Atomistic QM/MM simulations of the strength of covalent interfaces in carbon nanotube–polymer composites

2020

Bo Qiao, Somesh Mohapatra, Jeffrey Lopez, Graham Leverick, Ryoichi Tatara, Yoshiki Shibuya, Yivan Jiang, Arthur France-Lanord, Jeffrey C. Grossman, Rafael Gomez-Bombarelli, Jeremiah Johnson, Yang Shao-Horn

ChemRxiv

Molecular details often dictate the macroscopic properties of materials, yet, due to their vastly different length scales, relationships between molecular structure and bulk properties are often difficult to predict a priori, requiring Edisonian optimizations and preventing rational design. Here, we introduce an easy-to-execute strategy based on linear free energy relationships (LFERs) that enables quantitative correlation and prediction of how molecular modifications, i.e., substituents, impact the ensemble properties of materials. First, we developed substituent parameters based on inexpensive, DFT-computed energetics of elementary pairwise interactions between a given substituent and other constant components of the material. These substituent parameters were then used as inputs to regression analyses of experimentally measured bulk properties, generating a predictive statistical model. We applied this approach to a widely studied class of electrolyte materials: oligo-ethylene glycol (OEG)-LiTFSI mixtures; the resulting model enables elucidation of fundamental physical principles that govern the properties of these electrolytes and also enables prediction of the properties of novel, improved OEG-LiTFSI-based electrolytes. The framework presented here for using context-specific substituent parameters will potentially enhance the throughput of screening new molecular designs for next-generation energy storage devices and other materials-oriented contexts where classical substituent parameters (e.g., Hammett parameters) may not be available or effective.

  • linkedin3
  • Twitter Social Icon
  • YouTube Social  Icon
  • Facebook Social Icon
  • Researchgate

© 2021 by Materials Design, Inc. 

Privacy Policy
Materials Design® and MedeA® are registered trademarks of Materials Design, Inc.