Abstract
Linear magnetoresistance (LMR) is a special case of a magnetic-field induced resistivity response, which has been reported in highly disordered semiconductor systems and in topological materials. In this work, we observe LMR effect in half-metallic perovskite Sr2CrMoO6 thin films, of which the maximum MR value exceeds +1600% at 2 K and 14 T. It is an unusual behavior in ferrimagnetic double perovskite material like Sr2CrMoO6, which are known for intrinsic tunneling-type negative magnetoresistance. In the thin films, the high carriers’ density (~1022 cm−3) and ultrahigh mobility (~104 cm2 V−1 s−1) provide a low-resistivity (~10 nΩ·cm) platform for spin-polarized current. Our DFT calculations and magnetic measurements further support the half-metal band structure. The LMR effect in Sr2CrMoO6 could possibly originate from transport behavior that is governed by the guiding center motion of cyclotron orbitals, where the magnetic domain structure possibly provides disordered potential. The ultrahigh mobility and LMR in this system could broaden the applications of perovskites, and introduce more research on metallic oxide ferri-/ferro-magnetic materials.
Similar content being viewed by others
Introduction
Magnetoresistance (MR) is the responding of resistance of a conductor to external magnetic field, which describes the charge carriers’ scattering mechanism. In a typical metal with closed Fermi surface, the MR is parabolic-like in low magnetic field region and turns to saturation (usually several or tens of percent) in strong field limits, which, in contrast, never saturates to metal with open Fermi surfaces. Special cases appear in compensated semimetals like Bismuth or compounds like WTe21 and NbSb22,3 which possess both electron and hole pockets at Fermi surface, and the carrier densities are of similar value, giving rise to a giant parabolic-like MR that is always present (reaching millions of percent at ~10T), without a sign of saturation even at 60 T field. Another important MR behavior shows linear magnetic-field-dependence of resistance with no saturation (LMR), which has been found in highly disordered system such as InSb4, Ag2-δX (X = Se, Te)4,5,6, topological insulators, Bi2Te3 family7, Dirac or Weyl semimetals TlBiSSe8, TaAs9, Na3Bi10, Cd2As311,12. Recently, LMR has also been reported in perovskite material SrRuO3 thin films, which is a ferromagnetic Weyl semimetal13. Although the phenomenon of LMR is quite straightforward, the mechanism or explanation is complicated and has attracted increasing study in the past decade.
To further discuss the LMR effect, we should revisit some general ideas about MR. In a condensed Fermi gas system with approximately spherical Fermi surface system, the electrons travel in straight lines between collisions, and the resistivity obeys the famous formula: \(\rho _0 = m^ \ast\! /\!ne^2\tau\), in which e is the charge of an electron, n is the electron’s density, m* is the effective mass, and τ is the relaxation time. With an applied magnetic field B, the Lorentz force \(e{\boldsymbol{v}} \times {\boldsymbol{B}}\) bends the path of electrons, resulting in an additional angular velocity \(\omega _c = eB/m^ \ast .\) It means that the angle turned between collisions is \(\omega _c\tau = B\sigma _0/ne\), and unless ωcτ > 1, no obvious MR effect is expected. With a large enough magnetic field applied (ωcτ >> 1), the electron trajectories can be described in the combination of fast cyclotron orbit motion r(t), and slow guiding-center (GC) motion R(t). The cyclotron motion r(t) with the characteristic radius \(r_c\), depends on materials’ fermiology and B, whereas the GC motion R(t) depends on the potential of the electron over one cycle14. In a material with slowly varying disorder potentials (the potential disorder correlation length ξ >> \(r_c\)), electron trajectories are dominated by the GC motion, which follows the local disorder landscape. In this case, MR is dominated by the GC motion and shows linear dependence on the magnetic field above the turn-on magnetic field7.
In metals with long-range ferro-/ferri-magnetic ordering, intrinsic tunneling-type negative magnetoresistance (TMR) is usually observed, e.g., in Fe3O415, Tl2Mn2O716, and La2/3Sr1/3MnO317. Similarly, the double perovskite A2BB’O6 family (A = Ca, Sr, and Ba; B = Cr, Mn, Fe, Co, and Ni, B′ = Mo, W, Re, Ru, Os, Rh, Ir) is also famous for offering high magnetic ordering temperatures (>400 K) and large negative MR values18,19,20,21,22,23,24, e.g., Sr2FeMoO6 is known for its room-temperature TMR of ~−10%19. In this work, we observe unconventional positive LMR effect in epitaxial Sr2CrMoO6 (SCMO) thin films on SrTiO3 (STO) substrates at low temperatures, which may attract further study of double perovskite of this family. The positive LMR is usually related to high mobility Dirac materials, and attracts wide transport, photoemission, and scanning tunneling microscopy/spectrum studies. We propose that the LMR effect in SCMO may originate from the GC motion dominant transport, where the magnetic domain structures provide the slow-varying disordered potential.
Results and discussion
Structural properties
Since the electronic transport properties of thin films are highly dependent on the crystallization quality of thin films, we conducted a series of measurements to demonstrate the excellent quality of SCMO thin films. The deposition condition was already optimized in the previous steps, leaving the deposition time as the only variable in the thin-film samples, which are: S1, 2.5 min, ~6 nm; S2, 5 min, ~12 nm; S3, 10 min, ~24 nm; S4, 20 min, ~48 nm; S5 30 min, ~72 nm; S6, 45 min, ~108 nm; and S7, 90 min ~216 nm. As an example, the crystallization quality of S5 characterizations through X-ray based technique and HRTEM are shown in Fig. 1a–f. In the XRD θ−2θ scan, the sharp cubic SCMO (004) peak locates on the shoulder of the STO (002) peak (Fig. 1a), the full width at half-maximum (FWHM) value of which is only 0.048° according to the rocking curve scan, as shown in the upper inset of Fig. 1a, which suggests high crystalline quality of this sample. The sharp diffraction peaks of other samples are shown in Supplementary Fig. S1a. The FWHM values of all samples are within 0.09°, which decreases with the increase of deposition time (in below 45 min regime), suggesting the increasing thin film crystallization quality in thicker samples within 108 nm region, as demonstrated in Fig. S1c. XRD phi scan patterns, as shown in the lower inset of Fig. 1a, show that the SCMO film grows epitaxially on the STO substrate. Further, the XRD intensity reciprocal space mapping is plotted in Fig. 1b in the −1.7 Å−1 < qx < −1.5 Å−1, and 4.55 Å−1 < qy < 5.05 Å−1 regions, in which one can observe two peaks indexed by STO (130) and SCMO (260). The sharp SCMO XRD peak suggests the nearly perfect atomic layout in our sample. The XRD results of all samples are listed in Supplementary Fig. S1, in which one may notice that the SCMO (004) peaks’ positions shift to higher angle in thinner samples, suggesting the strain effect in those thin films. To study the strain effect, we carefully fitted the diffraction patterns near 2θ = 46 ° with two Gaussian peaks. The obtained peak positions are summarized in Fig. S1c, in which one can see the SCMO (004) peaks are at the same position in 48–216 nm thin films. Therefore, we argue that the transport behavior in thin films above 48 nm thickness are less affected by the interfacial strain effect. We further zoom-in to the atomic view employing the HRTEM equipment, shown in Fig. 1c–f. In the low-resolution image (Fig. 1d), the thin film is sandwiched by STO substrate and amorphous glue, the interfaces of which are atomically smooth (Fig. 1c), indicated by the yellow lines. The high-resolution images near the substrate cross-section are shown in Fig. 1c, in which the coherent STO-SCMO interface is evidence of the high quality of epitaxial thin film of our sample. Since the cubic SCMO possesses a lattice constant of 7.865 Å which is slightly larger than two of STO lattice constants (2 × 3.905 Å = 7.810 Å), one can see lattice compressive distortion, which tends to relax quickly. Since the XRD and HRTEM provide evidence that the strained layers are negligible, they would not dominant the total transport or magnetic properties in our sample set. A zoomed-in bright field image of the SCMO atomic structure is shown in Fig. 1e, in which we superimposed three SCMO unit cells along (001) direction, to show the stacking of the atoms. The selected area electron diffraction (SAED) pattern of SCMO sample is demonstrated in Fig. 1f, in which the sharpest spots are indexed in \(F_{m\bar 3m}\) space group. The XRD and HRTEM results demonstrate the excellent quality of the epitaxial SCMO thin films, supporting the further magnetic and transport measurements. Another evidence of the film quality is the nano-/sub-nano magnitude of surface mean square roughness, which is shown in Supplementary Fig. S2 and Supplementary Table S1.
Electronic transport properties
The temperature and magnetic field-dependent resistivity curves were measured by four-parallel electrodes configuration, as sketched in the inset of Fig. 2a, where the applied transverse magnetic fields are in the thin-film plane, and perpendicular to the current (T configuration). Another two measurement configurations were also applied to measure all samples, which are: the in-plane magnetic field parallel to the current (P configuration), and the out-of-plane vertical magnetic field parallel to the normal vector of the thin film (V configuration). At zero field, the temperature-dependent resistivity (T) of S5 behaves as a good metal, with 2K = 52 nΩ·cm and 300K = 65.9 μΩ·cm, as shown in Fig. 2a. The resistivity is comparable to half-metallic Sr2CrWO6, e.g., 2K = 4.9–92 nΩ·cm and 300K = 95–370 μΩ·cm for 12–48 nm thin films on STO substrates, as well as the residual resistivity ratio (RRR), i.e., RRR(S5) = 1267, and RRR(Sr2CrWO6) = 2444–19,38725. The zero-field T curve below 175 K can be quite well fitted using the equation \(\rho(T) =\rho_0 + AT^n\) (Fig. 2a), where ρ0 is the residual resistivity, A is a constant, and n is the parameter indicating scattering mechanisms. The obtained residual resistivity ρ0 = 20 nΩ·cm, and n = 2.7 is close to that of the topological semimetal single crystals, e.g., n ~ 3 for Cd3As226 and ZrSiS family27,28. This type of temperature dependence of resistivity, deviating from the pure electronic correlation-dominated scattering mechanism (n = 2), can be attributed to the interband electron-phonon scattering28. In Fig. 2b, for thinner films (6–24 nm), the resistivity increases with film thickness, however, the thickness dependent behavior vanishes for 48–216 nm thin films. Based on the XRD pattern fittings, one can see that for the 6–24 nm thin films, the interfacial strain effect is more pronounced. Therefore, we deduce that the carriers’ density (Fig. 3a) and conductivity are positively related to the interfacial strain. For thin films with thickness above 48 nm, the interfacial strain is relaxed, and the resistivity show less thickness dependence.
The Hall effect was measured for S1–S7, to characterize the carrier properties of the SCMO samples. The total Hall effect shows linear-like decreasing curves, which corresponds to an n-type conductor contributing electron carriers, as shown in Fig. S13. From the Hall effect curves, we can calculate the Hall coefficient \(R_H\), and thus obtain the carrier density via \(n_H = 1/R_He\) (e is the charge of an electron) and Hall mobility \(\mu_H = \sigma R_H\) (σ is the conductivity), which are shown in Fig. 3a, b. The carrier density \(n_H\) of all samples are in 1021–1022 cm−3 range, and for each sample, \(n_H\) increases monotonically during heating. Due to the half-metallic band structure, which will be further discussed below, the carriers in SCMO are fully spin polarized. The combination of fully spin polarization, high \(n_H\) and high \(\mu_H\) is rare in metallic materials, which paves an avenue to low-dissipation spintronic devices. Unlike a typical metal, the carriers’ mobility is much higher at low temperatures (103–104 cm2/Vs), which decreases with heating dramatically. One can estimate the mean free path \(l_e = \frac{{\hbar \sqrt {2\pi n} }}{e}\mu\), where n = \(n_H\) is the carrier’s area density, μ = \(\mu_H\) is the carrier’s mobility, \(e\) is the charge of electron, e.g., le (S5_2 K) = 4.3 μm. The carrier density, Hall mobility and mean free path for S1–S7 at 2 K are listed in Table 1.
With transverse applied magnetic fields, the resistivity shows an upturn below 10 K as shown in the inset of Fig. 2a, which is similar to topological semimetals. There are several models related to magnetic induced resistivity upturn effect, e.g., Tafti et al.29 attributed the upturn in LaSb single crystal to magnetic-field-induced gap opening, on the contrary, Jo et al.30 provided enough evidence to verify the absence of gap opening during the upturn and simply employed Kohler’s scaling rule to explain this phenomenon in PtSn4. In order to further investigate this upturn effect, we conducted magnetic field-dependent resistivity (MR) measurements at various temperatures on S5, with a transverse magnetic field. As shown in Fig. 2b, the samples with different thicknesses show roughly similar zero-field RT behavior with S5, which only varies in resistivity values, (with applied magnetic fields, the resistivity upturn effect is universal in SCMO system, as shown in Supplementary Figs. S3–S9).
As shown in Fig. 2c, the (T configuration) MR values of S5 from 2 K to 100 K, up to 14 T, are in the positive region, unlike those tunneling-type negative MR in Sr2FeMoO619 and related double perovskites. In the present scale magnitude, one may notice that the MR curve at 2 K from 0 to ±14 T shows linearly increasing with the magnetic field, with no sign of saturation, and reached more than 1600% at ±14 T. The 14-T-MR value decreases dramatically during heating, which is ~ 1230% at 3 K, ~900% at 4 K, and only 200% at 10 K. As shown in Supplementary Fig. S11, the 14-T-MR values can be roughly fitted in an inverse proportional function, which is quite different from the behavior in topological semimetals, e.g., 14-T-MR of ZrGeSe are nearly constant below ~20 K region27. Another inversely-proportional feature can be found in the Hall mobility \(\mu_H\), which is also demonstrated in Supplementary Fig. S11. In topological semimetals, the low-temperature resistivity form plateaus without and with magnetic fields1,2,3,27,28, where the resistivity values only change with the magnetic fields. However in SCMO, the resistivity changes with the temperature significantly, similar to the situation in Sr2CrWO625. With further heating, the MR values decrease monotonically, reaching only a few percent at 100 K. The LMR was also observed in other measuring configurations, either with parallel magnetic fields (P configuration), or vertical magnetic fields (V configuration), as shown in Supplementary Fig. S7, in which the main features are consistent: (1) linear, or quasi-linear field-dependent behavior is dominant in high fields and low temperatures; (2) MR values at 14 T decreases fast with heating due to the mobility cascading, which are neglectable at ~ 100 K. The MR behavior among configurations are slightly different, e.g., 1620, 1380 and 1670% for T, P and V configurations (at 2 K and 14 T) respectively.
As abovementioned, the LMR is quite rare in solids, only observed in inhomogeneous systems, or in some high mobility topological materials. Since the XRD results and HRTEM images demonstrate the high quality of thin films, and there is no evidence relating the band structure to topology, the origin of this surprising LMR effect in SCMO may trigger everyone’s curiosity. First of all, one may notice that the thin films were deposited in high temperature and high vacuum condition, which induces oxygen vacancies in both SCMO films and STO substrates. Owing to the intrinsic metallic nature of SCMO, and intrinsic insulating nature to STO, oxygen vacancies behave differently in thin film and substrate. With increasing oxygen vacancy level, the defect scattering of electrons becomes significant, which can even tune the transport behavior to semiconducting in some perovskites25. Therefore, the high conductivity of SCMO is a good evidence that the oxygen vacancy level is low enough to present quite limited effects on the whole picture of transport behavior. On the other hand, the oxygen vacancy level can tune the STO to conducting. Thus, a control set of the sample S0 was employed during the fabrication of S5, in which we set a mask between the substrate and target. As shown in Supplementary Fig. S10, the pure STO substrate treated with high temperature at high vacuum (same conditions as S5) exhibits resistivity of ~2 kΩ magnitude, and neglectable MR.
Since the high uniformity of the SCMO thin films is verified by XRD and HRTEM, the model of heavily disordered semiconductors4,31 is not suitable for this case. The high carriers’ concentration of SCMO thin films, as well as the DFT calculations, suggests that the Fermi pockets are too large for 14 T field to quantize carriers into zeroth Landau Level, therefore the quantum MR model is not applicable for SCMO either32. LMR also been reported in 2D electron gas system, which originates from the giant Hall effect contributing to longitudinal MR due to the carrier density fluctuation33. However, in SCMO, the Hall effect is weaker than longitudinal MR, which means the carrier density fluctuation induced Hall effect component only have limited contribution to MR behavior. Note that the LMR effect in ferromagnetic SrRuO3 thin films are dominated by linear dispersed Weyl bands, similar to other topological materials13. Therefore, it is reasonable to deduce that the LMR behavior in SCMO is similar to the topological insulators TlBiSeS8 or Dirac semimetals Cd3As2:11,12 GC motion dominant behavior. In Cd3As2 single crystal, LMR arises because the local current density acquires spatial fluctuations in both magnitude and direction, as a result of the heterogeneity or microstructure caused by nonhomogeneous carrier and mobility distribution. The GC motion is perpendicular to cycloid motion in the magnetic fields, due to the effects of the electric field. During GC motion across low-mobility islands, multiple small-angle scattering occurs and thus the LMR effect can be observed. In this model, the conductor should be in three dimensional to allow electrons moving in z direction. There’s a crossover effect within this model, which is, the resistivity increases parabolically with field in low-field regime (below the critical value: \(B_L\)), and LMR is only observed when magnetic field is sufficiently large (\(B \!>\! B_L\))11,14. We thus carefully conducted low-field MR measurements with small steps on S5 below 10 K, as shown in Fig. 2d. One may notice that, in low-field region, the MR curves increase quasi-parabolically with the magnetic field to \(B_L\), and further increase linearly, which exactly fits to the GC motion model. In the GC model explained by Song et al.14 a feature of GC motion governed LMR is that the MR can be described in Kohler’s rule since it scales with mobility. We employ Kohler’s plot here at high magnetic field regime (Fig. 2e) and low-field regime (Fig. 2f), with different scaling rule, e.g., due to the Hall angle difference (Supplementary Fig. S12), Fig. 2e is scaled with resistivity, mobility, and Hall angle, whereas Fig. 2f is directly scaled with resistivity. In low-field and high field limit, the data coincide with each other quite well, which suggests the different scattering mechanisms above and below \(B_L\). The crossover effect is a signature of GC motion dominant MR behavior, which can be found in all LMR curves in SCMO.
The similar linear or quasi-linear MR can be found in S1–S7 series SCMO samples, including the thin-limit (6 nm) sample, as shown in Supplementary figs. S3–S9. Since the thin films crystallize in a cubic lattice with a normal vector of (001), there should be less anisotropy intrinsically within- and out-of-thin film plane. It is obvious that the MR originates from Lorenz force, which results in greater MR for magnetic field-perpendicular-to-current configurations (T and V). Moreover, the thin film shape favors cyclotron orbits with angular moment parallel to the normal vector, meanwhile the perpendicular orbits suffer more from surface scattering. The abovementioned effect could be more obvious in thin-limit samples, e.g., in S1–S3, the 2 K and 14 T T- and V-MR values are at least twice larger than P-MR value.
Magnetic properties
Since the ground state of SCMO is half-metallic, the carriers are fully spin-polarized, and effectively scattered by the magnetic domain structure, the magnetic properties are important to the LMR effect. To directly test this, we conducted the temperature and magnetic field dependent magnetization measurements of SCMO thin film S5 . We measured the hysteresis loops at various temperatures from 3 K to 380 K within and perpendicular to the thin film plane, which are shown in Fig. 4a, b. Please notice that the moment is obtained via subtracting a linear diamagnetic component contributed by STO substrate. The moment was converted from the total magnetization to Bohr magneton per formula unit. The in-plane saturation moment at 2 K is ~0.5 µB/f.u., which slightly increases to ~0.7 µB/f.u. at 3 K, and then decreases to ~0.65 µB/f.u. at 10 K, and 0.6 µB/f.u. at 20 K. With the magnetic field perpendicular to the film plane, the saturation moment is ~1.45 µB/f.u. at 2 K, and decreases to ~0.25 µB/f.u. at 380 K. This is, however, less than expected for a fully aligned Cr3+ (3 µB) and Mo5+ (1 µB), which would be ~2 µB for an antiferromagnetic collinearly-aligned Cr3+-Mo5+ spin dimer. One may note that, the saturation moment changes with temperature drastically in 2–380 K regime, which is unusual in a ferrimagnet ordered at high temperatures (above 400 K). To solve this question, direct measurement of the magnetic moment via neutron scattering or X-ray magnetic circular dichroism is desired. Further, we measured the temperature-dependent magnetization curves in both zero-field-cooling (ZFC) and field-cooling with data collected on warming (FCW) procedures between 3 and 380 K. After subtracting the temperature-dependent diamagnetic background obtained from MH loop subtraction, the temperature-dependent magnetic moments of pure SCMO thin film are shown in the Fig. 4c, with 100 and 1000 Oe applied magnetic field. One can see the clear difference of the ZFC & FCW curves in the 1000 Oe out-of-plane curves, indicating a slight history-dependence of the magnetization, which is a hallmark of a magnetically ordered state. Similar behaviors can be found in other measurements, however, only ZFC curves are present to make the graph clear enough to read. The ferrimagnetic transition temperature \(T_C\) of SCMO is ~450 K34, which indicates all the transport and magnetic measurements are in ferrimagnetic ordering regime. We note that the domain structures of ferro-/ferri-magnetic thin films observed at low temperatures are well studied, e.g., yttrium iron garnet (YIG) films show long tail stripes domain structure below \(T_C\), which is still clear at low temperatures35. Therefore, we believe that the domain structure exists in SCMO thin films at low temperature, and contributes to the carrier scattering process. One interesting point is, the MT curves show upturn below ~20 K, which indicates the larger moment of SCMO, together with the high mobility and large MR values. In the high mobility regime, \(\omega_c > > 1\) and carriers’ trajectories are dominated by GC motions. During the GC drifts from one magnetic domain to another, the spin–spin interaction may occur at the domain wall, which scatters the carriers. Thus, the GC motion would undergo backscattering or small-angle grazing near the domain wall, similar to the GC motion picture through mobility fluctuation area in Cd3As211,14. It should be noted that the LMR effect of metallic ferromagnetic system has been observed in Cr/Ag/Cr sandwich structure36 and LaMn2Ge2 polycrystals37. The LMR effect in SCMO would be an intrinsic property to half-metallic/ferromagnetic-metallic systems, which broadens the LMR research, as well as its application in more material systems.
Theoretical calculations
To verify that the observed magnetic properties are consistent with the half-metallic double perovskite phase, ab initio calculations were performed. Figure 5a shows the idealized crystals structure after atomic relaxation with perfect superlattice formed by alternating Mo/Cr sites. The direction and magnitude of the magnetic moments are shown by the vectors in the structure. The magnetic moments in this configuration were found to arrange in a simple G-type ferrimagnetic ground state with Cr (2.24 µB) and Mo (0.43 µB) giving a net moment of 1.86 µB in reasonable agreement with experiment. The small mismatch between the experimental data and theory may be attributed to the role of a small number of anti-site defects (where Cr and Mo mix on their various sites) which can reduce the net moment in a ferrimagnet double perovskite38,39. The anti-site defects could also lead to disorder-induced positive MR, and therefore contribute to total magnetotransport behavior. Figure 5b, c show the corresponding band-structure and spin-polarized density of states respectively. One of the spin-states is gapped, whereas the other shows states at the Fermi level – a characteristic of a half-metal. Examination of the projected density of states reveals that the states near the Fermi level are almost entirely formed by Mo-3d states, and the splitting thereof is therefore caused by the onsite exchange interaction. Calculations including the spin–orbit interaction show that this well-defined splitting between the spin-states is preserved, as expected given the relatively weak atomic spin–orbit interaction of Mo and thus the half metallicity is robust. The unusual band structure gives rise to an electron parabolic band at Γ that coexists with a hole band at W. The latter band has a linear dispersion, and identical Dirac-line feature is observed in the exchange split band for spin-down states below the Fermi level. The Dirac-feature bands may contribute to the high mobility of SCMO, which ensures cyclotron motion dominating magnetotransport behavior at experimentally achieved magnetic fields. This is an important point of observing LMR effect in SCMO thin films.
In summary, various SCMO thin films with different thicknesses were deposited on STO single-crystal substrates. The crystallization quality is excellent, which is evidenced by XRD and HRTEM. DFT calculations suggest that the cubic double perovskite SCMO is a half metal, with intrinsically antiparallel coupled Cr3+ and Mo3+ moments, which agrees well with the magnetization measurements. Magnetization measurements of SCMO thin films presented nearly-neglectable-coercivity MH curves, with out-of-plane saturation moments of ~1.45 µB/f.u. at 2 K, which is close to the DFT calculated 1.86 µB/f.u. with ferrimagnetic coupling. SCMO possesses nΩ·cm magnitude resistivity and ultrahigh mobility (104 cm2 V−1 s−1) in all half metals, which provides a platform for low-dispassion fully spin-polarized current. In cryogenic temperatures, SCMO exhibits LMR behavior, which is probably contributed by the GC motion across magnetic domain. Our DFT calculations further show Dirac-like bands near the Fermi level, which could be a good reason of the high mobility in SCMO. The unusual behavior in SCMO expands giant positive linear magnetoresistance research in oxide materials, which will attract more fundamental and application research in double perovskite systems.
Methods
Preparation of Sr2CrMoO6 ceramic target
A ceramic target with nominal composition of Sr2CrMoO6 was prepared by the conventional solid-state reaction method using stoichiometric Sr (SrCO3 (99.95%)), Cr (Cr2O3(99.95%)), and Mo (MoO3 (99.95%)) as starting materials. The starting materials are well mixed via ball milling for 20 h and sintered at 950 °C for 12 h to complete the chemical reaction. The obtained polycrystal sample was further grounded into a fine powder via 20 h ball milling, and cold-pressed into a pellet. The pellet was sintered at 1100 °C for 12 h to obtain the ceramic target with a diameter of 25 mm.
Thin film growth
Pulsed laser deposition (PLD) apparatus equipped with a KrF (λ = 248 nm) excimer laser was employed to grow Sr2CrMoO6 (SCMO) thin films on one-side polished (001)-oriented SrTiO3 (STO) single-crystal substrates. Since the target and thin film are in different chemical composition, the high-vacuum condition is necessary to guarantee low-oxygen thin film deposition. Before deposition, the chamber has been pumped into high vacuum with a pressure of 5.0 × 10−5 Pa. The deposition process has been carried out at 5.0 × 10−5 Pa for 2.5–90 min for different samples with a substrate temperature of 775 °C, followed by in-situ annealing for 30 min. Then the film has been cooled down to room temperature at a rate of 10 °C min−1. The distance between the target and the substrate was set as 5 cm. The laser energy density and repetition rate are 1 J/cm2 and 2 Hz, respectively. The film thickness is controlled by the number of laser pulses.
Structural characterization
The structural crystallization of SCMO thin film has been characterized via X-ray diffraction (XRD) rocking curve, θ–2θ and φ-scans, and reciprocal space mapping using an x-ray diffractometer (PANalytical X’Pert MRD) equipped with Cu Kα1 radiation (λ = 1.5406 Å). Cross-section microscopic structural properties have been characterized via high-resolution transmission electron microscopy (HRTEM) images and selected area electron diffraction (SAED) using a Tecnai G2F20 S-Twin transmission electron microscope. Sample for HRTEM measurements was cut into lamellas by Focused Ion Beam (Scios 2 HiVac, Thermo Fisher).
Electronic transport measurements
Ohmic contacts were employed on the silver-patterned thin film surface with four-parallel electrodes configurations to conduct the magnetotransport measurements up to 14 T in a physical property measurement system (PPMS-14, Quantum Design). Hall measurements were performed via the Van de Pauw configuration using PPMS. The magnetic properties are measured using the SQUID magnetometer up to 7 T (MPMS3, Quantum Design).
Computational calculation methods
Electronic structure calculations were performed using density functional theory (DFT) in the Vienna Ab Initio Simulation Package (VASP)40,41,42. The exchange-correlation energy was described using the generalized-gradient approximation described by Perdew et al. (GGA-PBE)43. The projector augmented-wave method was used to represent the ionic cores40,41,42, and the number of valence electrons in the atomic electronic state of Sr, Cr, Mo, and O were 10, 12, 14, and 6 respectively. Wave functions were presented in a plane-wave basis and the cut-off energy was 500 eV. Structural data taken from Parish et al.4 (ref. 44) was used as the input, and initially, the system was assumed to exhibit perfect structural order on the Cr/Mo sites to give an ideal double perovskite in the \(F_{m\bar 3m}\) space group. Ionic and cell relaxation was performed until the forces converged to beneath 0.01 eV/Å. A gamma-centered 8 × 8 × 8 k-mesh was used for the density of states calculation, and the eigenvalues were calculated along a standard k-path through the Brillouin zone for the band structure calculations.
Data availability
The authors declare that the data supporting the findings of this study are available within the article and its Supplementary Information files.
References
Ali, M. N. et al. Large, non-saturating magnetoresistance in WTe2. Nature 514, 205–208 (2014).
Wang, K., Graf, D., Li, L., Wang, L. & Petrovic, C. Anisotropic giant magnetoresistance in NbSb2. Sci. Rep. 4, 7328 (2014).
Guo, L. et al. Extreme magnetoresistance and SdH oscillation in compensated semimetals of NbSb2 single crystals. J. Appl. Phys. 123, 155103 (2018).
Parish, M. M. & Littlewood, P. B. Non-saturating magnetoresistance in heavily disordered semiconductors. Nature 426, 162–165 (2003).
Xu, R. et al. Large magnetoresistance in non-magnetic silver chalcogenides. Nature 390, 57–60 (1997).
Lee, M., Rosenbaum, T. F., Saboungi, M.-L. & Schnyders, H. S. Band-gap tuning and linear magnetoresistance in the silver chalcogenides. Phys. Rev. Lett. 88, 066602 (2002).
Wang, X., Du, Y., Dou, S. & Zhang, C. Room temperature giant and linear magnetoresistance in topological insulator Bi2Te3 nanosheets. Phys. Rev. Lett. 108, 266806 (2012).
Novak et al. Large linear magnetoresistance in the Dirac semimetal TlBiSSe. Phys. Rev. B 91, 041203 (2015).
Huang, X. et al. Observation of the chiral-anomaly-induced negative magnetoresistance in 3D Weyl semimetal TaAs. Phys. Rev. X 5, 031023 (2015).
Xiong, J. et al. Anomalous conductivity tensor in the Dirac semimetal Na3Bi. EPL 114, 27002 (2016).
Narayanan, A. et al. Linear magnetoresistance caused by mobility fluctuations in n-doped Cd3As2. Phys. Rev. Lett. 114, 117201 (2015).
Feng, J. et al. Large linear magnetoresistance in Dirac semimetal Cd3As2 with Fermi surfaces close to the Dirac points. Phys. Rev. B 92, 081306 (2015).
Takiguchi, K. et al. Quantum transport evidence of Weyl fermions in an epitaxial ferromagnetic oxide. Nat. Commun. 11, 1–12 (2020).
Song, J. C. W., Refael, G. & Lee, P. A. Linear magnetoresistance in metals: guiding center diffusion in a smooth random potential. Phys. Rev. B 92, 180204 (2015).
Lee, S. et al. Electrically driven phase transition in magnetite nanostructures. Nat. Mater. 7, 130–133 (2008).
Shimakawa, Y. et al. Crystal structure, magnetic and transport properties, and electronic band structure of A2Mn2O7 pyrochlores, (A=Y, In, Lu and TI). Phys. Rev. B 59, 1249–1254 (1999).
Hwang, H. Y., Cheong, S. W., Ong, N. P. & Batlogg, B. Spin-polarized lntergrain tunneling in La2/3Sr1/3MnO3. Phys. Rev. Lett. 77, 2041–2044 (1996).
García-Hernández, M., Martínez, J. L., Martínez-Lope, M. J., Casais, M. T. & Alonso, J. A. Finding universal correlations between cationic disorder and low field magnetoresistance in FeMo double perovskite series. Phys. Rev. Lett. 86, 2443 (2001).
Kobayashi, K. I., Kimura, T., Sawada, H., Terakura, K. & Tokura, Y. Room-temperature magnetoresistance in an oxide material with an ordered double-perovskite structure. Nature 395, 677–680 (1998).
Kato, H. et al. Metallic ordered double-perovskite Sr2CrReO6 with maximal Curie temperature of 635 K. Appl. Phys. Lett. 81, 328–330 (2002).
Philipp, J. B. et al. Structural and doping effects in the half-metallic double perovskite A2CrWO6. Phys. Rev. B 68, 399–404 (2003).
Pardo, V. & Pickett, W. E. Compensated magnetism by design in double perovskite oxides. Phys. Rev. B 80, 054415 (2009).
Tomioka, Y. et al. Magnetic and electronic properties of a single crystal of ordered double perovskite Sr2FeMoO6. Phys. Rev. B 61, 422–427 (2000).
Kobayashi, K. I. et al. Intergrain tunneling magnetoresistance in polycrystals of the ordered double perovskite Sr2FeReO6. Phys. Rev. B 59, 11159 (1999).
Zhang, J. et al. Giant positive magnetoresistance in half-metallic double-perovskite Sr2CrWO6 thin films. Sci. Adv. 3, e1701473 (2017).
Tian, T. et al. Ultrahigh mobility and giant magnetoresistance in the Dirac semimetal Cd3As2. Nat. Mater. 14, 280–284 (2015).
Guo, L. et al. Electronic transport evidence for topological nodal-line semimetals of ZrGeSe single crystals. ACS Appl. Electron. Mater. 1, 869–876 (2019).
Singha, R., Pariari, A. K., Satpati, B. & Mandal, P. Large nonsaturating magnetoresistance and signature of nondegenerate Dirac nodes in ZrSiS. Proc. Natl Acad. Sci. USA 114, 2468–2473 (2017).
Tafti, F. F., Gibson, Q. D., Kushwaha, S. K., Haldolaarachchige, N. & Cava, R. J. Resistivity plateau and extreme magnetoresistance in LaSb. Nat. Phys. 12, 272–277 (2016).
Jo, N. H. et al. Extremely large magnetoresistance and Kohler’s rule in PdSn4: a complete study of thermodynamic, transport, and band-structure properties. Phys. Rev. B 96, 165145 (2017).
Jingshi, H. U. & Rosenbaum, T. F. Classical and quantum routes to linear magnetoresistance. Nat. Mater. 7, 697–700 (2008).
Abrikosov, A. A. Quantum magnetoresistance. Phys. Rev. B 58, 2788–2794 (1998).
Khouri, T. et al. Linear magnetoresistance in a quasifree two-dimensional electron gas in an ultrahigh mobility GaAs quantum well. Phys. Rev. Lett. 117, 256601 (2016).
Arulraj, A., Ramesha, K., Gopalakrishnan, J. & Rao, C. N. R. Magnetoresistance in the double perovskite Sr2CrMoO6. J. Solid State Chem. 155, 233–237 (2000).
Wang, R., Shang, Y. X., Wu, R., Yang, J. B. & Ji, Y. Evolution of magnetic domain structure in a YIG thin film. Chin. Phys. Lett. 33, 126–129 (2016).
Verbanck, G. et al. Large positive magnetoresistance in Cr/Ag/Cr trilayers. Appl. Phys. Lett. 70, 1477–1479 (1997).
Mallik, R., Sampathkumaran, E. V. & Paulose, P. L. Large positive magnetoresistance at low temperatures in a ferromagnetic natural multilayer, LaMn2Ge2. Appl. Phys. Lett. 71, 2385–2387 (1997).
Bertinshaw, J. et al. Spin-cycloid instability as the origin of weak ferromagnetism in the disordered perovskite Bi0.8La0.2Fe0.5Mn0.5O3. Phys. Rev. B 89, 144422 (2014).
McBride, B. R. et al. Study of the B-site ion behaviour in the multiferroic perovskite bismuth iron chromium oxide. J. Appl. Phys. 123, 154104 (2018).
Kresse, G. G. & Furthmüller, J. J. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys. Rev. B 54, 11169–11186 (1996).
Kresse, G. & Furthmüller, J. Efficiency of ab-initio total energy calculations for metals and semiconductors using a plane-wave basis set. Comput. Mater. sci. 6, 15–50 (1996).
Kresse, G. & Hafner, J. Ab initio molecular dynamics for liquid metals. Phys. Rev. B 47, 558 (1993).
Perdew, J. P., Burke, K. & Ernzerhof, M. Generalized gradient approximation made simple. Phys. Rev. lett. 77, 3865–3868 (1996).
Blasco, J., Ritter, C., Rodríguez-Velamazán, J. A. & Herrero-Martín, J. Electron doping versus antisite defects: Structural and magnetic properties of Sr2-xLaxCrMoO6 and Sr2−xLaxCr1+x/2Mo1−x/2O6 perovskites. Solid State Sci. 12, 750–758 (2010).
Acknowledgements
We are very grateful to Dr. Kirrily Rule for valuable discussions. This work is supported by National Natural Science Foundation of China (grant no. 11974155) and ARC Centre of Excellence in Future Low-Energy Electronic Technologies (CE170100039). Support from Jiangxi Key Laboratory for Two-Dimensional Materials is also acknowledged.
Author information
Authors and Affiliations
Contributions
R.K.Z. and W.Z. conceived the idea and supervised the research. Z.C.W. prepared thin films. Z.C.W. and S.S.L conducted electronic transport and AFM measurements. L.C. contributed to the data analyses. G.Y.G. and J.S.Y. performed XRD and TEM measurements. F.T. and Y.F. conducted magnetic measurements. D.C. performed DFT calculations and analyzed computational data. X.W. contributed to the discussion of the results. Z.C.W., W.Z., and R.K.Z. wrote the manuscript. All authors contributed to the discussion of the results and the revision of the manuscript.
Corresponding authors
Ethics declarations
Competing interests
The authors declare no competing interests.
Additional information
Publisher’s note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary information
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons license, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons license and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Wang, ZC., Chen, L., Li, SS. et al. Giant linear magnetoresistance in half-metallic Sr2CrMoO6 thin films. npj Quantum Mater. 6, 53 (2021). https://doi.org/10.1038/s41535-021-00354-1
Received:
Accepted:
Published:
DOI: https://doi.org/10.1038/s41535-021-00354-1
- Springer Nature Limited
This article is cited by
-
High valley-degeneracy electron gas at double perovskite - strontium titanate interface
Communications Physics (2024)