In this paper, we present systematic measurements of the temperature and magnetic field dependencies of the thermodynamic and transport properties of the Yb-based heavy fermion YbPtBi for temperatures down to 0.02 K with magnetic fields up to 140 kOe to address the possible existence of a field-tuned quantum critical point. Measurements of magnetic-field- and temperature-dependent resistivity, specific heat, thermal expansion, Hall effect, and thermoelectric power indicate that the AFM order can be suppressed by an applied magnetic field of H-c similar to 4 kOe. In the H-T phase diagram of YbPtBi, three regimes of its low-temperature states emerge: (I) AFMstate, characterized by a spin density wave-like feature, which can be suppressed to T = 0 by the relatively small magnetic field of H-c similar to 4 kOe; (II) field-induced anomalous state in which the electrical resistivity follows Delta(rho)(T) proportional to T-1.5 between H-c and similar to 8 kOe; and (III) Fermi liquid (FL) state in which Delta(rho)(T) proportional to T-2 for H %26gt;= 8 kOe. Regions I and II are separated at T = 0 by what appears to be a quantum critical point. Whereas region III appears to be a FL associated with the hybridized 4f states of Yb, region II may be a manifestation of a spin liquid state. DOI: 10.1103/PhysRevB.87.075120

• 出版日期2013-2-15