Whereas the electronic band topology in nonmagnetic topological materials is determined by the crystal symmetry and the relative strength of spin-orbit coupling, the magnetic ground state also plays a decisive role in magnetic topological materials1,2,3,4,5,6,7. The concurrence of magnetism and electronic band topology leads to unusual states of matter, including Weyl fermions in centrosymmetric systems8,9, magnetic topological insulators10, quantum anomalous Hall states11, and axion insulators12. The dependence of band topology on the magnetic ground state grants access to topological phase transitions by manipulation of the latter, and opens up a route for discovering functional properties in magnetic topological materials.

f-electron materials provide a fertile setting for discovering emergent physics at the intersection of magnetism, electron correlations and topology, including magnetic topological insulators13,14,15,16, as well as topological spin textures17,18,19,20 and strongly correlated topological phases such as topological Kondo insulators and semimetals21,22,23,24. Among the f-electron magnetic topological materials, EuCd2As2, which crystallizes into the trigonal CaAl2Si2-type structure25, exhibits a single Dirac cone at the Fermi level well inside the paramagnetic state, offering an ideal platform for realizing exotic quasiparticles13,26,27. Below the antiferromagnetic transition temperature TN ≈ 9 K, the Eu2+ moments are oriented in the ab-plane and form A-type antiferromagnetic (AFM) order, with antiferromagnetically stacked ferromagnetic (FM) Eu2+ layers28. With such a magnetic ground state, a gap opens at the Dirac point and the system may be a small-gap magnetic topological insulator (MTI)14,29. A fully polarized state along the c-axis can be readily obtained upon applying a magnetic field, giving rise to an ideal single pair of Weyl points14,30. A Weyl state is also suggested for the paramagnetic phase slightly above TN based on photoemission measurements, resulting from a proliferation of quasi-static in-plane ferromagnetic fluctuations31,32. A plethora of additional topological states, including magnetic Dirac semimetals, axion insulator, and higher-order topological insulator, are also expected given the appropriate magnetic ground state29. Moreover, in addition to becoming fully polarized under modest in-plane or c-axis magnetic fields28, a FM ground state can be stabilized by changes in the synthesis protocol33 or applying hydrostatic pressure34, demonstrating highly-tunable magnetism. These behaviors highlight the proximity of competing magnetic ground states in EuCd2As2, which can be harnessed to manipulate its electronic topology.

Here, by carrying out resistivity measurements on EuCd2As2 single crystals under hydrostatic pressure, we find an insulating dome within a small pressure window between pc1 ~ 1.0 GPa and pc2 ~ 2.0 GPa, straddled by two regimes (p < pc1 and p > pc2) with metallic transport. The insulating state is easily suppressed by a magnetic field (0.2 T for H c), leading to a remarkable colossal negative magnetoresistance (MR) which reaches ~105% at 0.3 K, and can likely be enhanced upon further cooling. Based on first-principles calculations, these experimental observations may arise from two topological phase transitions tuned by magnetism. Namely, a transition from an AFM topological insulator to an AFM trivial insulator (TrI) at pc1 ~ 1.0 GPa, and a transition from an AFM TrI to a FM Weyl semimetal (WSM) at pc2 ~ 2.0 GPa, triggered by a pressure-induced AFM-FM transition of the magnetic ground state. A similar mechanism accounts for the suppression of the TrI state under applied magnetic field, which polarizes the AFM state and transforms the system to a WSM, leading to the colossal MR. These findings demonstrate that the combination of Dirac fermions and proximate magnetic ground states provides a route for discovering tunable topological quantum materials with functional properties.


Metallic-insulating-metallic evolution of electrical transport under pressure

EuCd2As2 crystallizes in a centrosymmetric trigonal structure (space group \(P\bar{3}m1\)25), with planes of Eu2+ that form triangular lattices [inset of Fig. 1a] separated by layers of Cd-As tetrahedra networks25. Whereas the FM alignment of magnetic moments within the ab-plane is robust, the stacking of these FM planes can be tuned between AFM or FM order along the c-axis, resulting in an overall A-type AFM or FM ground state28,33,35. Given the proximity between these magnetic ground states, the physical properties of our EuCd2As2 samples were carefully characterized at ambient pressure, with the results summarized in Fig. 1. Clear peaks in both the resistivity ρ(T) and specific heat Cp(T) are observed around TN ≈ 9 K (Fig. 1a, b). Measurements of the magnetic susceptibility under a small field of 0.1 T (Fig. 1c) suggest an AFM ground state with an easy ab-plane, in agreement with resonant x-ray scattering measurements28. Magnetization measurements reveal saturation fields (saturated moments) of about 1.7 T (7.1 μB/Eu) for H c and 0.7 T (7.0 μB/Eu) for H c (Fig. 1d). The saturated moments are close to the ideal value of 7.0 μB for Eu2+ ions, indicating localized magnetism. These characterizations establish that the EuCd2As2 samples used in this study exhibit an A-type AFM ground state below TN ≈ 9 K at ambient pressure, similar to previous reports28,34,36.

Fig. 1: Physical properties of EuCd2As2 at ambient pressure.
figure 1

a Temperature dependence of the resistivity ρ(T) in the ab-plane. The primitive unit cell is shown in the inset, with Eu2+ ions forming a triangular lattice in the ab-plane25. b Total specific heat Cp(T). c Magnetic susceptibility χ(T), measured in an applied field of μ0H = 0.1 T. d The field-dependence of the magnetization M(H), measured for two field directions at 2 K after zero-field cooling.

In order to track the pressure-evolution of the ground state properties of EuCd2As2, electrical resistivity measurements were carried out on four samples under pressures up to 2.50 GPa and temperatures down to 0.3 K. The results for two samples #1 and #2 are presented in Fig. 2, and the others are shown in the Supplementary Fig. 1. All samples exhibit consistent behaviors under pressure.

Fig. 2: Metallic-insulating-metallic evolution of electrical transport under applied pressure.
figure 2

Temperature dependence of the ab-plane resistivity ρ(T) of EuCd2As2 under various pressures from 0.45 GPa to 1.28 GPa, for samples (a) #1 and (b) #2. The corresponding ρ(T) under pressures from 1.50 GPa to 2.21 GPa are shown in panels (c) and (d). The insets of (c) and (d) show \(\ln \rho (T)\) as a function of 1/T at 1.50 GPa, and fits to \((\rho (T)-{\rho }_{0})\propto {e}^{\frac{{{\Delta }}}{{k}_{{{{\rm{B}}}}}T}}\) are performed at low temperatures, where \(\ln \rho (T)\) is linear in 1/T (solid black lines). The vertical arrow in each panel marks the direction of increasing pressure.

For pressures up to 0.87 GPa (Fig. 2a, b), ρ(T) is qualitatively similar to that at ambient pressure, with a sharp peak around TN and metallic behavior at low temperatures [ρ(0.3K)  20 mΩ  cm]. Upon increasing the pressure to 1.05 GPa, an additional subtle upturn appears when cooling below ~ 2 K. The upturn in ρ(T) at low temperatures becomes more prominent under 1.28 GPa, and is maximized around 1.50 GPa (Fig. 2c, d), with ρ(0.3K) reaching ≈ 40 Ω  cm and ≈15 Ω  cm, for samples #1 and #2 respectively [0 T data in Fig. 3e, f). The temperature-dependence of the resistivity under 1.50 GPa can be captured by \((\rho (T)-{\rho }_{0})\propto \exp (\frac{{{\Delta }}}{{k}_{{{{\rm{B}}}}}T})\), where ρ0 is a temperature-independent contribution and Δ represents an energy gap [insets in Fig. 2c, d]. This indicates that the upturn is associated with an electronic gap, suggesting a metal-insulator transition in EuCd2As2 across pc1 ~1.0 GPa. By fitting ρ(T) of all measured samples for T < 5 K, Δ is consistently found to be ≈ 0.07−0.10 meV at 1.50 GPa (see Supplementary Fig. 1 and Supplementary Note 1), suggesting that Δ does not exhibit a significant variation in samples used in this work. We note that an insulating behavior in ρ(T) was not reported in Ref. 34 at 1.57 GPa down to 5 K, possibly related to signatures of the insulating state being weak at 5 K and sample differences.

Fig. 3: Colossal magnetoresistance in EuCd2As2 under 1.50 GPa.
figure 3

Field-dependence of the resistivity ρ(H) at various temperatures, for fields (a) along the c-axis, and (b) in the ab-plane, plotted on a log scale. The magnetoresistance (MR) under 1.50 GPa of pressure at 0.3 K, defined as [ρ(H) − ρ(0)]/ρ(0), for (c) c-axis and (d) ab-plane magnetic fields. The fields needed to achieve −102%, −103%, −104% and −105% magnetoresistance are respectively 0.05 T, 0.10 T, 0.18 T and 0.42 T in (c), and respectively 0.04 T, 0.06 T, 0.10 T, and 0.22 T in (d). Temperature-dependence of the resistivity ρ(T) under various magnetic fields along (e) the c-axis, and in (f) the ab-plane.

Upon further increasing the pressure, the upturn in ρ(T) weakens under 1.79 GPa and disappears for p 2.21 GPa, at which ρ(0.3K) reverts back to  20 mΩ  cm. Such an evolution points to the restoration of metallic transport above pc2 ~ 2.0 GPa, and experimentally establishes the presence of an insulating dome within the magnetically ordered state for pc1 < p < pc2. Since A-type AFM order is present in EuCd2As2 up to ~ pc2, as indicated by the response of the resistivity to small magnetic fields (see Supplementary Fig. 2 and Supplementary Note 2) and previous transport and μSR measurements34, the insulating state appears tied to the AFM order.

Colossal magnetoresistance in the insulating state

To further elucidate the connection between the magnetic order and the insulating state under pressure, magnetoresistance measurements were carried out under 1.50 GPa for samples #1 and #2, and the results are shown in Fig. 3. Since the saturation field of EuCd2As2 is small (Fig. 1d), and further reduces with increasing pressure34, it is straightforward to assume that the A-type AFM order of EuCd2As2 can be polarized to achieve a FM state using accessible magnetic fields. If the insulating state indeed relies on the presence of A-type AFM order, it should be suppressed when the AFM state becomes fully polarized.

At 1.5 GPa, with increasing field both along the c-axis and in the ab-plane, ρ(0.3K) reduces by around three orders of magnitude, and settles to values less than 20 mΩ  cm, as shown in Fig. 3a, b. This transformation from insulating to metallic electrical transport is similar to the pressure-induced evolution across pc2. Quantitatively, the MR [defined as [ρ(H) − ρ(0)]/ρ(0)] at 0.3 K reaches −3.78 × 105% for sample #1 with H c [Fig. 3(c)], and −1.05 × 105% for sample #2 with H c (Fig. 3d). The values of the MR in EuCd2As2 are large even when compared to the colossal MR in the manganites37,38,39, and are even more striking considering that they are achieved with relatively small fields [caption of Fig. 3]. The fields at which the MR saturates are μ0H ~ 1.5 T for H c and μ0H ~ 0.2 T for H c, which are in excellent agreement with the saturation fields34, and indicates that the MR is associated with polarization of the Eu2+ moments. At higher temperatures, the resistivity in zero field is substantially reduced, whereas the resistivity under \(\left|{\mu }_{0}H\right|\gtrsim 2\) T remains similar to that at 0.3 K. This leads to a weakening of the MR upon warming, originating from a decrease in the zero-field resistivity with increasing temperature.

The colossal negative MR can also be seen from the temperature dependence of the resistivity under various fields for samples #1 and #2 at 1.50 GPa, as shown in Fig. 3e, f. Similar to the results in Fig. 2c, d, where the insulating state is suppressed by increasing pressure above pc2, modest magnetic fields also efficiently suppress the insulating state. In both cases, the A-type AFM phase is destabilized and superseded by a FM state, respectively due to an AFM-FM transition at pc2 ~ 2.0 GPa, or the full polarization of Eu2+ moments by an applied field. While a sizable MR is also seen in EuCd2As2 at ambient pressure near TN, it should be emphasized that the colossal MR we have uncovered in the insulating state of EuCd2As2 is distinct. Whereas the former is associated with critical fluctuations near a magnetic transition with similar behaviors detected in a number of Eu-based compounds40,41,42, the MR shown in Fig. 3 is linked to a field-induced transition from an insulating state with a small electronic gap Δ to a metallic state, and persists down to at least 0.3 K. Therefore, although the MR in our measurements may contain contributions related to critical fluctuations near the magnetic transition temperature, the MR at low temperatures (e.g. T < 2 K) clearly has a different, and thus far unreported mechanism.

From Fig. 3e, f, it can be seen that the low-temperature MR gradually decreases with increasing temperature. On the flip side, this suggests that the MR should continue to increase as the temperature is lowered below 0.3 K. In fact, since the resistivity tends to infinity for an insulator when the temperature approaches absolute zero, the MR could become substantially larger (possibly by orders of magnitude) than what we observed at 0.3 K. This consideration makes the colossal negative MR in EuCd2As2 of potential interest for ultra-low-temperature applications, especially ones at millikelvin temperatures.

Evolution of the electronic structure under pressure

The experimentally observed insulating dome is difficult to understand without considering magnetic order, and the colossal MR points to a strong coupling between electrical transport, which is dictated by the electronic topology, and magnetism. To gain insight into the origin of these experimental observations, the electronic structures of EuCd2As2 were calculated for different magnetic ground states and at various pressures, using density functional theory (DFT), with results shown in Fig. 4. Applied pressures in DFT calculations are gauged via the unit cell volume V, with increasing pressure corresponding to a decrease in V (see Supplementary Note 3 and Supplementary Table 1). For the A-type AFM state with moments in the ab-plane found experimentally28, EuCd2As2 is a MTI with a 10 meV bulk gap and topologically-protected surface states when V = 127.60 Å3 (Fig. 4a), and parity of the band states at time-reversal invariant momenta further indicate it can be categorized as an axion insulator (see Supplementary Note 3 and Supplementary Table 2). While the bulk of a MTI is insulating, topologically-protected surface states that cross the Fermi level [inset in Fig. 4a] give rise to metallic conduction, which accounts for the metallic conduction seen experimentally for p < pc1.

Fig. 4: Calculated band structures of EuCd2As2 tuned by the magnetic ground state and pressure.
figure 4

The electronic structure of A-type AFM EuCd2As2 with moments in the ab-plane, for unit cell volumes of (a) 127.60 Å3, (b) 124.78 Å3, and (c) 121.11 Å3. d The electronic structure for FM EuCd2As2 with moments in the ab-plane, with a unit cell volume of 121.11 Å3. Depending on the magnetic ground state and pressure (unit cell volume), EuCd2As2 may be a magnetic topological insulator (MTI), a trivial insulator (TrI), or a Weyl semimetal (WSM). The values of the energy gaps for the MTI and TrI states are indicated in the insets of (ac). The insets in (ac) show calculated surface states along − MΓM, with clear topologically-protected surface states in (a). The inset in (d) shows the surface Fermi arc along kz in the kx − kz-plane.

Within the A-type AFM state of EuCd2As2, upon increasing pressure such that V = 124.78 Å3, EuCd2As2 evolves to become a TrI with an 8 meV trivial band gap (Fig. 4b), where relative to the MTI state, topologically-protected surface states disappear due to an increase in the electronic hopping relative to spin-orbit coupling, which suppresses band inversion. When V becomes further compressed from 124.78 Å3 to 121.11 Å3, the trivial band gap increases from 8 meV to 64 meV (Fig. 4c). For a trivial insulator, its surface states are also gapped [insets in Fig. 4b, c], similar to the bulk, so that the system as a whole lacks mobile carriers. These calculations show that within the A-type AFM state of EuCd2As2, the transition from a MTI to a TrI upon increasing pressure provides an explanation for the experimentally observed evolution of electrical transport across pc1.

While AFM EuCd2As2 with V = 121.11 Å3 is a TrI [Fig. 4(c)], for a FM ground state with in-plane moments under the same pressure (same V), EuCd2As2 is a WSM with bulk Weyl points and a surface Fermi arc [Fig. 4d and its inset]. Such a FM state occurs experimentally when the moments are fully polarized by an ab-plane field or when p > pc2, with both the Weyl points and the Fermi arc contributing to metallic transport. A FM state with moments along the c-axis is also a WSM for V = 121.11 Å3 (see Supplementary Note 3 and Supplementary Fig. 3), which is realized in the fully polarized state when H c. The DFT results in Fig. 4c, d indicate that for AFM EuCd2As2 in the TrI state, altering the magnetic order to FM results in a WSM, which induces a insulator-metal transition. Experimentally, such a change can occur in two ways, either by applying a magnetic field to fully polarize the moments (Fig. 3), or by increasing pressure above pc2 (Fig. 2c, d), around which an AFM-FM transition occurs (see Supplementary Fig. 2 and Supplementary Note 2)34.

Based on the DFT calculations shown in Fig. 4, the evolution of the topological classification for EuCd2As2 under pressure is schematically shown in Fig. 5a. Under ambient pressure and inside the AFM state, EuCd2As2 is a small-gap MTI, with topologically-protected surface states contributing to metallic conduction. With increasing pressure, the bulk band inversion necessary for a topological insulator is suppressed and AFM EuCd2As2 becomes a TrI, with diminished charge carriers when cooled to sufficiently low temperatures. When EuCd2As2 goes through an AFM-FM transition, the TrI state evolves to become a WSM, with metallic conduction restored by Weyl fermions and surface Fermi arcs.

Fig. 5: Phase diagram of EuCd2As2 under pressure.
figure 5

a Theoretically anticipated evolution of the ground state in EuCd2As2 with increasing pressure, evolving from a magnetic topological insulator (MTI) to a trivial insulator (TrI), and then to a Weyl semimetal (WSM). Magnetic ground states and electronic structures associated with the MTI, TrI and WSM phases are shown schematically. The solid curve represents the evolution of the electronic gap, which is negative in the presence of a band inversion, and positive in its absence. b Color-coded experimental ρ(T) as a function of pressure and temperature for sample #4 (the results for other samples are provided in the Supplementary Fig. 7), note that ρ(T) is shown on a log scale. TN (black symbols) and TC (blue symbols) mark local maxima in dρ/dT, respectively corresponding to transition temperatures into the AFM and FM phases (see Supplementary Fig. 8). For comparison, the magnetic transition temperatures from Ref. 34 are also included in the plot.


Our resistivity measurements under pressure provide compelling evidence for an unusual insulating dome inside the AFM state of EuCd2As2 for pressures between pc1 ~ 1.0 GPa and pc2 ~ 2.0 GPa, with an AFM-FM transition in the magnetic ground state also occurring around pc2 (Fig. 5b). Such an evolution under pressure can be qualitatively captured by the DFT calculations, which suggest that EuCd2As2 goes through consecutive topological phase transitions. Within this scenario, the first transition is from a MTI to a TrI at pc1, occurring within the A-type AFM phase; the second transition that occurs at pc2 is from a TrI to a WSM, driven by the AFM-FM transition in the magnetic ground state. Given the proximity between the AFM and FM ground states35, the AFM-FM transition can also be driven by an applied field, which accounts for the colossal MR achievable with a small magnetic field. In such a situation, similar to increasing pressure above p2, the MR is caused by a change from a TrI to a WSM, which occurs both when FM moments are oriented along the c-axis or in the ab-plane (see Supplementary Note 3, Supplementary Table 3, and Supplementary Figs. 36).

The colossal negative MR observed in EuCd2As2 for pc1 < p < pc2 is unusual, as its magnitude is large, persists to the lowest temperatures, and likely arises from a field-induced topological phase transition from a TrI to a topologically nontrivial WSM. Given that the MR arises from an insulator-metal transition, record-breaking values of MR may be achieved upon cooling to ever lower temperatures. The small fields required to achieve the large values of MR further makes EuCd2As2 appealing for technological applications at very low temperatures. The observation of colossal MR for small fields both along the c-axis and in the ab-plane (Fig. 3c, d) means that the colossal MR would be robust regardless of the sample orientation, and would persist even in polycrystalline samples. While a modest pressure is required to access the TrI phase of EuCd2As2 with the colossal MR, it may be possible to replace the hydrostatic pressure with chemical pressure via partial substitution of P for As, and realize a similar colossal MR under ambient pressure.

Whereas the transition from a MTI to TrI under pressure within the AFM state of EuCd2As2 arises from enhanced electronic hopping that suppresses the band inversion, both the pressure- and field-induced transitions from a TrI to a WSM requires a transformation of the magnetic ground state. To facilitate such a change, the distinct magnetic ground states should be nearly degenerate, which in the case of EuCd2As2 results from weak magnetic exchange couplings along the c-axis, which can be easily overcome by an applied magnetic field. Furthermore, EuCd2As2 exhibits weak magnetic anisotropy due to the vanishing orbital moments of the Eu2+ ions, which allows the magnetic moments to become fully polarized regardless of the field orientation, leading to a robust colossal MR that is nearly independent of the relative orientation between the sample and the applied field. In combination with an electronic topology that depends on the magnetic structure, the weak interlayer magnetic exchange couplings and magnetic anisotropy in EuCd2As2 enables the switching between magnetic ground states, and hence the electronic topology, leading to dramatic changes in the macroscopic electrical transport. These findings demonstrate a clear example of topological phase transitions driven by the manipulation of the magnetic ground state, and underscore weak magnetic exchange couplings and magnetic anisotropy as key ingredients in the search for tunable magnetic topological materials.


Experimental details

Single crystals of EuCd2As2 were grown using the Sn-flux method, with synthesis details and basic characterizations in Refs. 43,44. Electrical resistivity measurements under pressure were carried out in a piston-cylinder pressure cell using the standard four probe method, with the current in the ab-plane. To ensure hydrostaticity, Daphne 7373 was used as the pressure-transmitting medium. Values of the applied pressure were determined from the shift of the superconducting transition temperature Tc for a high-quality Pb single crystal. All the resistivity measurements were performed down to 0.3 K in a 3He refrigerator with a 15 T magnet. Specific heat under ambient pressure was measured using a Quantum Design Physical Property Measurement System (PPMS), using a standard pulse relaxation method. Magnetization measurements were carried out using the vibrating sample magnetometer (VSM) option in a Quantum Design PPMS.

First-principles electronic structure calculations

The electronic structures of EuCd2As2 under pressure were calculated from first principles using density functional theory (DFT). The DFT calculations were performed using the plane-wave projected augmented wave method as implemented in the VASP code45,46. The Perdew, Burke and Ernzerho parameterization (PBE) of the general gradient approximation (GGA) was used for the exchange-correlation functionals47. The plane-wave basis energy cut-off was set to 480 eV, and a 12 × 12 × 4 Γ-centered k-mesh was used to perform integration over the Brillouin zone. An additional on-site Coloumb interaction of U = 6 eV was included for the Eu-4f orbitals in the LDA+U calculations. Both the lattice constants and the atomic internal coordinates were optimized for all magnetic configurations, so that forces on each atom were smaller than 0.01 eV/Å. The band structures from VASP were fit to tight-binding Hamiltonians using the maximally projected Wannier function method. The resulting tight-binding Wannier-orbital-based Hamiltonians were used to calculate the corresponding surface states48 and analyze their electronic topology with the WannierTools package49.