De Novo Design of Molecules with Low Hole Reorganization Energy Based on a Quarter-Million Molecule DFT Screen: Part 2.

Organic semiconductors have many desirable properties including improved manufacturing and flexible mechanical properties. Due to the vastness of chemical space, it is essential to efficiently explore chemical space when designing new materials, including through the use of generative techniques. New generative machine learning methods for molecular design continue to be published in the literature at a significant rate but successfully adapting methods to new chemistry and problem domains remains difficult. These challenges necessitate continual method evaluation to probe method viability for use in alternative applications not covered in the original works. In continuation of our previous work, we evaluate four additional machine-learning-based de novo methods for generating molecules with high predicted hole mobility for use in semiconductor applications. The four generative methods evaluated here are (1) Molecule Deep Q-Networks (MolDQN), which utilizes Deep-Q learning to directly optimize molecular structure graphs for desired properties instead of generating SMILES, (2) Graph-based Genetic Algorithm (GraphGA), which uses a genetic algorithm for optimization where crossovers and mutations are defined in terms of RDKit's reaction SMILES, (3) Generative Tensorial Reinforcement Learning (GENTRL), which is a variational autoencoder (VAE) with a learned prior distribution and optimized using reinforcement learning, and (4) Monte Carlo tree search exploration of chemical space in conjunction with a recurrent neural network (RNN) decoder (ChemTS). The generated molecules were evaluated using density functional theory (DFT) and we discovered better performing molecules with the GraphGA method compared to the other approaches.

[1]  M. Halls,et al.  De Novo Design of Molecules with Low Hole Reorganization Energy Based on a Quarter-Million Molecule DFT Screen. , 2021, The journal of physical chemistry. A.

[2]  Oskar J. Sandberg,et al.  A History and Perspective of Non‐Fullerene Electron Acceptors for Organic Solar Cells , 2021, Advanced Energy Materials.

[3]  M. Halls,et al.  Massive Theoretical Screen of Hole Conducting Organic Materials in the Heteroacene Family by Using a Cloud Computing Environment. , 2020, The journal of physical chemistry. A.

[4]  C. B. Nielsen,et al.  The role of chemical design in the performance of organic semiconductors , 2020, Nature Reviews Chemistry.

[5]  Alán Aspuru-Guzik,et al.  Deep learning enables rapid identification of potent DDR1 kinase inhibitors , 2019, Nature Biotechnology.

[6]  Yong‐Young Noh,et al.  Printable Semiconductors for Backplane TFTs of Flexible OLED Displays , 2019, Advanced Functional Materials.

[7]  K. Mirica,et al.  Electrically-Transduced Chemical Sensors Based on Two-Dimensional Nanomaterials. , 2019, Chemical reviews.

[8]  Marwin H. S. Segler,et al.  GuacaMol: Benchmarking Models for De Novo Molecular Design , 2018, J. Chem. Inf. Model..

[9]  Li Li,et al.  Optimization of Molecules via Deep Reinforcement Learning , 2018, Scientific Reports.

[10]  Alán Aspuru-Guzik,et al.  Automatic Chemical Design Using a Data-Driven Continuous Representation of Molecules , 2016, ACS central science.

[11]  Demis Hassabis,et al.  Mastering the game of Go without human knowledge , 2017, Nature.

[12]  Koji Tsuda,et al.  ChemTS: an efficient python library for de novo molecular generation , 2017, Science and technology of advanced materials.

[13]  Li Gao Flexible Device Applications of 2D Semiconductors. , 2017, Small.

[14]  Thomas Blaschke,et al.  Molecular de-novo design through deep reinforcement learning , 2017, Journal of Cheminformatics.

[15]  Suchol Savagatrup,et al.  Mechanical Properties of Organic Semiconductors for Stretchable, Highly Flexible, and Mechanically Robust Electronics. , 2017, Chemical reviews.

[16]  Woody Sherman,et al.  AutoQSAR: an automated machine learning tool for best-practice quantitative structure-activity relationship modeling. , 2016, Future medicinal chemistry.

[17]  M. Oh-e,et al.  Estimation of charge carrier mobility in amorphous organic materials using percolation corrected random-walk model , 2016 .

[18]  Jennifer L. Knight,et al.  OPLS3: A Force Field Providing Broad Coverage of Drug-like Small Molecules and Proteins. , 2016, Journal of chemical theory and computation.

[19]  Pascal Friederich,et al.  Ab Initio Treatment of Disorder Effects in Amorphous Organic Materials: Toward Parameter Free Materials Simulation. , 2014, Journal of chemical theory and computation.

[20]  Jing Zhang,et al.  Jaguar: A high-performance quantum chemistry software program with strengths in life and materials sciences , 2013 .

[21]  G. V. Paolini,et al.  Quantifying the chemical beauty of drugs. , 2012, Nature chemistry.

[22]  David Rogers,et al.  Extended-Connectivity Fingerprints , 2010, J. Chem. Inf. Model..

[23]  Peter Ertl,et al.  Estimation of synthetic accessibility score of drug-like molecules based on molecular complexity and fragment contributions , 2009, J. Cheminformatics.

[24]  Federico D. Sacerdoti,et al.  Scalable Algorithms for Molecular Dynamics Simulations on Commodity Clusters , 2006, ACM/IEEE SC 2006 Conference (SC'06).

[25]  Ghassan E. Jabbour,et al.  Organic-Based Photovoltaics: Toward Low-Cost Power Generation , 2005 .

[26]  William A. Goddard,et al.  Predictions of Hole Mobilities in Oligoacene Organic Semiconductors from Quantum Mechanical Calculations , 2004 .

[27]  W. L. Jorgensen,et al.  Development and Testing of the OPLS All-Atom Force Field on Conformational Energetics and Properties of Organic Liquids , 1996 .

[28]  A. Becke Density-functional thermochemistry. III. The role of exact exchange , 1993 .

[29]  David Weininger,et al.  SMILES, a chemical language and information system. 1. Introduction to methodology and encoding rules , 1988, J. Chem. Inf. Comput. Sci..

[30]  W. R. Wadt,et al.  Ab initio effective core potentials for molecular calculations. Potentials for main group elements Na to Bi , 1985 .

[31]  W. R. Wadt,et al.  Ab initio effective core potentials for molecular calculations. Potentials for K to Au including the outermost core orbitals , 1985 .

[32]  W. R. Wadt,et al.  Ab initio effective core potentials for molecular calculations , 1984 .

[33]  J. Pople,et al.  Self‐Consistent Molecular‐Orbital Methods. IX. An Extended Gaussian‐Type Basis for Molecular‐Orbital Studies of Organic Molecules , 1971 .

[34]  Rudolph A. Marcus,et al.  On the Theory of Electron-Transfer Reactions. VI. Unified Treatment for Homogeneous and Electrode Reactions , 1965 .

[35]  D J Rogers,et al.  A Computer Program for Classifying Plants. , 1960, Science.

[36]  Rudolph A. Marcus,et al.  On the Theory of Oxidation‐Reduction Reactions Involving Electron Transfer. I , 1956 .