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Semimetal

A semimetal is a material in characterized by a small overlap between the bottom of its conduction and the top of its , resulting in a zero but a very low at the . This structure leads to a small, equal number of electrons and holes as charge carriers, enabling electrical conductivity that is metallic in nature yet orders of magnitude lower than in conventional metals, with carrier concentrations typically on the order of 10^17 to 10^19 cm^{-3}. Semimetals thus exhibit properties intermediate between those of metals and semiconductors, including positive temperature-dependent resistivity similar to semiconductors and high carrier mobilities due to low effective masses. Classical semimetals, such as (), (), (As), and , have been studied since the early 20th century for their unique electronic behaviors arising from this band overlap. In these materials, the is small and often anisotropic, leading to direction-dependent transport properties and nonspherical electron orbits, which contribute to phenomena like the de Haas-van Alphen effect. , for instance, displays exceptionally high and low thermal conductivity, making it valuable in thermoelectric applications where efficient heat-to-electricity conversion is desired. In the past decade, a new class of topological semimetals has garnered significant attention, featuring gapless band crossings protected by crystal symmetries and hosting exotic quasiparticles like Weyl and Dirac fermions, which emerge from band inversions rather than accidental overlaps. Unlike classical semimetals, these materials exhibit nontrivial topology, manifesting in such as Fermi arcs and chiral anomaly-related transport effects, with examples including Cd₃As₂ and Na₃Bi as Dirac semimetals, and TaAs and NbP as Weyl semimetals. Their high electron mobilities—exceeding 10^6 cm² V⁻¹ s⁻¹ in some cases—and strong spin-orbit coupling position topological semimetals as promising candidates for , , and low-energy electronics.

Definition and Fundamentals

Definition

A semimetal is a class of materials characterized by a small energy overlap between the bottom of the conduction band and the top of the valence band, typically on the order of tens of meV (e.g., ~38 meV in ), which eliminates a band gap while restricting the density of charge carriers. This overlap allows both electrons and holes to exist near the without requiring thermal activation, distinguishing semimetals from materials with distinct band gaps. Key features of semimetals include a zero or near-zero and a low () at the , which limits the number of available charge carriers and imparts behaviors resembling semiconductors—such as temperature-dependent conductivity—despite enabling metallic-like conduction at low temperatures. The low arises from the specific band touching or crossing points near the , often in the form of points or lines in momentum space, leading to carrier densities orders of magnitude smaller than in typical metals. Semimetals differ from metals, where a substantial band overlap results in a high and abundant free carriers for high electrical ; from semiconductors, which have a finite (usually 0.1–4 ) necessitating thermal excitation to generate carriers; and from insulators, featuring large (>4 ) that prevent significant conduction even at elevated temperatures. This intermediate electronic structure positions semimetals uniquely between fully conducting and insulating regimes. In a basic energy band schematic for a semimetal, the rises to meet and slightly overlap with the descending conduction band around the , creating pocket-like regions of electrons above and holes below this level, but without the extensive filling seen in metals. This overlap configuration ensures a pseudogap-like feature in the , maintaining balance between conduction and states.

Historical Development

The concept of semimetals emerged in the late 1920s and 1930s alongside the development of quantum mechanical band theory for solids. Felix Bloch's 1928 thesis introduced the idea of electrons in a periodic potential, described by Bloch waves, which formed the basis for understanding energy bands and gaps in materials. This framework allowed for the possibility of overlapping with no energy gap, a defining feature of semimetals, distinguishing them from metals with partially filled bands and insulators with full gaps. In the 1930s, applications of Bloch's to specific highlighted semimetallic , particularly in group V post-transition metals like , , and . Harry Jones extended Bloch's ideas to in 1934, analyzing its galvanomagnetic effects and proposing a band structure with small overlap leading to low carrier densities and unique transport properties. Nevill Mott and Jones further developed these concepts in their 1936 , emphasizing how the metal-insulator transition influences semimetal characteristics, such as compensated and carriers in group V . Mott's broader work on electronic correlations and transitions provided foundational insights into the boundaries between metallic, insulating, and semimetallic states. Experimental confirmation of semimetallic structures came in the mid-20th century through and spectroscopic measurements. In the 1950s and 1960s, experiments on revealed low effective masses and carrier densities on the order of 10^{17} cm^{-3}, consistent with band overlap rather than a gap. Benjamin Lax and colleagues' 1955 studies using cyclotron absorption directly probed the pockets, verifying the semimetal model for . Vsevolod Gantmakher advanced this understanding in the 1970s with detailed investigations of magnetotransport in semimetals like , elucidating electron-hole interactions and effects under high fields. By the 1980s, the semimetal classification extended to layered materials like graphite, whose band structure—calculated earlier but refined through de Haas-van Alphen measurements—showed a slight overlap between π valence and conduction bands, confirming its semimetallic nature with anisotropic conductivity. This period marked a transition to more sophisticated theoretical models, setting the stage for 2000s predictions of topological semimetals, where band touchings at Weyl or Dirac points were proposed in inversion-symmetric crystals, extending the conventional semimetal paradigm.

Electronic Band Structure

Band Overlap and Fermi Level

In semimetals, the electronic band structure features a slight overlap between the valence and conduction bands, distinguishing them from both insulators and conventional metals. This overlap occurs indirectly, meaning the maximum of the valence band and the minimum of the conduction band lie at different points in reciprocal space (k-space), rather than at the same wavevector as in direct overlaps typical of metals. As a result, the conduction band minimum is positioned slightly above the valence band maximum in energy at their respective k-points, but the bands extend into a common energy range due to their dispersion, creating pocket-like regions where states from both bands coexist near the Fermi energy. The in semimetals resides within this narrow overlap region, partially filling states in both the . This positioning leads to the formation of small pockets in the conduction band and pockets in the valence band, manifesting as closed contours in momentum . In intrinsic semimetals, the symmetric overlap results in equal densities of s and s, with carrier concentrations typically on the order of 10^{17} to 10^{19} cm^{-3}, much lower than in metals. For instance, in , the valence band maximum at the T point lies approximately 38 meV above the conduction band minimum at the point, producing distinct pockets near L and a pocket near T. The overlap energy, defined as \Delta E = E_{v,\max} - E_{c,\min}, quantifies this band intersection and is typically small, ranging from 10 to 100 meV, ensuring a pseudogap-like behavior with limited states at the . In the limit of zero overlap (\Delta E = 0), the and pockets would annihilate, transforming the semimetal into a with a finite . Momentum-space schematics illustrate these pockets as compact, ellipsoid-shaped surfaces offset from the center, highlighting the compensation between and contributions to transport.

Density of States

In semimetals, the (DOS), denoted as g(E), describes the number of available electronic states per unit energy interval and volume, and it plays a crucial role in determining the material's electronic behavior near the E_F. Due to the slight overlap of , the DOS profile near E_F is typically near-linear or in , leading to a significantly reduced value compared to metals. For instance, in , a prototypical semimetal, the DOS at E_F is approximately $10^{20} states/eV/cm³, which is about two orders of magnitude lower than the typical $10^{22} states/eV/cm³ observed in metals like . This low DOS at E_F results in small effective carrier concentrations, typically on the order of $10^{17} to $10^{19} cm^{-3}, even without an energy gap to suppress carriers. In , for example, the and concentrations are each around $3 \times 10^{17} cm^{-3} at . Consequently, semimetals exhibit ambipolar conduction, where both electrons from the conduction pocket and holes from the valence pocket contribute comparably to charge , distinguishing them from unipolar conduction in metals or doped semiconductors. The functional form of the DOS in three-dimensional semimetals arises from the parabolic dispersion near the band edges formed by the band overlap, yielding g(E) \propto |E - E_F|^{1/2} for energies close to E_F. In contrast, two-dimensional or quasi-two-dimensional semimetals with linear dispersion, such as , display a linear DOS, g(E) \propto |E - E_F|. Unlike semiconductors, where the DOS vanishes at E_F and features exponential tails due to thermal or disorder effects, semimetals lack pronounced Van Hove singularities near E_F, resulting in a smooth, weakly varying profile that underscores their unique carrier statistics.

Physical Properties

Electrical and Thermal Conductivity

Semimetals display electrical conductivity governed by the formula \sigma = n e \mu, where n arises from the small band overlap near the , leading to a low but finite density, and \mu is the enhanced by the low effective of charge carriers, typically m^* \approx 0.01 - 0.1 \, m_e for electrons and holes. This low m^* results in high mobilities, often exceeding $10^4 \, \mathrm{cm}^2/\mathrm{V \cdot s} at low s, enabling conductivities comparable to poor metals despite the reduced n. The dependence of \sigma varies with the degree of overlap: in cases of significant overlap, it shows a weak metallic-like increase with temperature due to , whereas minimal overlap can yield a semiconducting decrease as alters balance. Thermal conductivity \kappa in semimetals is notably high, primarily from phonon contributions and electronic transport, with ambipolar diffusion playing a key role as electrons and holes recombine and redistribute heat. The Wiedemann-Franz law, relating \kappa / (\sigma T) \approx L_0 where L_0 = 2.44 \times 10^{-8} \, \mathrm{W \Omega / K^2}, holds approximately in many semimetals but shows deviations at low temperatures or fields due to the low carrier density, which enhances and suppresses the Lorenz number. These deviations manifest as \kappa scaling faster than expected (e.g., T^4 at ultralow temperatures in compensated systems), highlighting non-Fermi liquid behavior. Carrier density n in semimetals remains approximately constant or weakly temperature-dependent, determined by the intrinsic overlap rather than thermal activation, unlike in semiconductors where n rises exponentially with . Under external perturbations like , semimetals can undergo a transition to a semiconducting state; for instance, exhibits a semimetal-to-semiconductor transition around 2.5 GPa, where band overlap closes, sharply increasing resistivity. At elevated temperatures under such , this transition is influenced by , further modulating transport. The ambipolar nature of transport leads to a low Seebeck coefficient S, given by S = \frac{\sigma_e S_e + \sigma_h S_h}{\sigma_e + \sigma_h}, where S_e < 0 and S_h > 0 for electrons and holes, respectively, causing partial cancellation in compensated systems and yielding S \approx 0 when effective masses are similar. This opposition suppresses thermoelectric power, though inelastic electron-hole scattering can introduce deviations, enhancing |S| slightly in asymmetric bands.

Magnetic and Optical Properties

Semimetals exhibit pronounced diamagnetic responses due to their electronic band structures, which feature small carrier orbits and high charge carrier mobility, leading to enhanced orbital contributions to the magnetization. In bismuth, a classic example, the molar diamagnetic susceptibility is approximately -2.8 \times 10^{-4} emu/mol at room temperature, reflecting the material's strong overall diamagnetism. This property is particularly evident in the de Haas-van Alphen effect, where magnetization oscillates periodically with applied magnetic field strength, providing insights into the small Fermi surface pockets characteristic of semimetals like bismuth. The effect arises from quantized Landau levels and is most prominent at low temperatures and high fields. The strong diamagnetism observed in semimetals like bismuth arises from their unique electronic band structures and small Fermi surfaces, which enhance orbital contributions beyond the simple free-electron Landau diamagnetism model. Temperature influences this diamagnetism, with susceptibility magnitude decreasing as thermal excitation broadens the Fermi distribution and reduces the coherence of orbital motion. Optically, semimetals show low reflectivity across the , akin to semiconductors, but their overlapping enable starting from zero via intraband and low-energy interband processes. A distinct edge emerges in the region, driven by the low free carrier density, as seen in where it marks the from metallic-like reflectivity to higher . Direct interband transitions prevail at elevated energies, contributing to the material's optical response. External perturbations such as or doping can induce an effective optical in semimetals, shifting edges and altering the frequency toward semiconducting characteristics.

Classification

Conventional Semimetals

Conventional semimetals represent a subclass of semimetals where the conduction and bands exhibit accidental overlaps at the , arising from the specific electronic structure of the material rather than any symmetry-imposed protection. These overlaps typically manifest as small and pockets in the , resulting in a very low near the and intermediate electrical between metals and semiconductors. Unlike symmetry-protected crossings, the band overlaps in conventional semimetals are fragile and can be eliminated by external perturbations such as or chemical . The defining criteria for conventional semimetals include a small overlap ΔE, often on the order of a few meV, between the valence band maximum and conduction band minimum, with no associated topological invariants like Chern numbers or . This overlap lacks robustness against or tuning parameters, allowing the material to transition to an insulating state by opening a band gap through methods like doping, , or temperature-induced defects. For instance, the full-Heusler compound Fe₂VAl was initially classified as a conventional semimetal but was reclassified as a narrow-gap in 2020, with calculations revealing a tunable bandgap of approximately 0.03 eV that widens under thermal activation of Al/V inversion defects. Historically, conventional semimetals were classified based on their energy-momentum (E-k) dispersion relations derived from band structure calculations and experimental probes like de Haas-van Alphen effect measurements. In these E-k diagrams, the overlaps appear as closed electron-hole pockets for typical cases, such as in , where the Fermi surface consists of small, disconnected pockets leading to compensated carrier densities. This classification emphasized the accidental nature of the band touching, distinguishing conventional semimetals from gapped materials without invoking modern topological concepts. A key challenge in studying conventional semimetals lies in their ambiguous distinction from narrow-gap semiconductors, where tiny energy overlaps (ΔE < 10 meV) can be misinterpreted as negligible gaps due to experimental resolution limits or computational approximations, complicating precise categorization. Additionally, the absence of topological invariants means conventional semimetals do not exhibit bulk-boundary correspondence, lacking robust, protected surface states that connect bulk band features to boundary modes.

Topological Semimetals

Topological semimetals are gapless electronic phases of matter in three dimensions where band crossings occur at discrete points or lines in the momentum space, protected by topological invariants and symmetries rather than fragile overlaps. These materials exhibit nontrivial topology characterized by invariants such as Chern numbers for point nodes or winding numbers for line nodes, ensuring robustness against weak perturbations that preserve the underlying symmetries. The protection arises from the global properties of the Bloch wavefunctions, leading to emergent phenomena distinct from conventional semimetals. Several types of topological semimetals are distinguished by the nature and dimensionality of their protected crossings. Weyl semimetals feature pairs of Weyl nodes acting as sources and sinks of Berry flux with monopole charges of ±1, necessitating the breaking of either inversion or time-reversal symmetry to stabilize the nodes. Dirac semimetals, in contrast, host Dirac nodes that are four-fold degenerate points with zero net monopole charge, requiring additional crystalline symmetries like rotation or mirror symmetries for protection. Nodal-line semimetals contain one-dimensional loops of band crossings in the Brillouin zone, often protected by mirror or chiral symmetries, where the topology is encoded in the linking numbers of these lines. Recent advances have introduced multifold topological semimetals featuring higher-degeneracy band crossings beyond twofold. Key features of topological semimetals stem from the bulk-boundary correspondence, which predicts the existence of surface states manifesting as Fermi arcs—open contours on the surface Brillouin zone connecting the projections of bulk nodes. In transport, the chiral anomaly, arising from the monopole structure, induces phenomena such as Adler-Bell-Jackiw anomaly-driven negative magnetoconductivity under parallel electric and magnetic fields. The theoretical foundation traces back to Hermann Weyl's 1929 prediction of massless chiral fermions as solutions to the Dirac equation in the context of quantum field theory, with experimental realizations of these quasiparticles in condensed matter systems emerging around 2015. Mathematically, the essence of these systems is captured by the Berry curvature \vec{\Omega}(\vec{k}), which behaves as an effective magnetic field in momentum space and integrates to the over closed surfaces enclosing the nodes, sourcing monopoles at . Near a , the low-energy effective Hamiltonian takes the form H = v \vec{\sigma} \cdot (\vec{k} - \vec{k_0}), where v is the , \vec{\sigma} are the , and \vec{k_0} locates the node, describing linearly dispersing chiral quasiparticles. This linear dispersion results in a low density of states near the nodes, scaling as |\epsilon|^2 with energy \epsilon, which influences the overall electronic properties.

Examples and Materials

Elemental Semimetals

Elemental semimetals are pure chemical elements that exhibit semimetallic behavior due to a small overlap between their conduction and valence bands, resulting in a finite density of states at the without a full band gap. These materials, primarily from groups 14 and 15 of the , display unique electronic properties arising from their crystal structures, which lead to anisotropic charge carrier transport and limited carrier densities. Key examples include group 15 elements like arsenic, antimony, and bismuth, as well as certain allotropes of and tin, where the band overlap is typically on the order of tens to hundreds of millielectronvolts. Arsenic (As) adopts a stable rhombohedral A7 crystal structure, consisting of puckered layers with two atoms per primitive cell, which is characteristic of group 15 semimetals. This structure results in a small band overlap of approximately 0.5 eV between the valence and conduction bands, enabling semimetallic conduction with low carrier densities. Arsenic has been a subject of early experimental studies on semimetal transport properties, including low-temperature measurements that highlighted its rhombohedral symmetry's role in the band structure. Antimony (Sb) shares a similar rhombohedral A7 structure with arsenic, leading to comparable semimetallic characteristics and a band overlap of around 0.2 eV. Its electronic properties exhibit strong anisotropy, with conductivity varying significantly along and perpendicular to the trigonal axis due to the layered arrangement. This anisotropy contributes to antimony's potential in thermoelectric applications, where its semimetallic nature allows for tunable carrier concentrations through doping or strain to optimize the and electrical conductivity. Bismuth (Bi), another group 15 element, possesses the rhombohedral A7 structure but features the smallest band overlap among these semimetals, approximately 0.03 eV, which results in an exceptionally low carrier density and high mobility. Bismuth displays strong diamagnetism, arising from its multiband electronic structure and orbital effects near the Fermi level. Under applied pressure, bismuth undergoes a semimetal-to-semiconductor transition, where the band overlap is suppressed, opening a small gap and altering its transport properties. Graphite, an allotrope of carbon, behaves as a layered semimetal with weak interlayer coupling, mimicking two-dimensional electronic behavior. Its band structure features Dirac points at the K points of the Brillouin zone, where the conduction and valence bands touch linearly, leading to massless Dirac fermion excitations. This structure positions graphite as a precursor to modern topological semimetals, and its electronic properties are described by the , a tight-binding approach that accounts for interlayer interactions and the trigonal warping of the Fermi surface. Alpha-tin (gray tin), a low-temperature allotrope of tin, adopts a diamond-like cubic structure but with an inverted band order compared to silicon or germanium, resulting in a semimetallic state with a band overlap of about 0.4 eV. This overlap allows for metallic conduction despite the semiconductor-like lattice. However, alpha-tin is thermodynamically unstable at room temperature, transitioning to the metallic beta-tin phase above 13.2°C, which limits its practical applications without stabilization techniques like epitaxial growth on substrates.

Compound and Layered Semimetals

Compound semimetals, such as mercury telluride (HgTe), exhibit inverted band structures where the Γ₆ conduction band lies below the Γ₈ valence band, resulting in a negative band gap that renders the material semimetallic. This inversion can be tuned by alloying with cadmium telluride (CdTe) to form Hg₁₋ₓCdₓTe, allowing the narrow gap to transition from semimetallic (x ≈ 0) to semiconducting (x > 0.16). Such tunability arises from hydrostatic pressure or strain effects that modify the band overlap, enabling applications in detection where the semimetallic phase provides high carrier mobility. Bismuth-antimony (Bi-Sb) alloys, particularly compositions like Bi₈₅Sb₁₅, function as thermoelectric semimetals due to their semimetallic band structure with low carrier effective masses and high mobilities at cryogenic temperatures. The semimetallic nature stems from band inversion near the point, where the valence band maximum and conduction band minimum touch or overlap slightly, depending on the Sb content (typically 3-20 at.% for optimal thermoelectric performance). These alloys achieve high figures of merit (ZT > 0.5 at 100 K) through conduction and low thermal conductivity, making them suitable for near-room-temperature cooling. Topological compound semimetals host protected band crossings that realize exotic quasiparticles. In the tantalum arsenide (TaAs) family, including TaAs, NbAs, , and NbP, Weyl fermions emerge as pairs of opposite-chirality nodes separated in momentum space, first experimentally confirmed in TaAs in 2015 via (ARPES). These chiral fermions exhibit surface Fermi arcs connecting bulk Weyl points, with the TaAs structure ( I41md) hosting 24 Weyl nodes due to broken inversion and mirror symmetries. Cadmium arsenide (Cd₃As₂) represents a three-dimensional Dirac semimetal with spin-degenerate Dirac cones along the Γ-X direction, protected by and evidenced by ARPES in 2014. It demonstrates exceptionally high , reaching approximately 10⁵ cm²/V·s at and up to 10⁷ cm²/V·s at low temperatures, attributed to minimal from the linear and low effective . Zirconium silicon sulfide (ZrSiS) exemplifies a nodal-line semimetal, where bands cross along a loop in the , protected by nonsymmorphic symmetry and glide-plane operations, as confirmed by quantum oscillations and ARPES. This yields drumhead surface states and weak antilocalization effects. Layered compound semimetals, often van der Waals materials, enable tunable topological phases through thickness control. ditelluride (WTe₂) in its Td phase realizes type-II Weyl semimetals, where tilted Weyl cones emerge from electron-hole pocket tilts exceeding the , predicted in 2015 and evidenced by transport signatures like negative magnetoresistance in 2017. The Weyl nodes lie near the , approximately 50 meV below, hosting eight Weyl nodes in four pairs with opposite . , a prototypical two-dimensional Dirac semimetal, features massless Dirac fermions at the K and K' points due to its honeycomb lattice and π-π* band touching, with linear dispersion v_F ≈ 10⁶ m/s and zero bandgap. dichalcogenides like WTe₂ extend this to bulk layered forms, where interlayer coupling modifies the nodal structure. Synthesis of these compound and layered semimetals typically employs (MBE) for epitaxial thin films, enabling precise thickness control and interface engineering, as demonstrated in high-quality Cd₃As₂ and WTe₂ growth on substrates like GaAs. (CVD) facilitates scalable production of layered materials such as and WTe₂ nanoflakes, though it requires optimized precursors to minimize defects. Topological compounds face stability challenges, including air sensitivity and oxidation in TaAs-family materials, necessitating inert atmospheres or encapsulation, while during growth poses issues for narrow-gap systems like HgTe.

Applications and Advances

Technological Applications

Semimetals, particularly bismuth-antimony (Bi-Sb) alloys, are widely utilized in thermoelectric devices such as Peltier coolers due to their favorable combination of high electrical conductivity and low conductivity, achieving figure-of-merit values (ZT) of approximately 1-2 near . These alloys enable efficient solid-state cooling by converting electrical energy directly into a , with applications in portable and where compressors are impractical. In , narrow-gap semimetals like mercury telluride (HgTe) serve as key materials for () detectors, leveraging their zero or near-zero bandgap to achieve high sensitivity across mid- to long-wave spectra. HgTe-based superlattices and alloys, such as HgCdTe, are integrated into focal plane arrays for , thermal imaging, and systems, offering tunable bandgaps for specific wavelengths. Additionally, Weyl semimetals have been theoretically proposed to support low-loss waveguides, potentially reducing propagation losses in photonic integrated circuits for . Weyl semimetals contribute to through their strong intrinsic , which generates dissipationless spin currents for efficient spin-based information processing and storage. In devices like spin Hall nano-oscillators, materials such as TaAs enable low-power manipulation of magnetization via spin-orbit torques, promising energy-efficient alternatives to conventional charge-based . Emerging applications harness the ultrahigh of cadmium arsenide (Cd3As2), a Dirac semimetal, in next-generation transistors, where field-effect devices demonstrate gate-tunable transport for high-speed, low-power logic operations. , with its unique diamagnetic response, is explored in magnetocaloric cooling systems, where field-induced entropy changes in bismuth-doped alloys enhance refrigeration efficiency without harmful refrigerants.

Recent Research Developments

In the mid-2010s, experimental breakthroughs confirmed the existence of topological semimetals hosting exotic quasiparticles. Angle-resolved photoemission spectroscopy (ARPES) measurements on tantalum arsenide (TaAs) revealed Weyl fermions as pairs of Weyl nodes near the Fermi level, marking the first direct observation of these monopoles of Berry curvature in a condensed matter system. Similarly, ARPES studies on sodium bismuthide (Na₃Bi) identified a three-dimensional topological Dirac semimetal phase with bulk Dirac cones protected by crystal symmetry, providing a platform analogous to three-dimensional graphene. Subsequent milestones validated key theoretical predictions of topological phenomena. In 2016, magneto-transport experiments on zirconium pentatelluride (ZrTe₅) observed the chiral magnetic effect, evidenced by a negative quadratic in , arising from the Adler-Bell-Jackiw anomaly in its Weyl-like band structure. The theoretical framework for higher-order topological semimetals, which feature protected boundary modes beyond conventional , was established in 2019 through symmetry-based classifications extending to gapless systems. Realization followed in the 2020s, with materials exhibiting hinge-localized states. Research in the 2020s has emphasized overcoming practical limitations while exploring richer band structures. Key challenges include achieving room-temperature stability against thermal disorder and scalable synthesis for device integration, as many topological semimetals suffer from sensitivity to defects or require cryogenic conditions. Efforts have shifted toward multifold fermions, where band degeneracies exceed twofold, enhancing spin-orbit coupling effects; for instance, sixfold fermions in materials like rhodium silicide (RhSi) exhibit amplified chiral responses observable in . Magnetic Weyl semimetals, such as Co₃Sn₂S₂, have emerged as focal points due to their intrinsic , with anomalous Hall conductivity reaching 10⁴ S/cm from Weyl node separation by broken time-reversal . Looking ahead, integrating topological semimetals with superconductors holds promise for engineering Majorana zero modes, as proximity-induced pairing in Weyl surfaces can host chiral Majorana edge states for fault-tolerant . As of 2025, high-throughput computational searches have identified over 500 new magnetic topological candidates, accelerating the discovery of stable quantum material platforms with tunable multifold degeneracies.