Quantum Mechanics and Dynamics of Open Polyatomic Systems

开放多原子系统的量子力学和动力学

• 批准号: RGPIN-2020-04017
• 负责人: Brumer, Paul
• 金额: $ 1.75万
• 依托单位: University of Toronto
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=739624
• 关键词: Quantum; Mechanics; Dynamics; Open; Polyatomic

We propose to study, both computationally and theoretically, various aspects of light-induced quantum dynamics of polyatomic (large) molecular systems that are coupled to an external environment. Such systems are ubiquitous in Chemistry, affecting all aspects of life. Indeed, the interaction of molecules with sunlight, in photosynthesis for example, is the primary source by which energy is transmitted to life on earth. In all cases to be studied we will proceed by developing formal theories, and building models containing the essential physical chemistry of the system examined. More complex modeling will be invoked when deemed enlightening. The work proposed is state-of-the-art in theoretical and computational  chemistry, taking advantage of the most modern of parallel computer facilities. Such research often precedes and heralds developments in technology and industry, providing Canada with the edge in important advanced technological applications. The proposed program is also expected to provide the research environment and research challenges that are vital to the training of modern, highly qualified personnel. In addition to basic issues in light-matter interactions we will consider two major directions: (a)  Coherent Control of Dynamic Processes is a foundational approach to controlling molecular processes via quantum interference effects. The methodology, based upon work that we have done over several decades, has been highly successful for small, isolated quantum systems. By contrast, control of larger molecules that are coupled to external environments (e.g., in solution or in a protein matrix)  is a fertile field that we propose to explore in detail. The results are expected to significantly expand the range of control over processes in chemistry using quantum interference effects, an emergent technology for the coming century. (b) Open Quantum Systems are described by master equations, which are inherently subject to a wide collection of approximations (secular vs. nonsecular, Markovian vs. Non-Markovian, global vs. local couplings, low order perturbation theories, etc.). The choice of approximation has a profound influence on the resultant dynamics. We propose extensive studies designed to explore domains of validity of these approximate schemes for photosynthetic systems. Of importance here is the actual nature of the coupling between the system and environment, explored using a variety of methods. The results are expected to contribute significantly to the range of validity and applicability of master equation methods for light harvesting processes.  In addition, we will examine issues related to the ability of photosynthetic systems to act as photon detectors, an issue of fundamental significance.

我们建议从计算和理论上研究耦合到外部环境的多原子（大）分子系统的光致量子动力学的各个方面。这样的系统在化学中无处不在，影响着生活的方方面面。事实上，分子与阳光的相互作用，例如在光合作用中，是能量传递给地球上生命的主要来源。在所有要研究的情况下，我们将继续发展正式的理论，并建立模型，包含基本的物理化学的系统检查。更复杂的建模将被调用时，认为有启发性。所提出的工作是国家的最先进的理论和计算化学，利用最现代的并行计算机设施。这种研究往往先于并预示着技术和工业的发展，使加拿大在重要的先进技术应用方面具有优势。该计划还将提供研究环境和研究挑战，这对培养现代高素质人才至关重要。除了光-物质相互作用的基本问题外，我们还将考虑两个主要方向：（a）动态过程的相干控制是通过量子干涉效应控制分子过程的基本方法。该方法基于我们几十年来所做的工作，对于小型孤立的量子系统非常成功。相比之下，控制与外部环境耦合的较大分子（例如，在溶液中或在蛋白质基质中）是我们建议详细探索的肥沃领域。这些结果有望大大扩大利用量子干涉效应控制化学过程的范围，这是即将到来的世纪的新兴技术。(b)开放量子系统由主方程描述，其固有地受到广泛的近似集合（长期与非长期，马尔可夫与非马尔可夫，全局与局部耦合，低阶微扰理论等）的影响。近似的选择对合成动力学有着深远的影响。我们提出了广泛的研究，旨在探索这些近似方案的有效性域光合系统。这里重要的是系统和环境之间耦合的实际性质，使用各种方法进行了探索。预计这些结果将有助于显着的范围内的有效性和适用性的主方程方法的光捕获processes. In此外，我们将研究有关的问题，光合系统的能力，作为光子探测器，一个具有根本意义的问题。