Abstract
Exploration of low temperature phase transitions associated with quantum critical point is one of the most mystifying fields of research which is under intensive focus in recent times. In this work, through comprehensive experimental evidences, we report the possibility of achieving quantum criticality in the neighborhood of a magnetic field-tuned tricritical point separating paramagnetic, antiferromagnetic and metamagnetic phases in a magnetic insulator, DyVO4. Magnetic susceptibility and heat capacity indicate to the presence of a long-range second order antiferromagnetic transition at TN ~ 3.2 K. Field variation of Magnetic susceptibility and heat capacity, along with differential magnetic susceptibility and DC field dependent AC susceptibility gives evidence of the modification of the antiferromagnetic structure below the tricritical point; implying the presence of a field-induced first order metamagnetic transition which persists down to 1.8 K. Further, the magnetic field dependence of the thermodynamic quantity − dM/dT, which is related to magnetic Gruneisen parameter, approaches a minimum, followed by a crossover near 5 kOe to a maximum; along with a hyperbolic divergence in temperature response of dM/dT in the critical field regime. Temperature response of heat capacity at 5 kOe also shows a deviation from the conventional behavior. Entropic topography phase diagram allows tracking of the variation of the entropy, which indicates towards the emergence of the peak at quantum critical point into a V-shaped region at high temperatures. Our studies yield an inimitable phase diagram describing a tricritical point at which the second-order antiferromagnetic phase line terminates followed by a first order line of metamagnetic transition, as the temperature is lowered, leading to metamagnetic quantum critical end point.
Highlights
quantum critical point (QCP) represents a kind of void in the material phase diagram, and it distorts the curvature of the phase diagram, creating a V-shaped quantum critical region, fanning out from the QCP
This feature is quite visible in the magnetic field-temperature phase diagram; especially in resistivity for metals, and in S for insulators1,2. CoNb2O6 is a rare example of magnetic insulators showing such kind of behavior in which the QCP is described by the conformal field theory[1,8]
Rare earth orthovanadates, D yVO4, a magnetic insulator, can be quite interesting. This compound has not been explored from the viewpoint of quantum criticality. This compound belongs to R VO4 series, in which the indirect exchange between neighboring rare earth magnetic ions may lead to a long-range magnetic ordering at very low temperatures and 4 f electron–phonon coupling can result in the lattice instabilities
Summary
Over the last few decades, with the development of novel materials, it has become possible to study the unstable phases of matter near the interface between the stable phases. In the lower symmetry phase, the JT coupling induces a mixing of the two lowest Kramer doublets, leading to large magnetic anisotropy[29–31] This large magnetic anisotropy along with the admixing of eigenfunctions is likely to induce the quantum effects and this increased quantum fluctuations at low temperatures and high magnetic fields might result in the suppression of AFM ordering. In this manuscript, we explore the possibility of the existence of the magnetic field tuned QCP in DyVO4 through magnetic, magnetocaloric effect (MCE) and thermodynamic measurements. Our study suggests that D yVO4 can be tuned to quantum criticality near ~ 2.4 K and ~ 5 kOe
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