III. Ecosmos: A Revolutionary Fertile, Habitable, Solar-Bioplanet Lifescape
2. A Consilience of Biology and Physics: Active Matter
Marson, G. Ajmone, et al. Stochastic Evolutionary Differential Games toward a System of Behavioral Social Dynamics. Mathematical Models and Methods in Applied Sciences. 26/6, 2016. In a well rated World Scientific journal, this paper by mathematicians G. A. Marsan, Organization for Economic Cooperation and Development OECD, Paris, Nicola Bellomo, King Abdulaziz University, Jeddah, and Livio Gibelli, Polytechnic University of Turin was cited as the most read of the year. Also at arXiv:1506.05699. It is an inquiry into how novel theories of self-active kinetic matter might, by way of “big data” networks, be applied far afield to a range of social and economic systems. See also Mathematical Models of Self-Propelled Particles by N. Bellomo and F. Brezzi in this journal (27/6, 2017).
This paper proposes a systems approach to social sciences based on a mathematical framework derived from a generalization of the mathematical kinetic theory and of theoretical tools of game theory. Social systems are modeled as a living evolutionary ensemble composed of many individuals, who express specific strategies, cooperate, compete and might aggregate into groups which pursue a common interest. A critical analysis on the complexity features of social system is developed and a differential structure is derived to provide a general framework toward modeling. (Abstract)
McFadden, Johnjoe and Jim Al-Khalili. Life on the Edge: The Coming of Age of Quantum Biology. New York: Bantam, 2014. A geneticist and a physicist, both at the University of Surrey, draw upon the leading edges of biological and physical science to explain a grand cross-integration of evolutionary organisms and a lively natural cosmos.
McFadden, Johnjoe and Jim Al-Khalili. The Origins of Quantum Biology. Proceedings of the Royal Society A. Vol.474/Iss.2220, 2018. A University of Surrey, UK biologist and a physicist who have each authored prior works (search) achieve a unique, thorough history of this incipient synthesis from A. N. Whitehead, Erwin Schrodinger and others such as organicists and vitalists, aka the Cambridge Theoretical Biology Club, to its worldwise fruition today. From this retro-vista, an Order from Order phrase can be coined, which is seen in effect by a flow of recent findings, as the abstract notes.
Quantum biology is usually considered to be a new discipline, arising from recent research that suggests that biological phenomena such as photosynthesis, enzyme catalysis, avian navigation or olfaction may not only operate within the bounds of classical physics but also make use of a number of the non-trivial features of quantum mechanics, such as coherence, tunnelling and, perhaps, entanglement. However, although the most significant findings have emerged in the past two decades, the roots of quantum biology go much deeper—to the quantum pioneers of the early twentieth century. We will argue that some of the insights provided by these pioneering physicists remain relevant to our understanding of quantum biology today. (Abstract)
Melkikh, Alexey and Andrei Khrennikov. Mechanisms of Directed Evolution of Morphological Structures and the Problems of Morphogenesis. Biosystems. 168/26, 2018. Reviewed more in Systems Evolution, a latest essay by the Ural Federal University, Russia and Linnaeus University, Sweden theorists.
Menon, Gautam. Active Matter. Krishnan, J. Murali, et al, eds. Rheology of Complex Fluids. Berlin: Springer, 2010. A Chennai Institute of Technology, India, mathematician draws upon this novel conception of natural spontaneities to better characterize dynamic, animate phenomena. The chapter was informed by discussions with Sriram Ramaswamy, its founder, Cristina Marchetti, and other colleagues. As this section conveys, from many instances across every scale, independent general principles can be distilled.
The term active matter describes diverse systems, spanning macroscopic (e.g. shoals of fish and flocks of birds) to microscopic scales (e.g. migrating cells, motile bacteria and gels formed through the interaction of nanoscale molecular motors with cytoskeletal filaments within cells). Such systems are often idealizable in terms of collections of individual units, referred to as active particles or self-propelled particles, which take energy from an internal replenishable energy depot or ambient medium and transduce it into useful work performed on the environment, in addition to dissipating a fraction of this energy into heat. Active particles can exhibit remarkable collective behaviour as a consequence of these interactions, including non-equilibrium phase transitions between novel dynamical phases, large fluctuations violating expectations from the central limit theorem and substantial robustness against the disordering effects of thermal fluctuations. (Abstract)
Menzel, Andreas. Tuned, Driven, and Active Soft Matter. Physics Reports. 554/1, 2015. The Heinrich Heine University theorist quantifies an inherent materiality that seems to act much as a living organism with internal propensities, responses and self-motility. Candidates such as colloids, nematic liquid crystals, ferrogels, magnetic elastomers, vesicles in shear flow, copolymers engage in self-propelled, variable movement, interactive, emergent organizations, and so on. The paper goes on to the Collective Behavior of Animals whence insects, fish, and birds are found to exhibit similar non-equilibrium phenomena. By turns, might we imagine the physical cosmos by nature to be organic and alive. See also his later paper On the Way of Classifying New States of Active Matter in New Journal of Physics (18/071001, 2016) as a further summary with a copious bibliography.
One characteristic feature of soft matter systems is their strong response to external stimuli. As a consequence they are comparatively easily driven out of their ground state and out of equilibrium, which leads to many of their fascinating properties. Here, we review illustrative examples. This review is structured by an increasing distance from the equilibrium ground state. On each level, examples of increasing degree of complexity are considered. Finally, we focus on systems that are “active” and “self-driven”. Here our range spans from idealized self-propelled point particles, via sterically interacting particles like granular hoppers, via microswimmers such as self-phoretically driven artificial Janus particles or biological microorganisms, via deformable self-propelled particles like droplets, up to the collective behavior of insects, fish, and birds. As we emphasize, similarities emerge in the features and behavior of systems that at first glance may not necessarily appear related. We thus hope that our overview will further stimulate the search for basic unifying principles underlying the physics of these soft materials out of their equilibrium ground state. (Abstract excerpts)
Mohseni, Masoud, et al. Quantum Effects in Biology. Cambridge: Cambridge University Press,, 2014. Among the editors and authors are Martin Plenio, Seth Lloyd, Graham Fleming, and Elisabet Romero (See Nature Physics 10/9, 2014). One of the first book-length collections which gathers years of research and realizations that, if properly understood, “quantum” phenomena are not arcane and off-putting. Instead, as the quote notes, their creative presence can then be found across all realms of living, quickening nature.
Quantum biology, as introduced in the previous chapter, mainly studies the dynamical influence of quantum effects in biological systems. In processes such as exciton transport in photosynthetic complexes, radical pair spin dynamics in magnetoreception, and photo-induced retinal isomerization in the rhodopsin protein, a quantum description is a necessity rather than an option. The quantum modelling of biological processes is not limited to solving the Schrödinger equation for an isolated molecular structure. Natural systems are open to the exchange of particles, energy or information with their surrounding environments that often have complex structures. Therefore the theory of open quantum systems plays a key role in dynamical modelling of quantum-biological systems. Research in quantum biology and open quantum system theory have found a bilateral relationship. Quantum biology employs open quantum system methods to a great extent while serving as a new paradigm for development of advanced formalisms for non-equilibrium biological processes. (Chapter 2, Open Quantum System Approaches to Biological Systems)
Mora, Thierry, et al. Questioning the Activity of Active Matter in Natural Flocks of Birds. arXiv:1511.01958. A team of nine physicists across Europe including Irene Giardina, Leonardo Parisi, Aleksandra Walczak, and Andrea Cavagna continue to expand and finesse a viewing animal groupings as exemplars of complex adaptive self-organizing systems. For a philosophical surmise, one might imagine a universally iterative nature not as only a book, an encyclopedia testament, but as a three dimensional, graphic revelation which our phenomenal human phase is meant to read, and to enhance anew.
The correlated motion of large bird flocks is an instance of self-organization where global order emerges from local interactions. Despite the analogy with ferromagnetic systems, a major difference is that flocks are active -- animals move relative to each other, thereby dynamically rearranging their interaction network. Although the theoretical importance of this off-equilibrium ingredient has long been appreciated, its relevance to actual biological flocks remains unexplored. Here we introduce a novel dynamical inference technique based on the principle of maximum entropy, which takes into account network reshuffling and overcomes the limitations of slow experimental sampling rates. We apply this method to three-dimensional data of large natural flocks of starlings, inferring independently the strength of the social alignment forces, the range of these forces, and the noise.
Moretti, Paolo and Miguel Munoz. Griffiths Phases and the Stretching of Criticality in Brain Networks. Nature Communications. Online October, 2013. We cite this paper as a good example of a growing sense, often by translation of terms, of the deepest affinities between all manner of biological and cerebral form and behavior with such basic physical phenomena. In this case University of Granada, Spain, computational neuroscientists draw parallels between the definitive self-organized critical poise of neural activity and mechanisms of statistical physics. The import of this study was noted by Claus Hilegetag and Marc-Thorsten Hutt in “Hierarchical Modular Brain Connectivity is a Stretch for Criticality” in Trends in Cognitive Sciences (Online November 2013).
Hallmarks of criticality, such as power-laws and scale invariance, have been empirically found in cortical-network dynamics and it has been conjectured that operating at criticality entails functional advantages, such as optimal computational capabilities, memory and large dynamical ranges. As critical behaviour requires a high degree of fine tuning to emerge, some type of self-tuning mechanism needs to be invoked. Here we show that, taking into account the complex hierarchical-modular architecture of cortical networks, the singular critical point is replaced by an extended critical-like region that corresponds—in the jargon of statistical mechanics — to a Griffiths phase. Using computational and analytical approaches, we find Griffiths phases in synthetic hierarchical networks and also in empirical brain networks such as the human connectome and that of Caenorhabditis elegans. Stretched critical regions, stemming from structural disorder, yield enhanced functionality in a generic way, facilitating the task of self-organizing, adaptive and evolutionary mechanisms selecting for criticality. (Abstract)
Morone, Flaviano, et al. Fibration Symmetries Uncover the Building Blocks of Biological Networks. Proceedings of the National Academy of Sciences. 117/8306, 2020. CCNY systems physicists including Hernan Makse describe a novel geometric intersect between living systems and their physical substrate by way of these webwork intricacies. Notably then the contribution serve belies its own inorganic building block metaphor.
The success of symmetries in explaining the physical world, from general relativity to particle physics and all phases of matter, raises the question of whether the same concept could explain emergent properties of biological systems. In other words, if life is an emergent property of physics then the symmetry principles that inform physics should also apply to the organizing principles of life. Here we show that a form of symmetry called fibration can describe the nodes and links of biological networks and other social and infrastructure networks. This result broadly opens the way to understand how information-processing networks are assembled from the bottom up. (Significance)
Mugler, Andrew and Bo Sun. Special Issue on Emergent Collective Behavior form Groups of Cells. Physical Biology. 115/6363, 2018. Purdue University and Oregon State University biophysicists introduce a collection of new findings about how physical phenomena are intimately engaged in biological development and activities. See for example Biophysical Constraints Determine the Selection of Pheneotypic Fluctuations During Directed Evolution by Hong-Yah Shih, et al in this issue.
Single cells perform extraordinary tasks: they follow chemical cues, process environmental information, make life-or-death decisions, and replicate themselves. Yet, few cells are truly 'single'. Even single-celled organisms exist and interact within complex communities. In recent years, it has become particularly evident that when groups of cells act collectively, their performance improves or they perform new tasks altogether. This special issue collects papers focusing on the new and improved behaviors that emerge when cells interact. In these reports cells interact in three major ways: competition, cooperation, and communication, and the interactions may be mechanical or biochemical in nature. A wide range of systems are discussed, from virus-host pathogenesis, growth and evolution of bacteria, to the motility, mechanosensing, and force generation of mammalian cells. (Summary)
Nagel, Sidney. Experimental Soft-Matter Science. Reviews of Modern Physics. 89/025002, 2017. A summary of a January 2016 workshop as admissions and insights grow about these non-equilibrium lively material forms, of which the article is a good tutorial. This heretofore unnoticed realm is cited as disordered, nonlinear, thermal and entropic, observable, gravity-affected, nonlocal, patterned, interfacial elastic, memory retaining, to wit active matter. That is to say it expresses an organic essence.
Soft materials consist of basic units that are significantly larger than an atom but much smaller than the overall dimensions of the sample. The label “soft condensed matter” emphasizes that the large basic building blocks of these materials produce low elastic moduli that govern a material’s ability to withstand deformations. Aside from softness, there are many other properties that are also caused by the large size of the constituent building blocks. Soft matter is dissipative, disordered, far from equilibrium, nonlinear, thermal and entropic, slow, observable, gravity affected, patterned, nonlocal, interfacially elastic, memory forming, and active. This is only a partial list of how matter created from large component particles is distinct from “hard matter” composed of constituents at an atomic scale. (Abstract)