{\sigma} | |
| AHC |
is a
pseudovector on the surface of the crystal, it must respect the surface symmetries, and
is one of them, but
| surf |
T\boldsymbol{\sigma} | |
| AHC |
=-
| surf |
\boldsymbol{\sigma} | |
| AHC |
resulting in
| surf |
\boldsymbol{\sigma} | |
| AHC |
=0
. This forces
on
every surface resulting in a Dirac cone (or more generally an odd number of Dirac cones) on
every surface and therefore making the boundary of the material conducting.
On the other hand, if time-reversal symmetry is absent, other symmetries can quantize
and but not force
| surf |
\boldsymbol{\sigma} | |
| AHC |
to vanish. The most extreme case is the case of inversion symmetry (I). Inversion is never a surface symmetry and therefore a non-zero
| surf |
\boldsymbol{\sigma} | |
| AHC |
is valid. In the case that a surface is gapped, we have
which results in a half-quantized surface AHC
.
A half quantized surface Hall conductivity and a related treatment is also valid to understand topological insulators in magnetic field [11] giving an effective axion description of the electrodynamics of these materials.[12] This term leads to several interesting predictions including a quantized magnetoelectric effect.[13] Evidence for this effect has recently been given in THz spectroscopy experiments performed at the Johns Hopkins University.[14]
Experimental realizations
Magnetic topological insulators have proven difficult to create experimentally. In 2023 it was estimated that a magnetic topological insulator might be developed in 15 years' time.[15]
A compound made from manganese, bismuth, and tellurium (MnBi2Te4) has been predicted to be a magnetic topological insulator. In 2024, scientists at the University of Chicago used MnBi2Te4 to develop a form of optical memory which is switched using lasers. This memory storage device could store data more quickly and efficiently, including in quantum computing.[16]
Notes and References
- Quantum corrections crossover and ferromagnetism in magnetic topological insulators . Bao . Lihong . Wang . Weiyi . 2013 . Scientific Reports . 3 . 2391 . en-US . 10.1038/srep02391 . 3739003 . 23928713 . Meyer . Nicholas . Liu . Yanwen . Zhang . Cheng . Wang . Kai . Ai . Ping . Xiu . Faxian. 2013NatSR...3E2391B .
- Web site: 'Magnetic topological insulator' makes its own magnetic field . phys.org . . en-us . 2018-12-17.
- Xu. Su-Yang. Neupane. Madhab . etal . 2012. Hedgehog spin texture and Berry's phase tuning in a Magnetic Topological Insulator. Nature Physics. en. 8. 8. 616–622. 10.1038/nphys2351. 1745-2481. 1212.3382. 2012NatPh...8..616X. 56473067.
- Hasan. M. Z.. Kane. C. L.. 2010-11-08. Colloquium: Topological insulators. Reviews of Modern Physics. 82. 4. 3045–3067. 10.1103/RevModPhys.82.3045. 2010RvMP...82.3045H. 1002.3895. 16066223.
- Web site: 2024-08-14 . MnBi2Te4 Unveiled: A Breakthrough in Quantum and Optical Memory Technology . 2024-08-18 . SciTechDaily . en-US.
- Varnava. Nicodemos. Vanderbilt. David. 2018-12-13. Surfaces of axion insulators. Physical Review B. 98. 24. 245117. 10.1103/PhysRevB.98.245117. 1809.02853. 2018PhRvB..98x5117V. 119433928.
- Qi . Xiao-Liang . Hughes . Taylor L. . Zhang . Shou-Cheng . Topological field theory of time-reversal invariant insulators . Physical Review B . 24 November 2008 . 78 . 19 . 195424 . 10.1103/PhysRevB.78.195424 . 2008PhRvB..78s5424Q . 0802.3537 . 117659977 .
- Fu . Liang . Topological Crystalline Insulators . Physical Review Letters . 8 March 2011 . 106 . 10 . 106802 . 10.1103/PhysRevLett.106.106802 . 21469822 . 2011PhRvL.106j6802F . 1010.1802 . 14426263 .
- Gong . Yan . etal . Experimental realization of an intrinsic magnetic topological insulator . Chinese Physics Letters . 2019 . 36 . 7 . 076801 . 10.1088/0256-307X/36/7/076801 . 1809.07926. 2019ChPhL..36g6801G . 54224157 .
- Otrokov . Mikhail M. . etal . Prediction and observation of the first antiferromagnetic topological insulator . Nature . 2019 . 576 . 7787 . 416–422 . 10.1038/s41586-019-1840-9 . 31853084 . 1809.07389. 54016736 .
- 58. 18. 1799–1802. Wilczek. Frank. Two applications of axion electrodynamics. Physical Review Letters. 4 May 1987. 10.1103/PhysRevLett.58.1799. 10034541. 1987PhRvL..58.1799W.
- Physical Review B. 78. 19. 195424. Qi . Xiao-Liang. Hughes . Taylor L.. Zhang . Shou-Cheng. Topological field theory of time-reversal invariant insulators. 24 November 2008. 10.1103/PhysRevB.78.195424. 2008PhRvB..78s5424Q . 0802.3537. 117659977.
- 10.1103/Physics.1.36. 1. 36. Franz . Marcel. High-energy physics in a new guise. Physics. 24 November 2008. 2008PhyOJ...1...36F. free.
- Wu. Liang. Salehi. M.. Koirala. N.. Moon. J.. Oh. S.. Armitage. N. P.. 2 December 2016. Quantized Faraday and Kerr rotation and axion electrodynamics of a 3D topological insulator. Science. en. 354. 6316. 1124–1127. 10.1126/science.aaf5541. 0036-8075. 27934759. 1603.04317. 2016Sci...354.1124W. 25311729.
- Web site: Anirban . Ankita . 15 years of topological insulators . 2024-08-18 . Nature . en.
- Web site: 2024-08-14 . MnBi2Te4 Unveiled: A Breakthrough in Quantum and Optical Memory Technology . 2024-08-18 . SciTechDaily . en-US.