A method which controls momentum evolution in a sub-region within a molecular dynamics simulation is derived from Gauss's principle of least constraint. The technique for localization is founded on the equations by Irving and Kirkwood [J. Chem. Phys. 18, 817 (1950)] expressed in a weak form according to the control volume (CV) procedure derived by Smith et al. [Phys. Rev. E. 85, 056705 (2012)]. A term for the advection of molecules appears in the derived constraint and is shown to be essential in order to exactly control the time evolution of momentum in the subvolume. The numerical procedure converges the total momentum in the CV to the target value to within machine precision in an iterative manner. The localized momentum constraint can prescribe essentially arbitrary flow fields in non-equilibrium molecular dynamics simulations. The methodology also forms a rigorous mathematical framework for introducing coupling constraints at the boundary between continuum and discrete systems. This functionality is demonstrated with a boundary-driven flow test case. (C) 2015 AIP Publishing LLC.
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机译:高斯的最小约束原理推导了一种在分子动力学模拟中控制子区域动量演变的方法。本地化技术基于Irving和Kirkwood [J.化学物理18,817(1950)]根据史密斯(Smith)等人的控制体积(CV)程序以弱形式表达。 [物理Rev. E. 85,056705(2012)]。分子对流的一个术语出现在派生的约束中,并被证明对于精确控制子体积中动量的时间演化至关重要。数值过程以迭代的方式将CV中的总动量收敛到机器精度内的目标值。局部动量约束可以在非平衡分子动力学模拟中规定基本上任意的流场。该方法还形成了一个严格的数学框架,用于在连续系统和离散系统之间的边界处引入耦合约束。边界驱动的流量测试案例演示了此功能。 (C)2015 AIP Publishing LLC。
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