Dynamic scaling and aging phenomena in short-range Ising spin glass: Cu0.5Co0.5Cl2-FeCl3 graphite bi-intercalation compound
Abstract
Static and dynamic behavior of short-range Ising-spin glass Cu0.5Co0.5Cl2-FeCl3 graphite bi-intercalation compounds (GBIC) has been studied with SQUID DC and AC magnetic susceptibility. The T dependence of the zero-field relaxation time τ above a spin-freezing temperature Tg (= 3.92 0.11 K) is well described by critical slowing down. The absorption below Tg decreases with increasing angular frequency ω, which is in contrast to the case of 3D Ising spin glass. The dynamic freezing temperature Tf(H,ω) at which dMFC(T,H)/dH=(T,H=0,ω), is determined as a function of frequency (0.01 Hz ≤ ω/2π ≤ 1 kHz) and magnetic field (0 ≤ H ≤ 5 kOe). The dynamic scaling analysis of the relaxation time τ(T,H) defined as τ = 1/ω at T = Tf(H,ω) suggests the absence of SG phase in the presence of H (at least above 100 Oe). Dynamic scaling analysis of (T, ω) and τ(T,H) near Tg leads to the critical exponents (β = 0.36 0.03, γ = 3.5 0.4, = 1.4 0.2, z = 6.6 1.2, = 0.24 0.02, and θ = 0.13 0.02). The aging phenomenon is studied through the absorption (ω, t) below Tg. It obeys a (ω t)-b power-law decay with an exponent b ≈ 0.15 - 0.2. The rejuvenation effect is also observed under sufficiently large (temperature and magnetic-field) perturbations.
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