Data centric nanocomposites design: Via mixed-variable Bayesian optimization

Keyphrases

• Nanocomposite Design 100%
• Data-centric 100%
• Mixed Variables 100%
• Bayesian Optimization 100%
• Design Space 50%
• Polymer Nanocomposites 50%
• Data-driven Design 50%
• Variable Design 50%
• Optimal Microstructures 50%
• Material Design 25%
• Nanoparticles 25%
• Surface Modification 25%
• Computationally Expensive 25%
• Dielectric Properties 25%
• Mechanical Properties 25%
• Design Framework 25%
• Design Process 25%
• Machine Learning 25%
• Effective Approach 25%
• State-of-the-art Techniques 25%
• Project Data 25%
• Polymer Nanoparticles 25%
• Nanocomposite Materials 25%
• Challenging Tasks 25%
• Interphase Model 25%
• Model Properties 25%
• Design of Engineered Materials System 25%
• Microstructure Characterization 25%
• Polymer Surface 25%
• Electrical Properties 25%
• Multi-criteria Optimization 25%
• Lack of Data 25%
• Uncertain Data 25%
• Electrically Insulating 25%
• Cost Simulation 25%
• Microstructure Reconstruction 25%
• Optimal Composition 25%
• Pareto Frontier 25%
• Fixed Combination 25%
• Geometric Arrangement 25%
• Polymer Modification 25%
• Dielectric Loss 25%
• Dielectric Permittivity 25%
• Surface Microstructure 25%
• Nanoparticle Modification 25%
• Dielectric Breakdown Strength 25%
• Multiple Industries 25%
• Latent Gaussian Process 25%

Material Science

• Nanocomposite 100%
• Polymer Nanocomposites 50%
• Dielectric Property 25%
• Materials Design 25%
• Microstructure Characterization 25%
• Permittivity 25%
• Polymer Nanoparticles 25%
• Surface Modification 25%
• Electrical Breakdown 25%
• Property Modeling 25%
• Nanoparticle 25%
• Dielectric Material 25%

Engineering

• Nanocomposites 100%
• Dielectrics 50%
• Design Space 33%
• Nanoparticles 33%
• Optimisation Problem 16%
• Design Process 16%
• Material System 16%
• Effective Approach 16%
• Gaussians 16%
• State-of-the-Art Technique 16%
• Pareto Frontier 16%
• Dielectric Loss 16%
• Learning System 16%