Computer Research and Modeling
RUS  ENG    JOURNALS   PEOPLE   ORGANISATIONS   CONFERENCES   SEMINARS   VIDEO LIBRARY   PACKAGE AMSBIB  
General information
Latest issue
Archive

Search papers
Search references

RSS
Latest issue
Current issues
Archive issues
What is RSS



Computer Research and Modeling:
Year:
Volume:
Issue:
Page:
Find






Personal entry:
Login:
Password:
Save password
Enter
Forgotten password?
Register


Computer Research and Modeling, 2020, Volume 12, Issue 1, Pages 171–183
DOI: https://doi.org/10.20537/2076-7633-2020-12-1-171-183
(Mi crm778)
 

This article is cited in 1 scientific paper (total in 1 paper)

MODELS IN PHYSICS AND TECHNOLOGY

High-throughput identification of hydride phase-change kinetics models

I. A. Chernov

Institute of Applied Mathematical Research, Karelian Research Centre of RAS, 11 Pushkinskaya st., Petrozavodsk, 185910, Russia
Full-text PDF (160 kB) Citations (1)
References:
Abstract: Metal hydrides are an interesting class of chemical compounds that can reversibly bind a large amount of hydrogen and are, therefore, of interest for energy applications. Understanding the factors affecting the kinetics of hydride formation and decomposition is especially important. Features of the material, experimental setup and conditions affect the mathematical description of the processes, which can undergo significant changes during the processing of experimental data. The article proposes a general approach to numerical modeling of the formation and decomposition of metal hydrides and solving inverse problems of estimating material parameters from measurement data. The models are divided into two classes: diffusive ones, that take into account the gradient of hydrogen concentration in the metal lattice, and models with fast diffusion. The former are more complex and take the form of non-classical boundary value problems of parabolic type. A rather general approach to the grid solution of such problems is described. The second ones are solved relatively simply, but can change greatly when model assumptions change. Our experience in processing experimental data shows that a flexible software tool is needed; a tool that allows, on the one hand, building models from standard blocks, freely changing them if necessary, and, on the other hand, avoiding the implementation of routine algorithms. It also should be adapted for high-performance systems of different paradigms. These conditions are satisfied by the HIMICOS library presented in the paper, which has been tested on a large number of experimental data. It allows simulating the kinetics of formation and decomposition of metal hydrides, as well as related tasks, at three levels of abstraction. At the low level, the user defines the interface procedures, such as calculating the time layer based on the previous layer or the entire history, calculating the observed value and the independent variable from the task variables, comparing the curve with the reference. Special algorithms can be used for solving quite general parabolic-type boundary value problems with free boundaries and with various quasilinear (i.e., linear with respect to the derivative only) boundary conditions, as well as calculating the distance between the curves indifferent metric spaces and with different normalization. This is the middle level of abstraction. At the high level, it is enough to choose a ready tested model for a particular material and modify it in relation to the experimental conditions.
Keywords: metal hydrides, modelling phase transition kinetics, numerical simulation of chemical kinetics.
Received: 15.08.2019
Revised: 04.10.2019
Accepted: 18.10.2019
Document Type: Article
UDC: 519.6
Language: Russian
Citation: I. A. Chernov, “High-throughput identification of hydride phase-change kinetics models”, Computer Research and Modeling, 12:1 (2020), 171–183
Citation in format AMSBIB
\Bibitem{Che20}
\by I.~A.~Chernov
\paper High-throughput identification of hydride phase-change kinetics models
\jour Computer Research and Modeling
\yr 2020
\vol 12
\issue 1
\pages 171--183
\mathnet{http://mi.mathnet.ru/crm778}
\crossref{https://doi.org/10.20537/2076-7633-2020-12-1-171-183}
Linking options:
  • https://www.mathnet.ru/eng/crm778
  • https://www.mathnet.ru/eng/crm/v12/i1/p171
  • This publication is cited in the following 1 articles:
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
    Computer Research and Modeling
    Statistics & downloads:
    Abstract page:135
    Full-text PDF :26
    References:21
     
      Contact us:
     Terms of Use  Registration to the website  Logotypes © Steklov Mathematical Institute RAS, 2024