Introduction

The development of a better understanding of the role of topology in electronic states has led to a revolution in exploring both old and new compounds for non-trivial topologies, and has provided a fertile platform to search for new topological fermionic excitations1,2,3. The discovery of topological insulators (TIs) with robust metallic surface states protected by the topology of the insulating bulk1,2 was followed by the discovery of topological semimetals (TSMs). These are found to have deep connections with particle physics models of relativistic chiral (Weyl) fermions and also provide fermionic excitations without high-energy counterparts3,4,5,6,7,8,9,10,11,12. In a Dirac semimetal (DSM), bulk valence and conduction bands cross each other linearly at discrete points protected by time-reversal, inversion, and crystal symmetries. These stable Dirac points with four-fold degeneracy make it possible to simulate massless Dirac fermions3,4. By breaking either inversion or time-reversal symmetry, a Dirac semimetal can be tuned to a Weyl state where the nondegenerate linear touchings of the bulk bands come in pairs. Each Weyl point with two-fold-degeneracy has a definite chirality of ±1 and the quasiparticle excitations mimic the relativistic Weyl (chiral) fermions5,6,13,14.

Cd3As2 and Na3Bi were the first theoretically predicted DSM candidates15,16, subsequently confirmed by experiments17,18,19,20. Recently, several materials including transition-metal icosagenides MA3 (M = V, Nb, and Ta; A = Al, Ga, In)21, MgTa2N322,23, CaAgBi24 and PtTe225, were predicted to host Dirac fermions. These form part of an even larger list of TSMs26,27,28 that also exhibit exotic physical properties including high carrier mobilities, chiral anomaly physics and topological superconductivity. Extremely large magnetoresistance (MR) is another symptom of such materials, which is usually very small in non-magnetic, non-compensated metals according to semiclassical transport theory. However, several TSMs—including Dirac semimetals Cd3As2 and ZrSiS29,30,31, the NbAs family32,33,34,35, the type-II Weyl semimetal WTe236 and several other TSMs such as NbSb237, PtSn438,39, LaSb40—exhibit extremely large MR behavior which could have potential application in magnetic sensors, spintronics, and memories. Very recently, multiple topological states have been predicted and observed in the iron-based superconductors LiFeAs and Fe(Se, Te)41, while possible Dirac fermions are predicted in heavy fermion superconductors Ce(Co,Rh,Ir)In542.

The MA4 family of materials (M = Sr, Ba, Eu; A = Al, Ga, In) form the prototype parent crystal structure of a large family of compounds including the ThCr2Si2-based iron superconductors43, classic heavy fermions systems such as CeCu2Si244,45, and numerous non-centrosymmetric compounds46. In addition, the MA4 family itself presents a rich variety of ground states. For instance, SrAl4 exhibits a charge density wave transition at 200 K, while Eu(Ga, Al)4 orders antiferromagnetically at 15 K and is thought to also exhibit charge density wave order47,48. In this work, we present the comprehensive combined experimental and theoretical study of topology in the classic prototype compound BaAl4, including first-principles electronic structure calculations, transport measurements, and angle-resolved photoemission (ARPES) studies. We predict BaAl4 to be a topological three-dimensional Dirac semimetal, where one pair of type-I Dirac points resides on the rotational axis with the C4v point group symmetry, and confirm this prediction using ARPES and quantum oscillations experiments. The calculated band structure is in excellent agreement with ARPES spectra, and Hall resistivity and quantum oscillations measurements confirm the multiband structure with electron and hole pockets, and is consistent with the predicted presence of Dirac hole pockets. Together with an extremely large MR that does not saturate in fields up to 32 T, our results indicate BaAl4 is a topological semimetal, and point to the MA4 family of materials as fertile territory for the exploration of a basis of topological systems.

Results

Non-trivial topology in BaAl4

Figure 1 a, b presents schematic illustrations of both the crystal structure and the bulk Brillouin zone of BaAl4. The high quality of single crystals grown by a self-flux method (see Fig. 1c) is confirmed by X-ray diffraction (Fig. S1 in SM) and core-level electron photoemission spectrum, as shown in Fig. 1d. Rietveld refinement of powder X-ray diffraction spectra confirms our samples to have the body-centered tetragonal structure with space group I4/mmm (No. 139). Clear peaks from Ba-5s, Ba-5s, and Al-2p core-level electrons observed by photoemission spectroscopy confirm the correct chemical composition.

Fig. 1: Non-trivial topology of prototype compound BaAl4.
figure 1

The crystal structure (a) and Brillouin zone (b) of single-crystalline BaAl4 (c) with I4/mmm space group are presented along with electronic structure calculations and symmetry analysis, revealing a three-dimensional Dirac spectrum with non-trivial topology. d The integrated photoemission core-level spectrum exhibits sharp peaks from Ba-5s, Ba-5p, and Al-2p core-levels, confirming high sample quality. The calculated bulk electronic structure is presented (e) without spin-orbit coupling and (f) with spin-orbit coupling included, with red box highlighting the Γ–Z dispersion where a Dirac point is located. g Enlarged low-energy band structure with irreducible representation, where the two crossing bands belong to two different irreducible representations of the C4v point group, showing the accidental band crossing protected by the crystal symmetry. The zoomed 3D Dirac structure exhibits a linear dispersion along the out-of plane (kz) direction [panel (h)] and a quadratic dispersion along the in-plane (kx/ky) directions [panel (i)], classifying this as a semi-Dirac point where massless and massive fermions can coexist at the same point in momentum space (see text).

In the BaAl4 unit cell, the Ba atoms sit at the Wyckoff position 2a, while the Al atoms sit at two non-equivalent Wyckoff positions 4d and 4e, as shown in Table I in the Supplementary Materials. Among them, 2a and 4d sites are the maximal Wyckoff positions, but 4e is not. The 4e Wyckoff position has a stabilizer group49 which is a subgroup of the stabilizer group of the maximal position 2a or 2b. Figure 1e, f shows the calculated bulk electronic structure along high-symmetry lines without (with) spin-orbit coupling, showing its semimetallic ground state feature. One observes that there are several crossing points along the Γ–X, Γ–Σ, and Z–Σ1 directions in different mirror reflection planes from two quasi-linear bands close to the Fermi level (EF) in the band structure without SOC. These Dirac nodal points could give rise to a variety of Dirac nodal lines in each mirror plane and also exotic surface states, which deserve further study.

Once the SOC is included, most of these crossing points open small gaps because the two crossing bands belong to the same irreducible representation of the point group indicated by the eigenvalue analyses. For example, the two bands crossing each other along the Γ–Σ direction at ~0.1 eV both belong to Γ5 representation and then the crossing point is gapped out. However, the crossing point along the Γ–Z direction is different. On Γ–Z path which is along the rotational axis, the point group symmetry is of C4v. The two doubly degenerate crossing bands (highlighted by the red square in Fig. 1f) are found to form two distinct irreducible representations Γ6 and Γ7 representation of the C4v double group. In Fig. 1g, we show these two bands belong to different representations of the symmetry group; therefore, the intersection of the two double-degenerate bands is protected by the crystalline symmetry, C4v, forming a massless Dirac fermion. Figure 1h, i shows the zoomed dispersion along out-of-plane (kz) and in-plane directions (kx/ky). While the slopes of the two crossing bands along the out-of-plane (kz) have opposite signs, reminiscent of a type-I Dirac point16,17,18,19,20, the dispersion along the other directions is quadratic. The crossing points are above the Fermi level, according to the ab initio calculations. The physical elemental band representations (pEBRs) are constructed by the orbitals at the maximal positions with time-reversal symmetry49, with all the pEBRs of 2a2b and 4d listed in Table II in the Supplementary Materials. For high-symmetry points, the eigenvalues (irreps) of all symmetry operators have been computed from the VASP wave functions for each band27,50. Referring to the character tables in the Bilbao Crystallographic Server (BCS)49,51, we successfully assign all the bands to corresponding irreducible representations (irreps). The irrep characters of the valence bands are listed in Table III in the Supplementary Materials. One can check if those valence bands can be decomposed into a linear combination of pEBRs. It turns out they cannot, which means those valence bands cannot be topologically trivial.

Angle-resolved photoemission

To verify band structure calculations, we measured ARPES to obtain the electronic structure of BaAl4 at various photon energies, using in situ cleaved single crystals of BaAl4 where the (001) surface cleavage plane is determined by X-ray diffraction (Fig. S1b of Supplementary Information). Figure 2 shows the measured ARPES spectra compared to the calculation (red curves). The intensity variation across the measured ARPES data is attributed to photoemission matrix element effects. Note that we shifted the calculated band structure by 70 meV (hole doping) to take into account the experimental data in Fig. 2. In Fig. 2a, we present the Fermi surface in the out-of-plane direction. The highly dispersive Fermi surface is clearly resolved, suggesting its bulk three-dimensional nature. Figure 2e shows the energy and momentum cut along the Z−Γ−Z line where the C4v exists. Consistent with the DFT prediction, the tail of the Dirac dispersion, which consists of small and large electron pockets at Z and Γ points, respectively, is observed. To further investigate the electronic structures, we show the in-plane Fermi surfaces for the high-symmetry planes (kz ~ 0, kz ~ 2π/c, and kz ~ 0.92π/c where the Dirac point (DP) protected by C4v is located) and the electronic dispersions (Γ–Σ, Z–Σ1, and DP) in Fig. 2b, c, f–h. Overall, the experimental Fermi surfaces and electronic dispersions are consistent with band structure calculations for all directions.

Fig. 2: ARPES spectra near the Fermi level compared to DFT calculation of BaAl4.
figure 2

ac Constant energy maps at EF in the high-symmetry planes: the kykz plane (perpendicular to the surface (001)-plane) (a) using the incident photon energy ranging from 80 to 120 eV, the kxky plane crossing Γ (b) using the incident photon energy of 95 eV, and the kxky plane crossing Z (c) using the incident photon energy of 112 eV. Black solid line represents the bulk Brillouin zones (BZ), marked with high-symmetry points. d Constant energy map at EF crossing the location of Dirac point (DP) using the incident photon energy of 86 eV. eg ARPES spectra of energy versus momentum cuts along the high-symmetry directions: Z–Γ–Z (e), Σ–Γ–Σ (f), and Σ1Z–Σ1 (g). h ARPES spectra of energy versus momentum cut crossing the DP along the in-plane direction ky. All spectra shown in (ad) are obtained by integrating intensities in the energy window of ±20 meV at EF. The red lines superposed in all panels here are the DFT calculation results for BaAl4. The locations of Dirac point are marked with green dots in (a, d). For a direct comparison, all Fermi surfaces (ad) and all energy and momentum cuts (e–h) shown here are centered at (kx, ky, kz) = (0, 0, 0) and symmetrized.

Similar to graphene, multiple Dirac dispersions in BaAl4 create a saddle-point singularity in between the two DPs in momentum space as a result of a change in electronic topology, reminiscent of a Lifshitz transition in the electronic structure. Figure 3a shows the location of the DP and VHS in the bulk BZ of BaAl4. To identify the saddle-point singularity experimentally, we show the energy and momentum dispersion along the Z−Γ−Σ direction (along the red line in Fig. 3a, b) in Fig. 3c. While the tail of the Dirac dispersion has the local energy minimum in between the DPs, the Γ point, the dispersion along the orthogonal direction (in-plane direction, Γ−Σ) has the opposite curvature, resulting in the saddle-point singularity of band structure, a Van Hove singularity (VHS). The integrated energy-distribution curve (EDC) around the Γ point shown in Fig. 3d clearly indicates the peak of local density of states (DOS) at ~−0.45 eV. This peak is consistent with a local DOS maximum in a saddle-point since the band structure is nearly flat at the VHS. Emergence of a VHS is associated with a Lifshitz transition. Figure 3e–j represents a series of ARPES constant energy maps near the Γ point (see the blue square in Fig. 3b) with various binding energies, emphasizing the change of topology of electronic structures. The energy contours of Dirac dispersions become close to each other toward the Γ point as the binding energy changes to deeper level (shown in Fig. 3e–g). Once it reaches the Lifshitz point (~−0.45 eV), the two unconnected tails of Dirac dispersions merge and the electronic topology changes as shown in Fig. 3h–j. This change in electronic topology is also clearly reproduced by the theoretical calculation (The red lines in Fig. 3h–j).

Fig. 3: Lifshitz point and Van Hove singularity in BaAl4.
figure 3

a The bulk BZ marked with the location of Dirac point (DP, green dot) and Van Hove singularity of saddle point type (VHS, light blue point). The light green plane represents the location for the constant energy contours shown in (b, ej). b Constant energy map at EF. The light blue square shows the location for (ej). Red lines in (a, b) are the high-symmetry lines for the energy and momentum cut shown in (c). c ARPES spectra of energy versus momentum cuts along the Z−Γ−Σ. The local maximum and minimum are observed at the same momentum Γ point, showing the saddle point singularity VHS. d Energy-distribution curve (EDC) obtained by integrating the ARPES intensity in the vicinity of Γ point (window size: ±0.02 Å−1). The peak of the EDC marks the VHS at EB ~ −450meV where the topology of Fermi surface changes. ej Series of the symmetrized constant energy maps at EB = −0.2, −0.35, −0.4, −0.45, −0.5, and −0.55 eV, respectively, showing the topology of electronic structure changes at the Lifshitz point (h), EB ~ −450meV. The red lines superposed in these panels here are the DFT calculation results for EB = −0.27, −0.4, −0.45, −0.497, −0.55, and −0.57, respectively. For a direct comparison, all constant energy maps (b, ej) are symmetrized, and these maps and the energy and momentum cut (c) shown here are centered at (kx, ky, kz) = (0, 0, 0).

Because the Dirac point protected by C4v symmetry is above EF and hence not accessible to ARPES, we cannot directly observe the vicinity of DP. However, the excellent agreement between our ARPES results and the first-principles calculation, validates the theoretical prediction of Dirac fermions above EF, confirming BaAl4 as a topological semimetal with Dirac points. Additionally, a VHS has been considered the key to inducing various correlated states, especially when close to the Fermi level, as shown in high-Tc superconductors52 and bilayer graphenes53,54. While further studies are needed to shift the Fermi level close to VHS with several techniques, such as chemical doping and gating techniques, our observation suggests that BaAl4 is an ideal 3D analog of graphene, similar to Na3Bi and provides a platform to study correlated effects induced by a VHS. Moreover, in BaAl4, while the Dirac dispersion along the out-of-plane axis (kz) has a linearly type-I dispersion, the dispersion is quadratic along the in-plane axis (kx/ky) as shown in Figs. 1h, i and 2e, h. Hence these DPs can be classified as semi-Dirac points where massless and massive fermions can coexist at the same point in momentum space. Similar semi-Dirac points are theoretically predicted and/or experimentally observed in two-dimensional systems such as a silicene oxide Si2O and black phosphorus55,56, and could result in interesting properties including highly anisotropic transport, distinct Landau level spectrum in a magnetic field, non-Fermi liquid, and Bloch-Zener oscillations57,58. Additionally, two-photon photoelectron (2PPE) spectroscopy technique may enable the investigation of the detailed electronic structure above EF, including the DP. As well as a thorough investigation and characterization, it is worth studying light-induced response by 2PPE because of the structure of DP in BaAl4. Such massive and anisotropic DP may induce a prolonged lifetime and electron-hole pairs.

Magnetoresistance and quantum oscillations

Figure 4 presents the electrical transport properties of single-crystalline BaAl4 samples. Extremely high mobilities approaching 200,000 cm2/Vs (see Hall analysis below) are reflective of the high quality of the samples, also indicated by very large residual resistivity ratios (RRR = ρ(300K)/ρ(2K) = 1500 in Sample A) and tiny residual resistivities (~ 90 nΩ cm). As observed in other TSMs such as WTe2, NaBi3, Cd3As2, TaAs, LaBi, and other related compounds16,29,34,36,40, a dramatic onset of strong MR develops at low temperatures and presents astonishingly high and unsaturated MR values attributed to the opening of an energy gap by magnetic fields at the band-touching point. In BaAl4, we also observe similar behavior, with a large upturn in resistivity at low temperatures that tends to saturate. Figure 4b presents the transverse MR for Sample B with current applied parallel to the ab plane and field along the c-axis, showing a quadratic evolution with field that does not saturate up to at least 35 T. MR exhibits an amplitude correlated with crystal quality (shown in Fig. S2 of supplementary materials). For Sample A with the highest RRR ~ 1500, the MR approaches 2 × 105% at 14 T (shown in Fig. 4a and also in Fig. S2 of supplementary materials), a value comparable to that reported in Cd3As2, the TaAs family, and other TSMs (including LaP with P=Sb and Bi, WTe2, NbSb2 family). At higher fields, the MR does not saturate, as shown for Sample B data up to 35 T, where MR approaches 106% (Fig. 4b).

Fig. 4: Extremely large magnetoresistance and carriers of Dirac semimetal BaAl4.
figure 4

a Temperature dependence of the resistivity at different magnetic field which is perpendicular to the electrical current for single crystal sample A. b Transverse magnetoresistance with current in the ab plane and field along the c-axis, for single crystal Sample B at several representative temperatures under field up to 35 T. In the measurements, the current is in the ab plane and the field is along the c-axis. c Field dependence of the Hall resistivity measured at several representative temperatures. d, e Temperature dependence of the mobility of the holes (μh) and electrons (μe), as well as the density of the holes (nh) and the density of the electrons (ne).

As shown in Fig. 4c, the Hall resistivity ρxy is positive above 50 K and nearly linear with field, indicating holes as the majority carriers at high temperatures. However, ρxy deviates from linear at temperatures below 50 K, and even changes sign at low temperature and high field, indicating coexistence of electrons and holes. It has been proposed that the extremely large MR in several semimetals arises due to a perfect compensation between electron and hole carrier concentrations59. The calculated band structure of BaAl4 does indeed show complex coexistence of electron and hole pockets. The hole pockets (see Fig. 5a) corresponding to the Dirac point along the Γ–Z direction mostly consist of two separated hollow cylinders surrounding the Z points, while the electron pocket is a one-piece structure centered at the Γ point shown in Fig. 5b. However, the volume surrounded by the hole and electron pockets is different. To estimate the carrier densities and mobility, a semiclassical two-band model is used to analyze the longitudinal conductivity σxx(B) and Hall conductivity σxy(B) in the magnetic fields B:

$${\sigma }_{xx}(B)=\frac{{n}_{e}q{\mu }_{e}}{1+{({\mu }_{e}B)}^{2}}+\frac{{\sigma }_{xx}(0)-{n}_{e}q{\mu }_{e}}{1+{({\mu }_{h}B)}^{2}},$$
(1)
$${\sigma }_{xy}(B)=\left[\frac{{n}_{e}{\mu }_{e}^{2}}{1+{({\mu }_{e}B)}^{2}}-\frac{{n}_{h}{\mu }_{h}^{2}}{1+{({\mu }_{h}B)}^{2}}\right]eB.$$
(2)

Here ne (μe) and nh (μh) are the carrier densities (mobilities) of electrons and holes, respectively. σxx(0) is the longitudinal conductivity at 0 T. The typical fitting results at several different temperatures are shown in Fig. S3a, b in the Supplementary Materials, and the fitting parameters are shown in Fig. 4d, e in the temperature range 2 K ~ 50 K. At low temperatures, holes are the minority carriers, but their mobility is nearly one order higher than the mobility of electrons. At 2 K, μh approaches ~20 m2/Vs. With increasing temperature, μh decreases significantly and becomes comparable to μe. Hence, the minority hole carriers dominate the transport in the entire temperature range because of their high mobility. This is consistent with the calculated electronic structure, where the Dirac pockets have hole characteristics.

Fig. 5: Fermi surface and quantum oscillation of Dirac semimetal BaAl4.
figure 5

a, b Calculated hole pockets (a) and electron pockets (b) in the Fermi surface for BaAl4 by density function theory with spin-orbit coupling. c The quantum oscillation in the magnetoresistance of BaAl4 single crystal at 2 K. The inset shows the FFT spectrum of the quantum oscillation. d Enlarged part of the low frequency region of the FFT spectrum of the quantum oscillation for Sample B of BaAl4 at different temperatures. The inset shows the detail of the FFT spectrum in high frequency region at 2K. e Wilson loop spectrum on a spherical surface enclosing the Dirac point \((0,0,{k}_{z}^{c})\). f Phase φj of the individual loop eigenvalues \(({e}^{i{\varphi }_{j}})\) as a function of the azimuthal angle θ.

Quantum oscillations measurements further clarify the nature of carriers in BaAl4. As shown in Fig. 4b, the measured MR of several BaAl4 crystals exhibits clear Shubnikov–de Haas oscillations. Subtracting a background MR yields an oscillatory signal composed of several components observable down to a few Teslas, as shown in Fig. 5c. The oscillation frequencies of different pockets in the calculated Fermi surface are extracted by finding the supercell k-space extremal area implemented in the SKEAF code60 and are compared to the frequencies by Fourier transform analysis of the experimental curves, correspondingly the oscillation frequencies obtained by Fourier transform of our experiment curves (in Fig. 5d) are assigned to different pockets of the calculated Fermi surface. Our experimental results are consistent with the calculated Fermi surface shown in Fig. 5a, b, and also most of them are close to the previous report reports47, as shown in Table IV of SM. In the high frequency region as shown in the inset of Fig. 5d, the frequency Fβ ~ 2.5 kT corresponds to the electron pocket shown in Fig. 5b, and the other frequency \({F}_{{\alpha }_{4}} \sim 1.6\) kT corresponds to the outer branch of the hole pocket surrounding Γ point in Fig. 5a. A small frequency \({F}_{{\alpha }_{3}} \sim 300\) T corresponds to the inner branch of the hole pocket. In addition to the detailed angular dependence of these frequencies previously reported47, two very close oscillation frequencies \({F}_{{\alpha }_{1}} \sim 100\) T and \({F}_{{\alpha }_{2}} \sim 106\) T which are missing in previous report47, are observed. These two close frequencies give a clear beating behavior shown in Fig. 5, and correspond to the small hole pockets along Γ − X lines. Lifshitz–Kosevich analysis of the temperature-dependent oscillation amplitude (Fig. S4 of SM) for these two frequencies \({F}_{{\alpha }_{1}}\) and \({F}_{{\alpha }_{2}}\) reveals a similar effective mass of ~0.2(1)me. This small effective mass of the hole pockets is consistent with the calculated hole-like Dirac spectrum (with a mass of about 0.15me, shown in Table IV of SM) and the ARPES measurement.

Discussion

Quantum oscillations, Hall resistivity and ARPES results reveal that although the electron and hole pockets coexist in BaAl4, they harbor different densities. This implies that some other mechanism beyond the perfect compensation between electron and hole pockets should govern the extremely large MR found in BaAl4, which may be related to the Dirac spectra as discussed for other TSMs. The extremely small residual resistivity ~90 nΩ cm is quite anomalous given the low carrier density ~1020 cm−3, and is similar to the case for other topological semimetals such as WTe2 (~30 nΩ cm) and La(Bi,Sb) (~0.1 μΩ cm), suggesting a topology-derived mechanism for reduction in scattering and large MR29,61. Although the Fermi surface is about 0.4 eV away form the Dirac points, the winding feature of the Wilson loop spectrum can still be stabilized by the C4z symmetry. Figure 5 shows the Wilson loop spectrum on a spherical surface enclosing the Dirac point \((0,0,{k}_{z}^{c})\) (e) and the phase φj of the individual loop eigenvalues \(({{\rm{e}}}^{{\rm{i}}{\varphi }_{j}})\) as a function of the azimuthal angle θ (f). On a given-θ Wilson loop, \((r\dot{s}in(\theta)cos(\phi),r\dot{s}in(\theta)sin(\phi),{k}_{z}(\theta))\) with \({k}_{z}(\theta)={k}_{z}^{c}+r\dot{c}os(274)\) and the spherical radius r, the Wilson loop is mapped as \({C}_{4z}{W}_{2\pi \leftarrow 0}{C}_{4z}^{-1}={W}_{\frac{5\pi }{2}\leftarrow \frac{\pi }{2}}={W}_{\frac{\pi }{2}\leftarrow 0}{W}_{2\pi \leftarrow 0}{W}_{0\leftarrow \frac{\pi }{2}}\), where WBA represents a parallel transport from ϕ = A to ϕ = B. Then we can redefine a symmetry \({\varsigma }_{4z}={W}_{\frac{\pi }{2}\leftarrow 0}^{-1}{C}_{4z}\), which yield \({\varsigma }_{4z}{W}_{2\pi \leftarrow 0}{\varsigma }_{4z}^{-1}={W}_{2\pi \leftarrow 0}\). Thus, each Wilson energy φj can be labeled by \({\lambda }_{\alpha }{{\rm{e}}}^{-{\rm{i}}\frac{{\varphi }_{j}}{4}}\) with \({\lambda }_{j}={{\rm{e}}}^{{\rm{i}}\frac{(2n-1)\pi }{4}}\) for j = {1, 2, 3, 4}, where we use \({\varsigma }_{4z}={W}_{\frac{\pi }{2}\leftarrow 0}^{-1}{C}_{4z}=-{{\rm{e}}}^{-{\rm{i}}{\varphi }_{j}}\). Our further calculations show that the ς4z eigenvalue of the blue(red) line is \({\lambda }_{2}{{\rm{e}}}^{-{\rm{i}}\frac{{\varphi }_{j}}{4}}\) (\({\lambda }_{3}{{\rm{e}}}^{-{\rm{i}}\frac{{\varphi }_{j}}{4}}\)). Thus, those two Wilson eigenstates cannot hybridize with each other, giving rise to a stable crossing in the Wilson loop spectrum. As long as the surface states are C4z symmetric, the winding feature of the Wilson loop spectrum is stable. This could, for instance affect the bulk transport properties, but requires further investigation.

Our results verify BaAl4 as a topological semimetal, as confirmed by calculations, symmetry analysis, photoemission, and transport experiments. Since a large diversity of physical phenomena appears in compounds derived from this prototype structure, one can consider the MA4 family as a playground for exploring the interaction between the non-trivial topology and symmetry-breaking or correlated phases, including superconductivity, heavy fermion and quantum critical systems, charge/spin density wave, etc. It could also be expected that some distortion/modification of the original crystal structure in the derived structures will slightly modify the topological electronic structure and induce phenomena. One interesting direction is to consider the consequences of breaking the inversion symmetry to achieve a non-centrosymmetric structure (e.g. LaPtSi3 and other materials), where band splitting could be expected to achieve Weyl or multiple-fermion states3. Noncollinear magnetic order (such as in EuAl4) may also induce band splitting, yielding other exotic topological states. 3D Dirac semimetals are on the verge of being topologically non-trivial. However, as long as the momentum is away from a high-symmetry point, the Dirac semimetals, when gapped, always go into a topological state, not a trivial one. One cannot gap a Dirac semimetal, infinitesimally, into a trivial state. The fact that the Dirac node cannot be immediately gapped (with small gapping terms) into a trivial state but only into a topological one brings about the second topological characterization62. Finally, we note that a recent theoretical study has proven that Dirac nodes show hinge Fermi arcs as the spectroscopic signatures, similar to Weyl nodes. While it remains a challenge for future research to detect such states in the MA4 family63, it offers a rich platform to investigate transport properties reflecting the hinge modes, such as nonlocal quantum oscillations and SQUIDs. Extending the symmetry analysis to the rest of the MA4 family of materials (M = Sr, Ba, Eu; A = Al, Ga, In), as well as the enormous set of derivative structures27, will expose more topological materials.

Methods

Crystal growth

Single crystals of BaAl4 were synthesized by a high-temperature self-flux method. Chunks of Ba (99.98%, Alfa Aesar) and pieces of Al (99.999% metal basis, Alfa Aesar) in the ratio of 2:98 were placed in the Canfield alumina crucible set with a decanting frit (LSP ceramics), sealed in the quartz ampule under partial Ar pressure, heated to 1150 C, held at that temperature for 6 h, cooled down at 3 degree/h to 950 C with subsequent decanting of the excess Al with the help of a centrifuge. The crystals tend to grow with large faceted surfaces normal to the (001) crystallographic plane. X-ray diffraction data were taken at room temperature with Cu Kα (λ = 0.15418 nm) radiation in a powder diffractometer.

Transport measurement

Electrical transport measurements up to 14 T were conducted on polished samples in a Quantum Design Physical Properties Measurement System (Dynacool) applying the conventional four-wire contact method. High field MR and dHvA oscillation were measured at the National High Magnetic Field Laboratory (NHMFL) Tallahassee DC Field Facility up to 35 T, using a one-axis rotator in a He-3 cryostat with temperature range 0.35–70 K. In all transport measurements, the electrical current flowing in the ab plane. The magnetization and dHvA oscillations were measured using a piezoresistive cantilever. The magnetic field rotated from a direction parallel to the c-axis to a direction parallel to the ab plane.

Photoemission measurement

ARPES measurements on single-crystalline samples of BaAl4 were performed at the Beamline 4.0.3 (MERLIN) of the Advanced Light Source in Berkley, California. Samples were cleaved in situ to yield clean (001) surfaces and measured at 14–20 K in ultra-high vacuum better than 3 × 10−11 Torr using photon energy of 80–120 eV with Scienta R8000 analyzer. The energy resolution was 20–30 meV and the angular resolution was better than 0.2 for all measurements. The inner potential V0 = 10.5 eV was used to calculate the momentum perpendicular to the surface.

DFT calculation

Theoretical calculations compared to ARPES were performed within generalized gradient approximation (GGA)64 for bulk BaAl4 as implemented in the VASP package65,66,67, using a relativistic version of PAW potentials68,69. The experimental crystal data (a = b = 4.566 Å and c = 11.278 Å) were used for the bulk calculation. PAW pseudopotentials with a plane wave energy cut-off of 40 Ry were used, and Monkhorst k-mesh was chosen as 24 × 24 × 24. All calculations prepared by VASP were double checked by the QUANTUM ESPRESSO Package70,71.