Abstract
A current of electrons traversing a landscape of localized spins possessing non-coplanar magnetic order gains a geometrical (Berry) phase, which can lead to a Hall voltage independent of the spin–orbit coupling within the material—a geometrical Hall effect. Here we show that the highly correlated metal UCu5 possesses an unusually large controllable geometrical Hall effect at T<1.2 K due to its frustration-induced magnetic order. The magnitude of the Hall response exceeds 20% of the ν=1 quantum Hall effect per atomic layer, which translates into an effective magnetic field of several hundred Tesla acting on the electrons. The existence of such a large geometric Hall response in UCu5 opens a new field of enquiry into the importance of the role of frustration in highly correlated electron materials.
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Introduction
Frustration is prevalent in nature, appearing in substances as simple as water ice to systems as complex as neural networks1,2. In general, frustration is the result of competing interactions of comparable strengths that can prevent a system from entering a single macroscopic lowest-energy configuration. The geometry of certain material structures is particularly prone to frustration, with the resulting degenerate ground states or near-ground states being highly susceptible to small perturbations and the emergence of exotic states of matter1,2. For example, frustration imposed by the geometrical arrangement of magnetic moments in electrical insulators induces novel states, such as spin-liquid, multiferroicity and magnetic monopole excitations in spin ice1,2,3,4,5,6,7. The absence of itinerant charge and spin degrees of freedom in magnetically frustrated insulators simplifies theoretical modelling of the microscopic origin and consequences of that frustration, and consequently, most studies have focussed on non-metallic materials. Nevertheless, geometrical frustration of spin configurations also may have significant consequences for metals, especially in highly correlated materials with itinerant electrons strongly coupled to localized spins8. One of those possible consequences is the emergence of a highly tunable and very large response of itinerant charge carriers to an applied magnetic field.
In an ordinary metal, a Hall voltage VHall arises perpendicular to both the current I and applied magnetic field H, and is related to the transverse resistivity ρxy=VHall/I=R0H, where R0 is the Hall coefficient9. For a magnetic metal, however, scattering of itinerant electrons off of localized spins can produce additional contributions to ρxy, typically proportional to the magnetization M and powers of the longitudinal resistivity ρxx=Vxx/I, resulting in so-called anomalous Hall effects described by Karplus and Luttinger10 and skew-scattering theories9 that are discussed in the Supplementary Methods section in the Supplementary Information. In addition, if frustration were to induce spin order in a non-coplanar structure, then itinerant electrons traversing the spin texture with local spin chirality (Fig. 1a) accumulate a chirality-induced Berry phase that also contributes to VHall (refs 9,11,12,13). Theoretically, the effect of the spin texture on the current can reach the equivalent of a local magnetic field of H~104–5 T, which is at least two orders of magnitude larger than the highest field currently generated in high magnetic-field laboratories. Furthermore, if this local effective field does not average to zero over the sample, then the predicted Hall response can be as large as the integer quantum Hall effect in every atomic plane14,15,16,17. As the local spin chirality leading to such a large effective magnetic field and associated Hall response can be tuned by applying a much smaller external field, a clean example of such an effect would open a new direction towards designing functional materials with exotic properties and states.
The highly correlated Kondo lattice compound UCu5 is a heavy-fermion metal in which the coupling between its U 5f-electron spins and band electrons leads to a large electronic specific heat coefficient of γ~300 mJ mol K−2, corresponding to an effective mass of its itinerant electrons nearly two orders of magnitude larger than that of a free electron18. Its magnetic U ions sit on a face-centred cubic (FCC) lattice and form a network of edge-sharing tetrahedra—a geometry conducive to magnetic frustration1 (Fig. 1b). Curie–Weiss fits to the magnetic susceptibility give a Weiss temperature of θW=−284 K, which reflects the strong anti-ferromagnetic interactions between magnetic ions19. Yet, UCu5 orders magnetically at temperatures T≪θW, first at TN=15.5 K, and then at T2=1.2 K, due in part to magnetic frustration1,2. Powder neutron diffraction experiments indicate that the anti-ferromagnetic order in both phases consists of localized U 5f-electron spins pointing along the crystal unit cell's <111> directions with ordering wave vectors symmetry related to q=<1/2,1/2,1/2> (refs 20,21,22), and the simplest magnetic order consistent with these data is the 1–q configuration shown in Fig. 1c with spins ferromagnetically aligned within (111) planes, but anti-ferromagnetically aligned with neighbouring (111) planes. The magnitude of q does not change when cooling through T2, despite clear signs of a phase transition in magnetization, resistivity and specific heat data, indicating that the transition is likely between single and multi-q states possessing the same |q|. In the absence of single crystals of UCu5, it is impossible to distinguish a multi-domain 1−q configuration from more complex multi-q variants using powder neutron diffraction measurements. Nevertheless, nuclear magnetic resonance experiments have revealed significant differences in the distribution of the local exchange field acting on the nuclei, consistent with a transition between distinct states with different numbers of ordered Fourier components of magnetization23.
Here we report a strikingly large geometrical Hall effect below T2. On the basis of experimental results and theoretical analysis, we argue that the phase below T2 possesses the 4–q non-coplanar anti-ferromagnetic order, illustrated in Fig. 1d, which causes a chirality-induced Berry phase in the itinerant electrons' wave functions and creates a large geometrical Hall effect that can be controlled by applying a relatively small magnetic field.
Results
Magnetic phase diagram and maximum in the hall resistivity
The magnetic phase diagram for UCu5 is shown in Fig. 2a, and we refer to the high- and low-temperature anti-ferromagnetic phases as M1 and M2, respectively. The phase diagram is constructed from M(H) data discussed below, as well as data shown in Supplementary Figs S1-S7. M1 and M2 are phases possessing anti-ferromagnetic order, whereas PM is the paramagnetic phase. A Curie–Weiss fit to our susceptibility data is shown in Supplementary Fig. S2 and gives θW=−238(2) K, which is much greater than TN and agrees with previous results19.
The Hall resistivity ρxy(H) in both M1 and M2 is presented in Fig. 2b. Notably, in M2 ρxy(H) has a pronounced peak near H~2-2.5 T, and the corresponding Hall conductivity σxy=−ρxy/(ρxx2+ρxy2) is extremely large, exceeding 20% of the v=1 quantum Hall effect per atomic layer at H=2.5 T, which for free electrons with density of order one electron per unit cell would require H~103 T (ref. 24). In contrast, ρxy(H) in M1 is a simple monotonic function of magnetization, consistent with standard spin–orbit coupling-dependent anomalous Hall effect mechanisms, such as skew scattering9,10 (Supplementary Fig. S7). The solid lines in Fig. 2b are data from a second separately prepared UCu5 sample confirming the peak in ρxy(H) is intrinsic to M2.
Magnetization and magnetoresistance
To examine the possible mechanisms responsible for the observed maximum in the low-temperature Hall resistance, the field- and temperature-dependent Hall responses should be compared with M(H) and ρxx(H) for temperatures and fields spanning M1 and M2. Figure 3a is an image plot of M(H) in which different colours correspond to dM/dH and highlight the M1–M2 phase boundary. In M1, M(H) is linear for fields up to the M1–M2 phase boundary where there is a step increase. After the step, M(H) continues linearly in M2, but with a larger slope, and M(H) is linear in M2 for all temperatures and fields measured. Figure 3b shows that at T=1.4 and 1.8 K ρxx(H) exhibits a positive magnetoresistance in M1, with hysteresis occurring at the M1–M2 phase boundary. Once a high-enough field is reached to cross into M2, ρxx(H) has negative magnetoresistance in agreement with T=0.05–0.2 K data. T=1 K data show large hysteresis near the M1–M2 boundary, which is consistent with the previously reported sharp temperature–hysteretic peak at T2 in specific heat indicative of a first order transition18. ρxx(H) in M2 shows a difference between virgin and field-cycled curves, but no other hysteresis.
Ruling out conventional anomalous Hall effect mechanisms
The highly unconventional peak in ρxy(H) in M2 contrasts with the featureless behaviour of both ρxx(H) and M(H). At T<0.5 K, Fig. 3b shows that ρxx(H) is almost constant up to H=3T, even as a peak in ρxy(H) is reached at H~2–2.5 T. Similarly, in M2, M(H) is linear in H and does not show any anomalies around H~2–2.5 T. Therefore, in contrast to ρxy(H) in M1, the unusual behaviour of ρxy(H) in M2 is not dominated by the standard anomalous Hall effect due to the spin–orbit interaction. The differences in behaviour between ρxy(H) in the M1 and M2 phases is particularly clear in the derivative dσxy/dM (Supplementary Fig. S8a). In the low-field region of M2, the behaviour of σxy is highly unconventional with dσxy/dM changing sign with increasing H, and Supplementary Fig. S8b shows that the maximum in ρxy(H) cannot be fit assuming skew scattering alone. This is the regime in which a geometrical Hall effect due to the acquired chirality-induced Berry phase dominates.
Discussion
To demonstrate how a chirality-induced geometrical Hall effect arises due to the non-coplanar 4−q magnetic order, we analyse the properties of UCu5 within the Kondo lattice model (KLM) for an FCC lattice:
where σδ are the Pauli matrices, c is the annihilation operator for the itinerant electrons, <i, j> indicates nearest-neighbour U sites, t is the hopping matrix element for the current of itinerant electrons, and Sδ is the component of the U spin in the δ direction. The dynamical Kondo coupling JK gives the coupling strength between itinerant electrons and U spins, and is the origin of the large effective mass18. Here, we will concentrate on the magnetically ordered phases and assume that local moments are classical. Using a variational calculation24, we find that depending on JK and the carrier density of the current, n, both the 1−q and 4−q states, among others, can be stabilized at T=0. A typical parameter set to stabilize 4−q order is JK/t=3.5 with n=0.3 electrons per site. It is possible to study the thermodynamic phase transitions of the KLM directly24, but it is very computationally intensive. Therefore, for finite temperature calculations, we use a related classical spin model which gives the same result as the KLM at T=0,
Here, S is the spin of Uranium, J1 and J2 are the anti-ferromagnetic exchange coupling strengths between nearest and next-nearest neighbours, respectively, K is the nearest-neighbour biquadratic exchange strength, and the final term allows coupling to an applied magnetic field. For 2J2>J1 and K=0 the model yields a continuum of ground states due to magnetic frustration. Single spin-flip Monte-Carlo simulations using J1=1.5, J2=1 and K=0.01, which give the experimentally observed ratio of TN/T2, yield the H=0 specific heat curve shown in Fig. 4a. The simulations reproduce the two-phase transitions, with the lower-temperature phase possessing the 4−q order and the higher-temperature phase possessing the 1−q order (within the framework of these simulations, the transitions at T2 and TN appear to be first and second order, respectively, which is consistent with experiments; the order of the transitions, however, has not yet been confirmed with complete certainty due to computational limitations). The transition between M2 and M1 is driven by thermal fluctuations favouring the 1−q state, because the order-by-disorder mechanism stabilizes coplanar magnetic order at finite temperature for a frustrated FCC lattice25,26. We note that the analysis of the NMR data in ref. 23 gives M1 as the 4−q state and M2 as the 1−q state. However, the 4−q state is expected to be more energetically favourable than the 1−q state in Kondo-lattice systems. Indeed, a highly frustrated insulator Gd2Ti2O7 has been shown to have a 4−q ground state and a 1−q state at higher temperatures26. This trend also is consistent with general theoretical arguments that thermal fluctuations tend to stabilize the simpler magnetic configuration25. Moreover, ρxx(T) data for Lu0.02U0.98Cu5 shown in Supplementary Fig. S9 show an increase in T2 with non-magnetic dilution, which is also consistent with order-by-disorder. Figure 4b and c show snapshots taken during the simulations of the spin configurations in the 4−q and 1−q phases, respectively. In the KLM, we have treated the spins classically and have not assumed any spin–orbit coupling, which is the key ingredient in most anomalous Hall-effect theories, and has been shown to be important in explaining the Hall effect in Pr2Ir2O7 and Nd2Mo2O7 (ref. 27).
Unlike spins, the scalar-spin chirality does not couple directly to a magnetic field and is invariant to the rigid rotation of all the spins that can be induced by a rotation of an external magnetic field. Therefore, it may appear that the Hall effect attributable to the scalar spin chirality must average to zero for polycrystalline samples. The presence of itinerant electrons prevents this, because electrons moving in a chiral texture acquire orbital magnetization28 that directly couples to the magnetic field. For the experimental values of σxy calculated from data in Fig. 2b, the orbital magnetization per unit cell is estimated to be ~10−2 μB; therefore, at T~1 K, a magnetic field of only 1 Tesla should be sufficient to align even small domains containing 100 unit cells. Thus, the acquired orbital magnetization can produce an experimental signature of a large geometrical Hall effect, even in polycrystalline samples.
Given this coupling between the orbital magnetization and magnetic field, we calculate σxy(H) at T=0 by first choosing among the multiple energetically equivalent ground states of equation (2) with different values of the scalar spin chirality χ111 projected on to the [111] direction, which for the purpose of our calculations we assume to be parallel to H. We then select the state with the largest χ111 to give us an initial spin configuration as this state will be favoured by the coupling between the orbital magnetization and H. Fig. 5a shows χ111(H) and examples of the spin configurations for different H. Next, we substitute the determined spin configurations into equation (1) and use the Kubo formula29 to calculate the chirality-induced Berry phase contribution to σxy(H). Fig. 5b and c show the measured and calculated σxy(H) curves, respectively. Remarkably, both curves show a local minimum as a function of magnetic field and have comparable magnitudes, despite the simplistic way in which we have chosen the Hamiltonian parameters. Though qualitative in nature, these calculations demonstrate that the magnetic field distortion of the 4−q magnetic order can induce an extremely strong response in the Hall conductivity, comparable to experimental results, and illustrate the principle of generating large geometric Hall responses with a field due to a non-coplanar spin texture without assuming any material-specific spin–orbit interaction.
These results strongly suggest that the peak in ρxy(H) in the M2 phase is due to a chirality-induced Berry phase caused by the frustration-created spin texture. Although previous works on Nd2Mo2O7 and Pr2Ir2O7 have argued for observation of such a geometrical Hall effect12,13, it has been contested that in these cases, the Hall effect primarily stems from the magnetic Mo or Ir ions and is due to the d-orbital angular momentum induced by the spin–orbit interaction rather than being induced by the non-coplanar spin textures of the Nd or Pr27. In our case, Cu is not magnetic and the chirality-induced Berry phase is due to magnetic exchange between f and d electrons. Also, the Berry phase due to spin–orbital effects in the electronic band structure should be insensitive to small amounts of disorder. As we show in Supplementary Figs S9 and S10, and discuss in the Supplementary Methods section, Hall measurements on UCu5−x Mx, with M=Ag or Au and x=0.01, 0.03 (that is, 0.2 and 0.6% substitution) and U1−xLuxCu5, x=0.02 show that the peak in ρxy(H) is suppressed by small, nominally isoelectronic substitutions. These experiments rule against a notable contribution to the Berry phase from the spin–orbit induced momentum–space monopoles9 and demonstrate that the 4−q order in UCu5 is necessary for the observed geometrical Hall effect. Finally, a chirality-induced Berry phase effect also has been proposed to explain σxy in MnSi (refs 30,31) and MnGe32; however, in these cases, the induced Hall effect is orders of magnitude weaker than in UCu5 due to the very smooth nature of the Skyrmion33 textures.
We have shown that a tunable, unusually large Hall conductivity, equivalent to the presence of an effective magnetic field of ~103 T, arises in UCu5, and that the chirality-induced Berry phase due to frustration-induced non-coplanar 4−q anti-ferromagnetic order creates this large geometrical Hall effect. These results provide an example of the possible exotic transport properties resulting from magnetic frustration in highly correlated metals, whereas illustrating the opportunities afforded by pursuing studies on other frustrated metals. In particular, control of the geometrical Hall effect by a small magnetic field shows that frustration can be an important tuning parameter, allowing for the tailoring of specific properties and states of correlated matter.
Methods
Sample synthesis
Polycrystalline samples of UCu5.1 and UCu5.05 were prepared by arc melting on a water-cooled Cu hearth under an Ar atmosphere, followed by annealing under vacuum (10−4 Torr) at 800 or 850 °C for 1–3 weeks. Samples were determined to be single phase by X-ray diffraction, and we confirmed that both UCu5.1 and UCu5.05 share the same field-temperature phase diagram. Hence, for simplicity, we refer to both samples as UCu5. The UCu5−x Mx, M=Ag, Au, x=0.01, 0.03, and U0.98Lu0.02Cu5 samples were made in a similar fashion.
Magnetization measurements
Magnetization measurements were made in a Quantum Design Superconducting Quantum Interference Device magnetometer, in a dilution refrigerator utilizing either a capacitance-based Faraday or torque magnetometer, and in pulsed magnetic fields using a compensated coil-extraction magnetometer.
Resistivity measurements
Four-wire resistivity measurements of the longitudinal resistivity and Hall resistivity were performed on thin rectangular samples using a Linear Research LR-700 ac resistance bridge, and the samples were cooled and exposed to a magnetic field in a Quantum Design Physical Property Measurement System or a dilution refrigerator with an incorporated magnet. Pt leads were attached to the samples by either spot welding or by applying silver paint. Longitudinal contributions to the Hall resistivity were cancelled by making measurements in both positive and negative fields. High-field measurements were made at the National High Magnetic Field Laboratories in Tallahassee and Los Alamos.
Additional information
How to cite this article: Ueland, B.G. et al. Controllable chirality-induced geometrical Hall effect in a frustrated highly correlated metal. Nat. Commun. 3:1067 doi: 10.1038/ncomms2075 (2012).
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Acknowledgements
We thank C. Pfleiderer, C.D. Batista, V.S. Zapf, S. Brown, G. Koutroulakis and M.F. Hundley for discussions and assistance. Work at Los Alamos was performed under the auspices of the U.S. Department of Energy, and supported by the Laboratory Directed Research and Development programme. Z.F. acknowledges support from the National Science Foundation NSF-DMR-0801253. B.G.U. acknowledges support from the G.T. Seaborg Institute for Transactinium Science.
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P.H.T., M.A.T., Z.F. and E.D.B. made the samples. C.F.M., R.O., R.M., Z.F., O.A.-Y., R.D.M., F.R. and B.G.U. made resistivity and Hall measurements. J.D.T., C.F.M., R.O., R.M., O.A.-Y. and R.D.M. made magnetization measurements. O.A.–Y. and R.D.M. performed the high-magnetic field measurements. Y.K. and I.M. developed the theory and performed calculations. J.D.T. suggested the course of study. B.G.U. performed analysis and wrote the manuscript with editorial input from all of the authors.
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Supplementary Figures S1-S10, Supplementary Methods and Supplementary References (PDF 922 kb)
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Ueland, B., Miclea, C., Kato, Y. et al. Controllable chirality-induced geometrical Hall effect in a frustrated highly correlated metal. Nat Commun 3, 1067 (2012). https://doi.org/10.1038/ncomms2075
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DOI: https://doi.org/10.1038/ncomms2075
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