Topological insulator
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A topological insulator is a material whose interior behaves as an
A topological insulator is an insulator for the same reason a "
Since this results from a global property of the topological insulator's band structure, local (symmetry-preserving) perturbations cannot damage this surface state.[6] This is unique to topological insulators: while ordinary insulators can also support conductive surface states, only the surface states of topological insulators have this robustness property.
This leads to a more formal definition of a topological insulator: an insulator which cannot be adiabatically transformed into an ordinary insulator without passing through an intermediate conducting state.[5] In other words, topological insulators and trivial insulators are separate regions in the phase diagram, connected only by conducting phases. In this way, topological insulators provide an example of a state of matter not described by the Landau symmetry-breaking theory that defines ordinary states of matter.[6]
The properties of topological insulators and their surface states are highly dependent on both the dimension of the material and its underlying
The surface states of topological insulators can have exotic properties. For example, in time-reversal symmetric 3D topological insulators, surface states have their spin locked at a right-angle to their momentum (spin-momentum locking). At a given energy the only other available electronic states have different spin, so "U"-turn scattering is strongly suppressed and conduction on the surface is highly metallic.
Despite their origin in quantum mechanical systems, analogues of topological insulators can also be found in classical media. There exist
topological insulators, among others.Prediction
The first models of 3D topological insulators were proposed by B. A. Volkov and O. A. Pankratov in 1985,[12] and subsequently by Pankratov, S. V. Pakhomov, and Volkov in 1987.[13] Gapless 2D Dirac states were shown to exist at the band inversion contact in PbTe/SnTe[12] and HgTe/CdTe[13] heterostructures. Existence of interface Dirac states in HgTe/CdTe was experimentally verified by Laurens W. Molenkamp's group in 2D topological insulators in 2007.[14]
Later sets of theoretical models for the 2D topological insulator (also known as the quantum spin Hall insulators) were proposed by Charles L. Kane and Eugene J. Mele in 2005,[15] and also by B. Andrei Bernevig and Shoucheng Zhang in 2006.[16] The topological invariant was constructed and the importance of the time reversal symmetry was clarified in the work by Kane and Mele.[17] Subsequently, Bernevig, Taylor L. Hughes and Zhang made a theoretical prediction that 2D topological insulator with one-dimensional (1D) helical edge states would be realized in quantum wells (very thin layers) of mercury telluride sandwiched between cadmium telluride.[18] The transport due to 1D helical edge states was indeed observed in the experiments by Molenkamp's group in 2007.[14]
Although the topological classification and the importance of time-reversal symmetry was pointed in the 2000s, all the necessary ingredients and physics of topological insulators were already understood in the works from the 1980s.
In 2007, it was predicted that 3D topological insulators might be found in binary compounds involving bismuth,[19][20][21][22] and in particular "strong topological insulators" exist that cannot be reduced to multiple copies of the quantum spin Hall state.[23]
Experimental realization
2D Topological insulators were first realized in system containing HgTe quantum wells sandwiched between cadmium telluride in 2007.
The first 3D topological insulator to be realized experimentally was
Shortly thereafter symmetry-protected surface states were also observed in pure antimony, bismuth selenide, bismuth telluride and antimony telluride using angle-resolved photoemission spectroscopy (ARPES).[30][31][32][33][34] and bismuth selenide.[34][35] Many semiconductors within the large family of Heusler materials are now believed to exhibit topological surface states.[36][37] In some of these materials, the Fermi level actually falls in either the conduction or valence bands due to naturally-occurring defects, and must be pushed into the bulk gap by doping or gating.[38][39] The surface states of a 3D topological insulator is a new type of two-dimensional electron gas (2DEG) where the electron's spin is locked to its linear momentum.[31]
Fully bulk-insulating or intrinsic 3D topological insulator states exist in Bi-based materials as demonstrated in surface transport measurements.[40] In a new Bi based chalcogenide (Bi1.1Sb0.9Te2S) with slightly Sn - doping, exhibits an intrinsic semiconductor behavior with Fermi energy and Dirac point lie in the bulk gap and the surface states were probed by the charge transport experiments.[41]
It was proposed in 2008 and 2009 that topological insulators are best understood not as surface conductors per se, but as bulk 3D magnetoelectrics with a quantized
In 2012, topological Kondo insulators were identified in samarium hexaboride, which is a bulk insulator at low temperatures.[46][47]
In 2014, it was shown that magnetic components, like the ones in spin-torque computer memory, can be manipulated by topological insulators.[48][49] The effect is related to metal–insulator transitions (Bose–Hubbard model).[citation needed]
Floquet topological insulators
Topological insulators are challenging to synthesize, and limited in topological phases accessible with solid-state materials.[50] This has motivated the search for topological phases on the systems that simulate the same principles underlying topological insulators. Discrete time quantum walks (DTQW) have been proposed for making Floquet topological insulators (FTI). This periodically driven system simulates an effective (Floquet) Hamiltonian that is topologically nontrivial.[51] This system replicates the effective Hamiltonians from all universal classes of 1- to 3-D topological insulators.[52][53][54][55] Interestingly, topological properties of Floquet topological insulators could be controlled via an external periodic drive rather than an external magnetic field. An atomic lattice empowered by distance selective Rydberg interaction could simulate different classes of FTI over a couple of hundred sites and steps in 1, 2 or 3 dimensions.[55] The long-range interaction allows designing topologically ordered periodic boundary conditions, further enriching the realizable topological phases.[55]
Properties and applications
Spin-momentum locking
The most promising applications of topological insulators are spintronic devices and dissipationless
Thermoelectrics
Some of the most well-known topological insulators are also thermoelectric materials, such as Bi2Te3 and its alloys with Bi2Se3 (n-type thermoelectrics) and Sb2Te3 (p-type thermoelectrics).[65] High thermoelectric power conversion efficiency is realized in materials with low thermal conductivity, high electrical conductivity, and high Seebeck coefficient (i.e., the incremental change in voltage due to an incremental change in temperature). Topological insulators are often composed of heavy atoms, which tends to lower thermal conductivity and are therefore beneficial for thermoelectrics. A recent study also showed that good electrical characteristics (i.e., electrical conductivity and Seebeck coefficient) can arise in topological insulators due to band inversion-driven warping of the bulk band structure.[66] Often, the electrical conductivity and Seebeck coefficient are conflicting properties of thermoelectrics and difficult to optimize simultaneously. Band warping, induced by band inversion in a topological insulator, can mediate the two properties by reducing the effective mass of electrons/holes and increasing the valley degeneracy (i.e., the number of electronic bands that are contributing to charge transport). As a result, topological insulators are generally interesting candidates for thermoelectric applications.
Synthesis
Topological insulators can be grown using different methods such as
(MBE).[34] MBE has so far been the most common experimental technique. The growth of thin film topological insulators is governed by weak van der Waals interactions.[71] The weak interaction allows to exfoliate the thin film from bulk crystal with a clean and perfect surface. The van der Waals interactions in epitaxy also known as van der Waals epitaxy (VDWE), is a phenomenon governed by weak van der Waal's interactions between layered materials of different or same elements[72] in which the materials are stacked on top of each other. This approach allows the growth of layered topological insulators on other substrates for heterostructure and integrated circuits.[72]
MBE growth of topological insulators
Molecular beam epitaxy (MBE) is an epitaxy method for the growth of a crystalline material on a crystalline substrate to form an ordered layer. MBE is performed in high vacuum or ultra-high vacuum, the elements are heated in different electron beam evaporators until they sublime. The gaseous elements then condense on the wafer where they react with each other to form single crystals.
MBE is an appropriate technique for the growth of high quality single-crystal films. In order to avoid a huge lattice mismatch and defects at the interface, the substrate and thin film are expected to have similar lattice constants. MBE has an advantage over other methods due to the fact that the synthesis is performed in high vacuum hence resulting in less contamination. Additionally, lattice defect is reduced due to the ability to influence the growth rate and the ratio of species of source materials present at the substrate interface.[73] Furthermore, in MBE, samples can be grown layer by layer which results in flat surfaces with smooth interface for engineered heterostructures. Moreover, MBE synthesis technique benefits from the ease of moving a topological insulator sample from the growth chamber to a characterization chamber such as angle-resolved photoemission spectroscopy (ARPES) or scanning tunneling microscopy (STM) studies.[74]
Due to the weak van der Waals bonding, which relaxes the lattice-matching condition, TI can be grown on a wide variety of substrates[75] such as Si(111),[76][77] Al
2O
3, GaAs(111),[78]
InP(111), CdS(0001) and Y
3Fe
5O
12 .
PVD growth of topological insulators
The physical vapor deposition (PVD) technique does not suffer from the disadvantages of the exfoliation method and, at the same time, it is much simpler and cheaper than the fully controlled growth by molecular-beam epitaxy. The PVD method enables a reproducible synthesis of single crystals of various layered quasi-two-dimensional materials including topological insulators (i.e., Bi
2Se
3, Bi
2Te
3).[79] The resulted single crystals have a well-defined crystallographic orientation; their composition, thickness, size, and the surface density on the desired substrate can be controlled.
The thickness control is particularly important for 3D TIs in which the trivial (bulky) electronic channels usually dominate the transport properties and mask the response of the topological (surface) modes. By reducing the thickness, one lowers the contribution of trivial bulk channels into the total conduction, thus forcing the topological modes to carry the electric current.[80]
Bismuth-based topological insulators
Thus far, the field of topological insulators has been focused on bismuth and antimony chalcogenide based materials such as Bi
2Se
3, Bi
2Te
3, Sb
2Te
3 or Bi1 − xSbx, Bi1.1Sb0.9Te2S.[41] The choice of chalcogenides is related to the van der Waals relaxation of the lattice matching strength which restricts the number of materials and substrates.[73] Bismuth chalcogenides have been studied extensively for TIs and their applications in thermoelectric materials. The van der Waals interaction in TIs exhibit important features due to low surface energy. For instance, the surface of Bi
2Te
3 is usually terminated by Te due to its low surface energy.[34]
Bismuth chalcogenides have been successfully grown on different substrates. In particular, Si has been a good substrate for the successful growth of Bi
2Te
3 . However, the use of sapphire as substrate has not been so encouraging due to a large mismatch of about 15%.[81] The selection of appropriate substrate can improve the overall properties of TI. The use of buffer layer can reduce the lattice match hence improving the electrical properties of TI.[81] Bi
2Se
3 can be grown on top of various Bi2 − xInxSe3 buffers. Table 1 shows Bi
2Se
3, Bi
2Te
3, Sb
2Te
3 on different substrates and the resulting lattice mismatch. Generally, regardless of the substrate used, the resulting films have a textured surface that is characterized by pyramidal single-crystal domains with quintuple-layer steps. The size and relative proportion of these pyramidal domains vary with factors that include film thickness, lattice mismatch with the substrate and interfacial chemistry-dependent film nucleation. The synthesis of thin films have the stoichiometry problem due to the high vapor pressures of the elements. Thus, binary tetradymites are extrinsically doped as n-type (Bi
2Se
3, Bi
2Te
3 ) or p-type (Sb
2Te
3 ).[73] Due to the weak van der Waals bonding, graphene is one of the preferred substrates for TI growth despite the large lattice mismatch.
Substrate | Bi 2Se 3 % |
Bi 2Te 3 % |
Sb 2Te 3 % |
---|---|---|---|
graphene | -40.6 | -43.8 | -42.3 |
Si | -7.3 | -12.3 | -9.7 |
CaF 2 |
-6.8 | -11.9 | -9.2 |
GaAs | -3.4 | -8.7 | -5.9 |
CdS | -0.2 | -5.7 | -2.8 |
InP | 0.2 | -5.3 | -2.3 |
BaF 2 |
5.9 | 0.1 | 2.8 |
CdTe | 10.7 | 4.6 | 7.8 |
Al 2O 3 |
14.9 | 8.7 | 12.0 |
SiO 2 |
18.6 | 12.1 | 15.5 |
Identification
The first step of topological insulators identification takes place right after synthesis, meaning without breaking the vacuum and moving the sample to an atmosphere. That could be done by using angle-resolved photoemission spectroscopy (ARPES) or scanning tunneling microscopy (STM) techniques.[74] Further measurements includes structural and chemical probes such as X-ray diffraction and energy-dispersive spectroscopy but depending on the sample quality, the lack of sensitivity could remain. Transport measurements cannot uniquely pinpoint the topology by definition of the state.
Classification
Bloch's theorem allows a full characterization of the wave propagation properties of a material by assigning a matrix to each wave vector in the Brillouin zone.
Mathematically, this assignment creates a vector bundle. Different materials will have different wave propagation properties, and thus different vector bundles. If we consider all insulators (materials with a band gap), this creates a space of vector bundles. It is the topology of this space (modulo trivial bands) from which the "topology" in topological insulators arises.[7]
Specifically, the number of
This space can be restricted under the presence of symmetries, changing the resulting topology. Although unitary symmetries are usually significant in quantum mechanics, they have no effect on the topology here.[82] Instead, the three symmetries typically considered are time-reversal symmetry, particle-hole symmetry, and chiral symmetry (also called sublattice symmetry). Mathematically, these are represented as, respectively: an anti-unitary operator which commutes with the Hamiltonian; an anti-unitary operator which anti-commutes with the Hamiltonian; and a unitary operator which anti-commutes with the Hamiltonian. All combinations of the three together with each spatial dimension result in the so-called periodic table of topological insulators.[7]
Future developments
The field of topological insulators still needs to be developed. The best bismuth chalcogenide topological insulators have about 10 meV bandgap variation due to the charge. Further development should focus on the examination of both: the presence of high-symmetry electronic bands and simply synthesized materials. One of the candidates is half-Heusler compounds.[74] These crystal structures can consist of a large number of elements. Band structures and energy gaps are very sensitive to the valence configuration; because of the increased likelihood of intersite exchange and disorder, they are also very sensitive to specific crystalline configurations. A nontrivial band structure that exhibits band ordering analogous to that of the known 2D and 3D TI materials was predicted in a variety of 18-electron half-Heusler compounds using first-principles calculations.[83] These materials have not yet shown any sign of intrinsic topological insulator behavior in actual experiments.
See also
- Topological order
- Topological quantum computer
- Topological quantum field theory
- Topological quantum number
- Quantum Hall effect
- Quantum spin Hall effect
- Periodic table of topological invariants
- Bismuth selenide
- Photonic topological insulator
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Further reading
- Hasan, M. Zahid; Kane, Charles L. (2010). "Topological Insulators". S2CID 16066223.
- Kane, Charles L.; Moore, Joel E. (2011). "Topological Insulators" (PDF). .
- Hasan, M. Zahid; Xu, Su-Yang; Neupane, M (2015). "Topological Insulators, Topological Dirac semimetals, Topological Crystalline Insulators, and Topological Kondo Insulators". In Ortmann, F.; Roche, S.; Valenzuela, S. O. (eds.). Topological Insulators. Wiley. pp. 55–100. ISBN 9783527681594.
- Brumfiel, G. (2010). "Topological insulators: Star material". Nature (Nature News). 466 (7304): 310–1. PMID 20631773.
- Murakami, Shuichi (2010). "Focus on Topological Insulators". New Journal of Physics.
- Moore, Joel E. (July 2011). "Topological Insulators". IEEE Spectrum.
- Ornes, S. (2016). "Topological insulators promise computing advances, insights into matter itself". Proceedings of the National Academy of Sciences. 113 (37): 10223–4. PMID 27625422.
- "The Strange Topology That Is Reshaping Physics". Scientific American. 2017.