We present a kinetic model of crystal growth of polymers of finite molecular weight.Experiments help to classify polymer crystallization broadly into two kinetic regimes.One is observed in melts or in high molar mass polymer solutions and is dominated by nucleation control with G approx exp(1/T DELTA T),where G is the growth rate and AT is the supercooling.The other is observed in low molar mass solutions(as well as for small molecules)and is diffusion controlled with G approx DELTA T,for small DELTA T.Our model unifies these two regimes in a single formalism.The model accounts for the accumulation of polymer chains near the growth front and invokes an entropic barrier theory to recover both limits of nucleation and diffusion control.The basic theory applies to both melts and solutions,and we numerically calculate the growth details of a single crystal in a dilute solution.The effects of molecular weight and concentration are also determined considering conventional polymer dynamics.Our theory shows that entropic considerations,in addition to the traditional energetic arguments,can capture general trends of a vast range of phenomenology.Unifying ideas on crystallization from small molecules and from flexible polymer chains emerge from our theory.
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机译:我们提供了一个有限分子量聚合物晶体生长的动力学模型,实验有助于将聚合物结晶大致分为两个动力学机制,一个是在熔体或高摩尔质量的聚合物溶液中观察到的,主要由成核控制以G近似exp( 1 / T DELTA T),其中G是生长速率,AT是过冷。另一个在低摩尔质量的溶液(以及小分子)中观察到,并且对于小DELTA T,用G约DELTA T进行扩散控制我们的模型在单一形式主义中统一了这两种机制,该模型考虑了聚合物链在生长前沿附近的积累,并调用了熵垒理论来恢复成核和扩散控制的极限,该基础理论适用于熔体和溶液,然后我们用数值方法计算出单晶在稀溶液中的生长细节。还考虑了常规聚合物动力学,还确定了分子量和浓度的影响。理论表明,除了传统的能量论证之外,熵的考虑还可以捕捉到各种现象学的总体趋势。从小分子和柔性聚合物链结晶的统一思想源于我们的理论。
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