Turning statistical physics models into materials design engines

Abstract: Despite the success statistical physics has enjoyed at predicting the properties of materials for given parameters, the inverse problem, identifying which material parameters produce given, desired properties, is only beginning to be addressed. Recently, several methods have emerged across disciplines that draw upon optimization and simulation to create computer programs that tailor material responses to specified behaviors. However, so far the methods developed either involve black-box techniques, in which th… Show more

“…More recently, design approaches using inverse methods have been implemented. [8][9][10][11]18 In these cases, the forward simulation consists of a numerical engine to solve various trial morphologies by implementing, e.g., a self-consistent field theory, 69 a mean field model based on the Cahn-Hilliard equation, 10 or a theoretically informed coarse-grain model for block copolymers. 70 As before, the forward simulation is coupled to an inverse process that optimizes the parameter set in order to achieve a solution that closely approximates the targeted design.…”

“…70 As before, the forward simulation is coupled to an inverse process that optimizes the parameter set in order to achieve a solution that closely approximates the targeted design. In this regard, our recent work 10,11,18 has shown that evolutionary strategies such as CMA-ES can be significantly faster and more efficient in finding optimized solutions than inverse methods based on Monte Carlo searches. 8,9 In a typical design task corresponding to Fig.…”

“…71 An alternative approach is to use a physics based model, be it a self-consistent field theory or a molecular simulation, to interpret the data. While such a consideration would be overly demanding for traditional Monte Carlo-based strategies, by relying on CMA-ES versions and our more recently proposed variants, 10,11,18 it is possible to interpret scattering in terms of a fully three-dimensional particle based model that includes fluctuations. 72 Again, we highlight the fact here that, from a computational point of view, a computational engine is charged with designing a material that scatters x-rays in a manner dictated by the experiments.…”

“…We recently were able to show that the answer is yes, at least for design problems where the underlying physics can be described by models based on statistical mechanics. 18 Specifically, in situations where the macro-level outcome depends on the likelihood for a system to be in a particular micro-level configuration, knowledge of the probability distribution for these microstates can be used to derive an "equation of motion" for the parameters that encode these microstates. This equation deterministically calculates updates along directions of small entropy change in order to find new, improved parameter values.…”

“…It is able to use information about how fluctuations in configurations correspond to fluctuations in quality because it has been built to exploit the extra fact that the simulation data were generated from a known distribution. 18 Importantly, to create the probability distribution, the microstate statistics have to be evaluated only once during this evolution toward the design goal.…”

Perspective: Evolutionary design of granular media and block copolymer patterns

“…More recently, design approaches using inverse methods have been implemented. [8][9][10][11]18 In these cases, the forward simulation consists of a numerical engine to solve various trial morphologies by implementing, e.g., a self-consistent field theory, 69 a mean field model based on the Cahn-Hilliard equation, 10 or a theoretically informed coarse-grain model for block copolymers. 70 As before, the forward simulation is coupled to an inverse process that optimizes the parameter set in order to achieve a solution that closely approximates the targeted design.…”

“…70 As before, the forward simulation is coupled to an inverse process that optimizes the parameter set in order to achieve a solution that closely approximates the targeted design. In this regard, our recent work 10,11,18 has shown that evolutionary strategies such as CMA-ES can be significantly faster and more efficient in finding optimized solutions than inverse methods based on Monte Carlo searches. 8,9 In a typical design task corresponding to Fig.…”

“…71 An alternative approach is to use a physics based model, be it a self-consistent field theory or a molecular simulation, to interpret the data. While such a consideration would be overly demanding for traditional Monte Carlo-based strategies, by relying on CMA-ES versions and our more recently proposed variants, 10,11,18 it is possible to interpret scattering in terms of a fully three-dimensional particle based model that includes fluctuations. 72 Again, we highlight the fact here that, from a computational point of view, a computational engine is charged with designing a material that scatters x-rays in a manner dictated by the experiments.…”

“…We recently were able to show that the answer is yes, at least for design problems where the underlying physics can be described by models based on statistical mechanics. 18 Specifically, in situations where the macro-level outcome depends on the likelihood for a system to be in a particular micro-level configuration, knowledge of the probability distribution for these microstates can be used to derive an "equation of motion" for the parameters that encode these microstates. This equation deterministically calculates updates along directions of small entropy change in order to find new, improved parameter values.…”

“…It is able to use information about how fluctuations in configurations correspond to fluctuations in quality because it has been built to exploit the extra fact that the simulation data were generated from a known distribution. 18 Importantly, to create the probability distribution, the microstate statistics have to be evaluated only once during this evolution toward the design goal.…”

Perspective: Evolutionary design of granular media and block copolymer patterns

Machine Learning Predictions of Block Copolymer Self‐Assembly

The promise of artificial intelligence in chemical engineering: Is it here, finally?