The paper by Ozawa et al. (1) presents numerical results for the configurational entropy density, sc, of a model glass-forming liquid in the presence of random pinning. The location of a “phase boundary” in the pin density (c) − temperature (T) plane, which separates an “ideal glass” phase from the supercooled liquid phase, is obtained by finding the points at which sc(T,c)→0. According to the theoretical arguments in ref. 2, an ideal glass transition at which the α-relaxation time τα diverges takes place when sc goes to zero.

We have studied the dynamics of the same system using molecular dynamics simulations. In Fig. 1, Left, we show the time dependence of the self intermediate scattering function, Fs(k,t), calculated at three state points in the (c−T) plane where sc(T,c)≃0 according to Ozawa et al. (1). It is clear from the plots that the relaxation time is finite (τα is of the order of 106) at these state points. Similar conclusions have been obtained in ref. 3, where an overlap function was used to calculate τα at these state points.

• Download figure
• Open in new tab
• Download powerpoint

Fig. 1.

(Left) Plots of the time dependence of the self intermediate scattering function, Fs(k,t)=(1/Nm)[〈∑i=1Nmeık→⋅(r→i(t)−r→i(0))〉], where k is the wavenumber at the first peak of the static structure factor, 〈…〉 implies an average over thermal history, […] represents an average over different realization of the pinned particles, and Nm is the number of unpinned mobile particles. Results are shown for three state points at which sc(T,c)≃0 according to Ozawa et al. (1). The α-relaxation time τα is calculated using a fit to the form Fs(k,t)=A⁡exp[−(t/τ1)2/2]+(1−A)exp[−(t/τα)β]. The fits are shown by solid lines. The relaxation times for these state points are τα(T=0.50,c=0.16)≃3.7×106, τα(T=0.55,c=0.20)≃2.4×106, and τα(T=0.70,c=0.30)≃9.0×105. (Middle) τα(T,c) versus 1/[Tsc(T,0)] for data extracted from Ozawa et al. (1). (Right) ln[τα(T,c)] versus 1/[Tsc(T,0)] for the data in ref. 3.

If the numerical results for sc(T,c) reported in Ozawa et al. (1) are correct, then our explicit demonstration of the fact that τα does not diverge at state points where sc=0 according to Ozawa et al. (1) would have fundamental implications for theories of the glass transition. The well-known random first-order transition (RFOT) description of the glass transition is based on the premise that the vanishing of sc causes a divergence of τα. The prediction (2) of the existence of a line of ideal glass transitions in the (c−T) plane for randomly pinned liquids was based on the RFOT description. Our results for τα would imply that the RFOT description is not valid for pinned liquids. Because a divergence of τα is the defining feature of the glass transition, the entropy-vanishing “transition” found in Ozawa et al. (1) at which τα does not diverge should not be called a glass transition.

If, however, we disregard the results for sc(T,c) reported in Ozawa et al. (1), then all available data for the dynamics of this system (3, 4) can be understood from a description that is consistent with RFOT and the requirement that the presence of pinning must decrease sc. This description (3) is based on the assumption that sc(T,c)=B(c)sc(T,0) for small values of c, where B(c) is a smooth function that decreases with increasing c, with B(0)=1. This assumption, when combined with the Adam–Gibbs relation, predicts that the logarithm of τα(T,c) should be a linear function of 1/[Tsc(T,0)] with a coefficient that increases with c. The data for τα(T,c) in ref. 3 are consistent with this prediction (Fig. 1, Right). We have verified that the data for τα(T,c) and sc(T,0) in Ozawa et al. (1) are also consistent with this prediction (Fig. 1, Middle). This observation provides a way of reconciling the behavior of τα(T,c) with RFOT, but it also implies that the data for sc(T,c) reported in Ozawa et al. (1) are not quantitatively accurate.