Grueneisen Ratio Divergence at the Quantum Critical Point in CeCu_{6-x}Ag_x
arXiv:cond-mat/0407798 · doi:10.1103/PhysRevLett.93.096402
Abstract
The heavy fermion system CeCu$_{6-x}$Ag$_x$ is studied at its antiferromagnetic quantum critical point, $x_c=0.2$, by low temperature ($T\geq 50$ mK) specific heat, $C(T)$, and volume thermal expansion, $β(T)$, measurements. Whereas $C/T\propto \log(T_0/T)$ would be compatible with the predictions of the itinerant spin-density-wave (SDW) theory for two-dimensional critical spin fluctuations, $β(T)/T$ and the Grüneisen ratio, $Î(T)\propto β/C$, diverge much weaker than expected, in strong contrast to this model. Both $C$ and $β$, plotted as a function of the reduced temperature $t=T/T_0$ with $T_0=4.6$ K are similar to what was observed for YbRh$_2$(Si$_{0.95}$Ge$_{0.05}$)$_2$ ($T_0=23.3$ K) indicating a striking discrepancy to the SDW prediction in both systems.
Physical Review Letters, to be published