Collective behavior in complex systems

复杂系统中的集体行为

• 批准号: RGPIN-2014-03807
• 负责人: Kolokolnikov, Theodore
• 金额: $ 2.04万
• 依托单位: Dalhousie University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2018
• 资助国家: 加拿大
• 起止时间: 2018-01-01 至 2019-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=655832
• 关键词: Collective; behavior; complex; systems

Collective behaviour is an ubiquitous natural phenomenon that pervades both the animal world and many inanimate physical systems. In biology, group formation is observed across all levels of the animal kingdom, from bacterial colonies, insect swarms, fish schools and flocks of birds, to complex human population interactions. Collective behaviour also arises in a multitude of physical systems such as granular gases, self-assembly of nanoparticles and DNA buckyball molecules, and crystal lattices in Bose-Einstein Condensates. The emergence of collective group behaviour is often a consequence of individuals (or atoms) following very simple rules, without any external coordination. In recent years, many models of group emergence and behaviour have been proposed. The purpose of this program is to study the fundamentals of emergent behaviour, develop new mathematical and computer tools, and to collaborate with other scientists to apply these ideas to problems in chemistry, physics and biology.**In biology, collective behaviour confers certain benefits on individuals or group as a whole, such as predator avoidance for bird flocks, food gathering for ants and heat preservation in penguin huddles. This poses numerous mathematical, biological and even philosophical questions such as: What are the physical/biological mechanisms that cause aggregation? What is the optimal shape (or size) of the swarm? To what extent is swarming an evolutionary adaptation? **An example of collective behaviour in physics are Bose-Einstein Condensates (BEC). This is a state of matter, theorized in 1920's by Bose and Einstein, that exists at extremely low temperatures (close to absolute zero), and which consists of concentrations of atoms. It was not until 1990's that BEC's existence was experimentally observed at MIT and JILA (Joint Institute for Laboratory Astrophysics), a work for which these groups were awarded the Nobel prize in Physics (2001). In this experiments, BEC were observed to self-organize into rigidly rotating "vortex crystals", which are very regular hexagonal lattice configurations of vortex-particles, with each vortex representing a concentration of atoms. **One of the goals of this proposal is to apply new methods recently developed in studies of biological swarms to gain insight into the structure of these vortex crystals: their shape, stability, and the so-called Tkatchenko vibrational modes. Recently, BECs have been found to have numerous potential applications such as Ramsey spectroscopy. Tantalizingly, BECs hold promise for potential breakthroughs in computing; it was demonstrated experimentally that BECs can potentially be used to factor large numbers and to perform logic operations with qubits in lieu of a quantum computer. **The study of swarms and collective behaviour is a very rich topic at the intersection of several mathematical, biological and physical sub-disciplines, and is currently undergoing an explosive development. A progress in any of these problems will have repercussions across multiple disciplines and the formation of lasting collaborations and the cross-pollination across disciplines is expected to be both timely and important. The variety of problems makes this area an ideal source of problems for training HQP at all levels (from undergrad to postdoc) and with different backgrounds.

集体行为是一种普遍存在的自然现象，既存在于动物世界，也存在于许多无生命的物理系统中。在生物学上，从细菌群落、昆虫群、鱼群和鸟群，到复杂的人类种群相互作用，在动物界的各个层面都可以观察到群体的形成。集体行为也出现在许多物理系统中，例如颗粒气体、纳米粒子和DNA巴克球分子的自组装，以及玻色-爱因斯坦凝聚物中的晶格。集体集体行为的出现往往是个人(或原子)遵循非常简单的规则，而没有任何外部协调的结果。近年来，人们提出了许多关于群体涌现和行为的模型。这个项目的目的是研究突发行为的基本原理，开发新的数学和计算机工具，并与其他科学家合作，将这些想法应用于化学、物理和生物学问题。**在生物学中，集体行为赋予个人或群体一定的好处，如避免鸟群捕食、蚂蚁聚集食物和企鹅窝中的保温。这引发了许多数学、生物学甚至哲学问题，例如：导致聚集的物理/生物机制是什么？蜂群的最佳形状(或大小)是什么？蜂拥而至在多大程度上是一种进化适应？**物理学中集体行为的一个例子是玻色-爱因斯坦凝聚体(BEC)。这是一种物质的状态，由玻色和爱因斯坦在1920年的S提出，它存在于极低的温度(接近绝对零度)，并且由原子浓度组成。直到1990年的S，BEC的存在才在麻省理工学院和JILA(联合实验室天体物理研究所)被实验观测到，这项工作使这两个小组获得了诺贝尔物理学奖(2001年)。在这个实验中，观察到BEC自组织成刚性旋转的“涡旋晶体”，这是非常规则的涡旋粒子的六边形晶格构型，每个涡旋代表一个原子的浓度。**这项提议的目标之一是应用最近在生物群研究中发展起来的新方法来深入了解这些涡旋晶体的结构：它们的形状、稳定性和所谓的Tkatchenko振动模。最近，人们发现BEC具有许多潜在的应用，如拉姆齐光谱。诱人的是，BEC有望在计算方面取得潜在的突破；实验证明，BEC可能被用来代替量子计算机进行大数的因式分解和用量子比特执行逻辑运算。**群体和集体行为的研究是一个非常丰富的课题，是几个数学、生物和物理分支学科的交叉学科，目前正在经历爆炸性的发展。这些问题中的任何一个问题的进展都将对多个学科产生影响，预计形成持久的合作和跨学科的交叉授粉是及时和重要的。各种各样的问题使这一领域成为培训各级(从本科生到博士后)和不同背景的HQP的理想问题来源。