Gr\"uneisen Parameter and Thermal Expansion by the Self-Consistent Renormalization Theory of Spin Fluctuations

Abstract

The thermal expansion coefficient α and the Gr\"uneisen parameter near the magnetic quantum critical point (QCP) are derived on the basis of the self-consistent renormalization (SCR) theory of spin fluctuation. From the SCR entropy, the specific heat CV, α, and are shown to be expressed in a simple form as CV=C a-C b, α=α a+α b, and = a+ b, respectively, where C i, α i, and i ( i= a, b) are related with each other. As the temperature T decreases, C a, α b, and b become dominant in CV, α, and , respectively. The inverse susceptibility of spin fluctuation coupled to the volume V in b is found to give rise to the divergence of at the QCP for each class of ferromagnetism and antiferromagnetism (AFM) in spatial dimensions d=3 and 2. This V-dependent inverse susceptibility in αb and b contributes to the T dependences of α and , and even affects their criticality in the case of the AFM QCP in d=2. a is expressed as a(T=0)=-VT0(∂ T0∂ V)T=0 with T0 being the characteristic temperature of spin fluctuation, which has an enhanced value in heavy electron systems.