Combining thermodynamics with tensor completion techniques to enable multicomponent microstructure prediction

Abstract: Multicomponent alloys show intricate microstructure evolution, providing materials engineers with a nearly inexhaustible variety of solutions to enhance material properties. Multicomponent microstructure evolution simulations are indispensable to exploit these opportunities. These simulations, however, require the handling of high-dimensional and prohibitively large data sets of thermodynamic quantities, of which the size grows exponentially with the number of elements in the alloy, making it virtually impossi… Show more

“…For systems with much larger number of components, the interfacing of an advanced thermodynamic database with a phase-field solver may become a computational issue and thus, the use of an approximate albeit accurate thermodynamic representation derived from CALPHAD databases (see [43]) might be considered.…”

“…In most cases, a 〈〈 local 〉〉 energy minimization is involved (e.g. local equilibrium of redox mechanisms in [26]) and the interfacing of a CALPHAD thermodynamic description with a phase-field becomes a computational issue to be handled with care [43]. The use of a thermodynamic solver (Gibbs energy minimizer) provides in fact an exact and continuous representation of the composition dependence of the CALPHAD Gibbs energies.…”

Phase-field modeling with the TAF-ID of incipient melting and oxygen transport in nuclear fuel during power transients

“…For systems with much larger number of components, the interfacing of an advanced thermodynamic database with a phase-field solver may become a computational issue and thus, the use of an approximate albeit accurate thermodynamic representation derived from CALPHAD databases (see [43]) might be considered.…”

“…In most cases, a 〈〈 local 〉〉 energy minimization is involved (e.g. local equilibrium of redox mechanisms in [26]) and the interfacing of a CALPHAD thermodynamic description with a phase-field becomes a computational issue to be handled with care [43]. The use of a thermodynamic solver (Gibbs energy minimizer) provides in fact an exact and continuous representation of the composition dependence of the CALPHAD Gibbs energies.…”

Phase-field modeling with the TAF-ID of incipient melting and oxygen transport in nuclear fuel during power transients

“…Another purpose of utilizing HEAs is in the development of hierarchical nanostructures that can demonstrate stability and compatibility while simultaneously possessing soft and hard phases, or in general with two extremely opposite physico-chemical properties [11]. In other words, HEAs or MPEAs are attributed with a wide range of properties or combination of physicochemical properties that are otherwise impossible to attain with alloys having a single major element [12]. These multitude of characteristics associated with MPEAs enable them to be categorized in the list of materials for future.…”

pyMPEALab Toolkit for Accelerating Phase Design in Multi-principal Element Alloys

“…The ubiquity in our big data era of data with (explicitly or implicitly) multiple dimensions/relations that are often incomplete and/or uncertain has given rise to numerous applications of tensor completion [1], such as image and video in-painting [2], hyperspectral imaging [3], prediction of multi-dimensional non-stationary wireless channels [4] semiconductor manufacturing [5], and computational materials science [6], to name only a few. Though still lacking in sufficient theoretical foundations and algorithmic variety when compared to its matrix-based counterpart, tensor completion has already a quite rich literature [1], which includes (among other approaches) methods based on lowrank decomposition models.…”

Rank-Revealing Block-Term Decomposition for Tensor Completion