The Fuzziness in Molecular, Supramolecular, and Systems Chemistry

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Autore:	Gentili Pier
Titolo:	The Fuzziness in Molecular, Supramolecular, and Systems Chemistry
Pubblicazione:	Basel, Switzerland, : MDPI - Multidisciplinary Digital Publishing Institute, 2020
Descrizione fisica:	1 electronic resource (154 p.)
Soggetto topico:	Research & information: general
	Biology, life sciences
Soggetto non controllato:	fuzzy logic
	complexity
	chemical artificial intelligence
	human nervous system
	fuzzy proteins
	conformations
	photochromic compounds
	qubit
	protein dynamics
	conformational heterogeneity
	promiscuity
	fuzzy complexes
	higher-order structures
	protein evolution
	fuzzy set theory
	artificial intelligence
	GCN4 mimetic
	peptides-DNA
	E:Z photoisomerization
	conformational fuzziness
	photoelectrochemistry
	wide bandgap semiconductor
	artificial neuron
	in materio computing
	neuromorphic computing
	intrinsically disordered protein
	intrinsically disordered protein region
	liquid-liquid phase transition
	protein-protein interaction
	protein-nucleic acid interaction
	proteinaceous membrane-less organelle
	fuzzy complex
	d-TST
	activation energy
	Transitivity plot
	solution kinetic
	Maxwell-Boltzmann path
	Euler's formula for the exponential
	activation
	transitivity
	transport phenomena
	moonlighting proteins
	intrinsically disordered proteins
	metamorphic proteins
	morpheeins
Persona (resp. second.):	GentiliPier
Sommario/riassunto:	Fuzzy Logic is a good model for the human ability to compute words. It is based on the theory of fuzzy set. A fuzzy set is different from a classical set because it breaks the Law of the Excluded Middle. In fact, an item may belong to a fuzzy set and its complement at the same time and with the same or different degree of membership. The degree of membership of an item in a fuzzy set can be any real number included between 0 and 1. This property enables us to deal with all those statements of which truths are a matter of degree. Fuzzy logic plays a relevant role in the field of Artificial Intelligence because it enables decision-making in complex situations, where there are many intertwined variables involved. Traditionally, fuzzy logic is implemented through software on a computer or, even better, through analog electronic circuits. Recently, the idea of using molecules and chemical reactions to process fuzzy logic has been promoted. In fact, the molecular word is fuzzy in its essence. The overlapping of quantum states, on the one hand, and the conformational heterogeneity of large molecules, on the other, enable context-specific functions to emerge in response to changing environmental conditions. Moreover, analog input–output relationships, involving not only electrical but also other physical and chemical variables can be exploited to build fuzzy logic systems. The development of “fuzzy chemical systems” is tracing a new path in the field of artificial intelligence. This new path shows that artificially intelligent systems can be implemented not only through software and electronic circuits but also through solutions of properly chosen chemical compounds. The design of chemical artificial intelligent systems and chemical robots promises to have a significant impact on science, medicine, economy, security, and wellbeing. Therefore, it is my great pleasure to announce a Special Issue of Molecules entitled “The Fuzziness in Molecular, Supramolecular, and Systems Chemistry.” All researchers who experience the Fuzziness of the molecular world or use Fuzzy logic to understand Chemical Complex Systems will be interested in this book.
Titolo autorizzato:	The Fuzziness in Molecular, Supramolecular, and Systems Chemistry
Formato:	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione:	Inglese
Record Nr.:	9910557495003321
Lo trovi qui:	Univ. Federico II
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