Robust Dynamics of Synthetic Molecular Systems as a Consequence of Broken Symmetry

The construction of molecular robot-like objects that imitate living things is an important challenge for current chemists. Such molecular devices are expected to perform their duties robustly to carry out mechanical motion, process information, and make independent decisions. Dissipative self-organization plays an essential role in meeting these purposes. To produce a micro-robot that can perform the above tasks autonomously as a single entity, a function generator is required. Although many elegant review articles featuring chemical devices that mimic biological mechanical functions have been published recently, the dissipative structure, which is the minimum requirement for mimicking these functions, has not been sufficiently discussed. This article aims to show clearly that dissipative self-organization is a phenomenon involving autonomy, robustness, mechanical functions, and energy transformation. Moreover, it reports the results of recent experiments with an autonomous light-driven molecular device that achieves all of these features. In addition, a chemical model of cell-amplification is also discussed to focus on the generation of hierarchical movement by dissipative self-organization. By reviewing this research, it may be perceived that mainstream approaches to synthetic chemistry have not always been appropriate. In summary, the author proposes that the integration of catalytic functions is a key issue for the creation of autonomous microarchitecture.

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Robust Dynamics of Synthetic Molecular Systems as A Consequence of Broken Symmetry

10.20944/preprints202009.0199.v1 ◽

2020 ◽

Author(s):

Yoshiyuki Kageyama

Keyword(s):

Self Organization ◽

Mechanical Motion ◽

Function Generator ◽

Minimum Requirement ◽

Molecular Systems ◽

Living Things ◽

Micro Robot ◽

Motion Process ◽

Important Challenge ◽

Catalytic Functions

The construction of molecular robotic-like objects that imitate living things is an important challenge for current chemists. Such molecular devices are expected to perform their duties robustly to carry out mechanical motion, process information, and make independent decisions. Dissipative self-organization plays an essential role in meeting these purposes. To produce a micro-robot that can perform the above tasks autonomously as a single entity, a function generator is required. Although many elegant review articles featuring chemical devices that mimic biological mechanical functions have been published recently, the dissipative structure, which is the minimum requirement, has not been sufficiently discussed. This article aims to show clearly that dissipative self-organization is a phenomenon involving autonomy, robustness, mechanical functions, and energy transformation. Moreover, the author details the recent experimental results of an autonomous light-driven molecular device that achieves all of these features. In addition, a chemical model of cell-amplification is also discussed to focus on the generation of hierarchical movement by dissipative self-organization. By reviewing this research, it may be perceived that mainstream approaches to synthetic chemistry have not always been appropriate. In summary, the author proposes that the integration of catalytic functions is a key issue for the creation of autonomous microarchitecture.

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Self-Organization of Molecular Systems and Evolution of the Genetic Apparatus

Angewandte Chemie International Edition in English ◽

10.1002/anie.197207981 ◽

1972 ◽

Vol 11 (9) ◽

pp. 798-820 ◽

Cited By ~ 85

Author(s):

Hans Kuhn

Keyword(s):

Self Organization ◽

Genetic Apparatus ◽

Molecular Systems

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Autonomous mesoscale positioning emerging from myelin filament self-organization and Marangoni flows

Nature Communications ◽

10.1038/s41467-020-18555-w ◽

2020 ◽

Vol 11 (1) ◽

Cited By ~ 1

Author(s):

Arno van der Weijden ◽

Mitch Winkens ◽

Sandra M. C. Schoenmakers ◽

Wilhelm T. S. Huck ◽

Peter A. Korevaar

Keyword(s):

Surface Tension ◽

Spatial Differentiation ◽

Self Organization ◽

Great Promise ◽

Mesoscopic Scale ◽

Molecular Systems ◽

Molecular Scale ◽

Filament Networks ◽

Non Equilibrium ◽

Marangoni Flows

Abstract Out-of-equilibrium molecular systems hold great promise as dynamic, reconfigurable matter that executes complex tasks autonomously. However, translating molecular scale dynamics into spatiotemporally controlled phenomena emerging at mesoscopic scale remains a challenge—especially if one aims at a design where the system itself maintains gradients that are required to establish spatial differentiation. Here, we demonstrate how surface tension gradients, facilitated by a linear amphiphile molecule, generate Marangoni flows that coordinate the positioning of amphiphile source and drain droplets floating at air-water interfaces. Importantly, at the same time, this amphiphile leads, via buckling instabilities in lamellar systems of said amphiphile, to the assembly of millimeter long filaments that grow from the source droplets and get absorbed at the drain droplets. Thereby, the Marangoni flows and filament organization together sustain the autonomous positioning of interconnected droplet-filament networks at the mesoscale. Our concepts provide potential for the development of non-equilibrium matter with spatiotemporal programmability.

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