Phase Transition as an Emergent Phenomenon Analysed by Violation of Structural Invariant (M, BM)

  • Jiri Bila Department of Instrumentation and Control Engineering, Czech Technical University in Prague, Czech Republic
  • Ali H Reshak Department of Instrumentation and Control Engineering, Czech Technical University in Prague, Czech Republic
  • Jan Chysky Department of Instrumentation and Control Engineering, Czech Technical University in Prague, Czech Republic
DOI: https://doi.org/10.13164/mendel.2020.2.045
Keywords: Modeling of complex systems, structural invariant, matroid, matroid bases, Ramsey theory of graph, phase transition

Abstract

When modeling complex systems, we usually encounter the following difficulties: partiality, large amounts of data and uncertainty of conclusions. The most common approach used for modeling is the physical approach, sometimes reinforced by statistical procedures. If we assume emergences in the complex system, a physical approach is not appropriate at all. Instead, we build here the approach of structural invariants. In this paper, we show that another plane can be built above the plane of physical description, which is responsible for violation of structural invariants. Main attention is concentrated (in this article) on the invariant matroid and bases of matroid (M, BM) in combination with Ramsey graph theory. In addition, the article introduces a calculus that describes the emergent phenomena using two quantities - the power of the emergent phenomenon and the complexity of the structure of the considered complex system. We show the application of the method for modeling phase transition in chemistry.

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Published
2020-12-21
How to Cite
[1]
Bila, J., Reshak, A. and Chysky, J. 2020. Phase Transition as an Emergent Phenomenon Analysed by Violation of Structural Invariant (M, BM). MENDEL. 26, 2 (Dec. 2020), 45-50. DOI:https://doi.org/10.13164/mendel.2020.2.045.
Issue
Vol 26 No 2 (2020): MENDEL
Section
Research articles

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