Abstract
The behavior of matter near a quantum critical point is one of the most exciting and challenging areas of physics research. Emergent phenomena such as high-temperature superconductivity are linked to the proximity to a quantum critical point. Although significant progress has been made in understanding quantum critical behavior in some low dimensional magnetic insulators, the situation in metallic systems is much less clear. Here, we demonstrate that NiCoCrx single crystal alloys are remarkable model systems for investigating quantum critical point physics in a metallic environment. For NiCoCrx alloys with x ≈ 0.8, the critical exponents associated with a ferromagnetic quantum critical point are experimentally determined from low temperature magnetization and heat capacity measurements. All of the five exponents (γT ≈ 1/2, βT ≈ 1, δ ≈ 3/2, νzm ≈ 2, {bar {rm alpha}}T ≈ 0) are in remarkable agreement with predictions of Belitz–Kirkpatrick–Vojta theory in the asymptotic limit of high disorder. Using these critical exponents, excellent scaling of the magnetization data is demonstrated with no adjustable parameters. We also find a divergence of the magnetic Gruneisen parameter, consistent with a ferromagnetic quantum critical point. This work therefore demonstrates that entropy stabilized concentrated solid solutions represent a unique platform to study quantum critical behavior in a highly tunable class of materials.
Highlights
One key to making progress in this area is the identification of model material systems that are complex enough to exhibit the physics of interest but simple enough to be compared to theory
Ref. 19) indicating significant effects that are not captured by density functional theory. This deviation from theory and the observation of Tc → 0 K motivate a detailed characterization of the critical behavior and exponents for compositions near NiCoCr0.8
We have provided strong evidence that NiCoCr0.8 is close to a ferromagnetic quantum critical point (FQCP) and the experimentally determine critical exponents npj Quantum Materials (2017) 3
Summary
The connection between quantum fluctuations in the vicinity of a quantum critical point (QCP) and emergent ground states, such as high-temperature superconductivity, remains a topic of great interest in the condensed matter physics community.[1,2,3,4,5] One key to making progress in this area is the identification of model material systems that are complex enough to exhibit the physics of interest but simple enough to be compared to theory. The NiCoCrx alloys (with x ≈ 1) are related to the recently discovered high-entropy-alloys, such as NiCoCrFeMn,[11, 12] where configurational entropy stabilizes a random distribution of elements on a simple face-centered cubic lattice (fcc). These alloys have been shown to be chemically homogeneous from the centimeter to the nanometer scale. Energy dispersive spectroscopy data for the NiCoCr0.8 and NiCoCr crystals presented in Fig. S1 illustrate chemical homogeneity on the micron scale
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