Institute of Humanities, Arts & Sciences, Federal University of Bahia, Rua Barão de Jeremoabo s∕n, Glauber Rocha Pavilion (PAF 3), Ondina University Campus, 40170-115 Salvador-BA, Brazil.
J Chem Phys. 2011 Nov 21;135(19):194703. doi: 10.1063/1.3656696.
We collect and critically analyze extensive literature data, including our own, on three important kinetic processes--viscous flow, crystal nucleation, and growth--in lithium disilicate (Li(2)O·2SiO(2)) over a wide temperature range, from above T(m) to 0.98T(g) where T(g) ≈ 727 K is the calorimetric glass transition temperature and T(m) = 1307 K, which is the melting point. We found that crystal growth mediated by screw dislocations is the most likely growth mechanism in this system. We then calculated the diffusion coefficients controlling crystal growth, D(eff)(U), and completed the analyses by looking at the ionic diffusion coefficients of Li(+1), O(2-), and Si(4+) estimated from experiments and molecular dynamic simulations. These values were then employed to estimate the effective volume diffusion coefficients, D(eff)(V), resulting from their combination within a hypothetical Li(2)Si(2)O(5) "molecule". The similarity of the temperature dependencies of 1/η, where η is shear viscosity, and D(eff)(V) corroborates the validity of the Stokes-Einstein/Eyring equation (SEE) at high temperatures around T(m). Using the equality of D(eff)(V) and D(eff)(η), we estimated the jump distance λ ~ 2.70 Å from the SEE equation and showed that the values of D(eff)(U) have the same temperature dependence but exceed D(eff)(η) by about eightfold. The difference between D(eff)(η) and D(eff)(U) indicates that the former determines the process of mass transport in the bulk whereas the latter relates to the mobility of the structural units on the crystal/liquid interface. We then employed the values of η(T) reduced by eightfold to calculate the growth rates U(T). The resultant U(T) curve is consistent with experimental data until the temperature decreases to a decoupling temperature T(d)(U) ≈ 1.1-1.2T(g), when D(eff)(η) begins decrease with decreasing temperature faster than D(eff)(U). A similar decoupling occurs between D(eff)(η) and D(eff)(τ) (estimated from nucleation time-lags) but at a lower temperatureT(d)(τ) ≈ T(g). For T > T(g) the values of D(eff)(τ) exceed D(eff)(η) only by twofold. The different behaviors of D(eff)(τ)(T) and D(eff)(U)(T) are likely caused by differences in the mechanisms of critical nuclei formation. Therefore, we have shown that at low undercoolings, viscosity data can be employed for quantitative analyses of crystal growth rates, but in the deeply supercooled liquid state, mass transport for crystal nucleation and growth are not controlled by viscosity. The origin of decoupling is assigned to spatially dynamic heterogeneity in glass-forming melts.
我们收集并批判性地分析了广泛的文献数据,包括我们自己的,关于在锂硅氧(Li(2)O·2SiO(2))中的三个重要动力学过程——粘性流动、晶体成核和生长——的研究,涵盖了从高于 T(m)到 0.98T(g)的宽温度范围,其中 T(g)≈727 K 是比热玻璃化转变温度,T(m)=1307 K 是熔点。我们发现,在这个系统中,螺旋位错介导的晶体生长是最有可能的生长机制。然后,我们计算了控制晶体生长的扩散系数 D(eff)(U),并通过观察从实验和分子动力学模拟中估计的 Li(+1)、O(2-)和 Si(4+)的离子扩散系数来完成分析。然后将这些值用于估计有效体积扩散系数 D(eff)(V),这是它们在假设的 Li(2)Si(2)O(5)“分子”内结合的结果。1/η(其中 η 是剪切粘度)和 D(eff)(V)的温度依赖性相似,证实了高温下 Stokes-Einstein/Eyring 方程(SEE)的有效性接近 T(m)。使用 D(eff)(V)=D(eff)(η)的等式,我们从 SEE 方程估计了跳跃距离 λ≈2.70 Å,并表明 D(eff)(U)的值具有相同的温度依赖性,但比 D(eff)(η)高约八倍。D(eff)(η)和 D(eff)(U)之间的差异表明前者决定了体相中的质量传输过程,而后者与晶体/液体界面上结构单元的迁移率有关。然后,我们使用降低八倍的 η(T)值来计算生长速率 U(T)。所得的 U(T)曲线与实验数据一致,直到温度降低到解耦温度 T(d)(U)≈1.1-1.2T(g),此时 D(eff)(η)开始随着温度的降低而比 D(eff)(U)更快地降低。在 D(eff)(η)和 D(eff)(τ)(从成核时间滞后估计)之间也发生了类似的解耦,但温度更低 T(d)(τ)≈T(g)。对于 T>T(g),D(eff)(τ)的值仅比 D(eff)(η)高两倍。D(eff)(τ)(T)和 D(eff)(U)(T)的不同行为可能是由于临界核形成机制的差异造成的。因此,我们表明在低过冷度下,粘度数据可用于晶体生长速率的定量分析,但在深过冷液体状态下,晶体成核和生长的质量传输不受粘度控制。解耦的起源归因于玻璃形成熔体的空间动态异质性。
