Warm a material and the electrons move randomly. Cool this material and the electrons follow patterns. Those patterns matter if you're designing super-efficient transmission power lines or ultra-powerful magnets. A crossover was predicted at the point where random motion, called incoherence in electronic excitations, becomes coherent waves. Exotic properties such as superconductivity are observed at these lower temperatures. For the first time, scientists validated this prediction with inelastic neutron scattering. Their experiments close the gap between what's seen and what's expected in terms of electron behavior.
Advances in neutron scattering and theoretical tools enabled detailed insights into strongly interacting electrons. Scientists need these insights. With them, they can predict useful behaviors and create new materials. Such materials could lead to novel memory, more efficient computing, and advanced sensors.
Strongly correlated electron systems have been studied for over five decades. Scientists predicted that at high temperatures, electrons in materials fluctuate in a random fashion. Upon cooling, the incoherent electronic fluctuations become coherent wave-like excitations. A quantitative understanding of the crossover from random to coherent electronic excitations is believed to be important to many phenomena in strongly correlated electron systems, including high-temperature superconductivity. Theory has long assumed a gradual loss of coherence with increasing temperature. Only recently has it become possible to perform realistic calculations to more completely include both strong local correlations and electronic band structures. These calculations combine density functional theory with dynamical mean field theory. Previous experiments could not verify the predicted loss because of the inherent limitations of the tools. Now, scientists have overcome these limitations with advancements in measuring inelastic neutron scattering at high flux sources. Neutron scattering data were collected from a cerium palladium compound over large volumes of momentum and energy transfer. The measured intensities showed strong momentum dependence due to the formation of coherent electron bands at low temperatures. The quantitative agreement between experiment and theory shows a robust understanding of the temperature dependence of this electron coherence. The research demonstrated how the latest advances in neutron scattering instrumentation enable quantitative comparisons with computational methods for calculating the behavior of strongly correlated electrons. This is vital for predicting emergent phenomena such as high-temperature superconductivity and colossal magnetoresistance with tremendous potential for applications and design of new materials.
Argonne National Laboratory
Argonne National Laboratory
Department of Energy (DOE), Office of Science, Basic Energy Sciences; Spallation Neutron Source, a DOE Office of Science user facility; Russian Foundation for Basic Research (Joint Institute for Nuclear Research); ISIS Pulsed Neutron Source in the United Kingdom; and Argonne National Laboratory (computing resources)
E.A. Goremychkin, H. Park, R. Osborn, S. Rosenkranz, J.P. Castellan, V.R. Fanelli, A.D. Christianson, M.B. Stone, E.D. Bauer, K.J. McClellan, D.D. Byler, and J.M. Lawrence, "Coherent band excitations in CePd3: A comparison of neutron scattering and ab initio theory." Science 359, 186 (2018). [DOI: 10.1126/science.aan0593]
Argonne National Laboratory article: Breaking bad metals with neutrons