Advances in Chemical Physics最新文献

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Local Fluctuations in Solution: Theory and Applications. 解的局部波动:理论与应用。

Advances in Chemical Physics

Pub Date : 2013-01-01 DOI: 10.1002/9781118571767.ch4

Elizabeth A Ploetz, Paul E Smith

引用次数: 21

Kinetics and Thermodynamics of Fluctuation‐Induced Transitions in Multistable Systems 多稳定系统中涨落诱导跃迁的动力学和热力学

Advances in Chemical Physics

Pub Date : 2012-04-09 DOI: 10.1002/9781118309513.CH1

G. Nicolis, C. Nicolis

1 Kinetics and Thermodynamics of Fluctuation-Induced Transitions in Multistable Systems By Gregoire Nicolis and Catherine Nicolis 27 Dynamical Rare Event Simulation Techniques for Equilibrium and Nonequilibrium Systems By Titus S. Van Erp 61 Confocal Depolarized Dynamic Light Scattering By M. Potenza, T. Sanvito, V. Degiorgio, and M. Giglio 79 The Two-Step Mechanism and The Solution-Crystal Spinodal for Nucleation of Crystals in Solution By Peter G. Vekilov 111 Experimental Studies of Two-Step Nucleation During Two-Dimensional Crystallization of Colloidal Particles with Short-Range Attraction By John R. Savage, Liquan Pei, and Anthony D. Dinsmore 137 On the Role of Metastable Intermediate States in the Homogeneous Nucleation of Solids from Solution By James F. Lutsko 173 Effects of Protein Size on the High-Concentration/Low-Concentration Phase Transition By Patrick Grosfils 193 Geometric Constraints in the Self-Assembly of Mineral Dendrites and Platelets By John J. Kozak 223 What can Mesoscopic Level IN SITU Observations Teach us About Kinetics and Thermodynamics of Protein Crystallization? By Mike Sleutel, Dominique Maes, and Alexander Van Driessche

1 .波坦萨，T. Sanvito, V. Degiorgio，共焦去偏振动态光散射[9]裴立全，John R. Savage，裴立全，等。两步成核过程的实验研究蛋白质大小对高浓度/低浓度相变的影响(Patrick Grosfils);矿物树晶和血小板自组装的几何约束(John J. Kozak);介观水平的原位观察能告诉我们关于蛋白质结晶动力学和热力学的什么?作者:Mike Sleutel, Dominique Maes和Alexander Van Driessche

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引用次数: 1

Effects of Protein Size on the High‐Concentration/Low‐Concentration Phase Transition 蛋白质大小对高浓度/低浓度相变的影响

Advances in Chemical Physics

Pub Date : 2012-04-09 DOI: 10.1002/9781118309513.CH7

P. Grosfils

引用次数: 0

Introduction to Quantum Algorithms for Physics and Chemistry 物理和化学量子算法导论

Advances in Chemical Physics

Pub Date : 2012-03-06 DOI: 10.1002/9781118742631.ch03

M. Yung, J. Whitfield, S. Boixo, D. G. Tempel, A. Aspuru‐Guzik

An enormous number of model chemistries are used in computational chemistry to solve or approximately solve the Schrodinger equation; each with their own drawbacks. One key limitation is that the hardware used in computational chemistry is based on classical physics, and is often not well suited for simulating models in quantum physics. In this review, we focus on applications of quantum computation to chemical physics problems. We describe the algorithms that have been proposed for the electronic- structure problem, the simulation of chemical dynamics, thermal state preparation, density functional theory and adiabatic quantum simulation.

计算化学中使用了大量的模型化学来求解或近似求解薛定谔方程;每一种都有自己的缺点。一个关键的限制是，计算化学中使用的硬件是基于经典物理的，通常不太适合模拟量子物理中的模型。本文主要介绍了量子计算在化学物理问题中的应用。我们描述了电子结构问题、化学动力学模拟、热态制备、密度泛函理论和绝热量子模拟的算法。

引用次数: 57

Quantum Dynamical Resonances in Chemical Reactions: From A + BC to Polyatomic Systems 化学反应中的量子动力学共振:从A + BC到多原子体系

Advances in Chemical Physics

Pub Date : 2012-01-31 DOI: 10.1002/9781118180396.CH1

Kopin Liu

引用次数: 33

Determination of molecular orientational correlations in disordered systems from diffraction data 从衍射数据测定无序体系中的分子取向相关性

Advances in Chemical Physics

Pub Date : 2012-01-31 DOI: 10.1002/9781118197714.CH3

S. Pothoczki, L. Temleitner, L. Pusztai

引用次数: 5

Recent advances in studying mechanical properties of DNA DNA力学性质研究的最新进展

Advances in Chemical Physics

Pub Date : 2012-01-31 DOI: 10.1002/9781118197714.CH4

Reza Vafabakhsh, Kyung-Sun Lee, T. Ha

引用次数: 2

Efficient and Unbiased Sampling of Biomolecular Systems in the Canonical Ensemble: A Review of Self-Guided Langevin Dynamics. 典型集合中生物分子系统的高效无偏采样：自导朗温动力学综述》。

Advances in Chemical Physics

Pub Date : 2012-01-31 DOI: 10.1002/9781118197714.ch6

Xiongwu Wu, Ana Damjanovic, Bernard R Brooks

This review provides a comprehensive description of the self-guided Langevin dynamics (SGLD) and the self-guided molecular dynamics (SGMD) methods and their applications. Example systems are included to provide guidance on optimal application of these methods in simulation studies. SGMD/SGLD has enhanced ability to overcome energy barriers and accelerate rare events to affordable time scales. It has been demonstrated that with moderate parameters, SGLD can routinely cross energy barriers of 20 kT at a rate that molecular dynamics (MD) or Langevin dynamics (LD) crosses 10 kT barriers. The core of these methods is the use of local averages of forces and momenta in a direct manner that can preserve the canonical ensemble. The use of such local averages results in methods where low frequency motion "borrows" energy from high frequency degrees of freedom when a barrier is approached and then returns that excess energy after a barrier is crossed. This self-guiding effect also results in an accelerated diffusion to enhance conformational sampling efficiency. The resulting ensemble with SGLD deviates in a small way from the canonical ensemble, and that deviation can be corrected with either an on-the-fly or a post processing reweighting procedure that provides an excellent canonical ensemble for systems with a limited number of accelerated degrees of freedom. Since reweighting procedures are generally not size extensive, a newer method, SGLDfp, uses local averages of both momenta and forces to preserve the ensemble without reweighting. The SGLDfp approach is size extensive and can be used to accelerate low frequency motion in large systems, or in systems with explicit solvent where solvent diffusion is also to be enhanced. Since these methods are direct and straightforward, they can be used in conjunction with many other sampling methods or free energy methods by simply replacing the integration of degrees of freedom that are normally sampled by MD or LD.

本综述全面介绍了自导朗格文动力学（SGLD）和自导分子动力学（SGMD）方法及其应用。文中还包括示例系统，为这些方法在模拟研究中的最佳应用提供指导。SGMD/SGLD 具有更强的能力来克服能量障碍，并将罕见事件加速到可承受的时间尺度。事实证明，在参数适中的情况下，SGLD 能够以分子动力学（MD）或朗格文动力学（LD）跨越 10 kT 能量障碍的速度常规跨越 20 kT 能量障碍。这些方法的核心是以直接方式使用力和力矩的局部平均值，从而保留典型集合。使用这种局部平均的结果是，当接近势垒时，低频运动从高频自由度 "借用 "能量，然后在越过势垒后返回多余的能量。这种自导效应也会导致加速扩散，从而提高构象采样效率。使用 SGLD 得出的集合与典型集合的偏差较小，这种偏差可以通过即时或后处理的重新加权程序进行校正，从而为加速自由度数量有限的系统提供出色的典型集合。由于重新加权程序一般不涉及大小问题，一种较新的方法 SGLDfp 使用力矩和力的局部平均值来保留集合，而无需重新加权。SGLDfp 方法具有尺寸广阔性，可用于加速大型系统中的低频运动，或在有明确溶剂的系统中加速溶剂扩散。由于这些方法直接而简单，它们可以与许多其他采样方法或自由能方法结合使用，只需替换通常由 MD 或 LD 采样的自由度积分即可。

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引用次数: 0

Computational Studies of the Properties of DNA‐Linked Nanomaterials DNA连接纳米材料性质的计算研究

Advances in Chemical Physics

Pub Date : 2012-01-31 DOI: 10.1002/9781118180396.CH5

One-Sun Lee, G. Schatz

引用次数: 4

Change‐Point Localization and Wavelet Spectral Analysis of Single‐Molecule Time Series 单分子时间序列变化点定位与小波谱分析

Advances in Chemical Physics

Pub Date : 2011-11-23 DOI: 10.1002/9781118131374.CH9

Haw Yang

引用次数: 26

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