https://qtcovi.github.io/tag/ai-in-chemistry/AI in ChemistryHugo Blox Builder (https://hugoblox.com)en-usMon, 01 Jan 2024 00:00:00 +0000https://qtcovi.github.io/media/icon_hu11734318148517933569.pnghttps://qtcovi.github.io/tag/ai-in-chemistry/https://qtcovi.github.io/research/machine-learning-chemistry/Mon, 01 Jan 2024 00:00:00 +0000https://qtcovi.github.io/research/machine-learning-chemistry/<h2 id="overview">Overview</h2> <p>Machine learning is transforming computational chemistry, and we are harnessing it in two complementary ways:</p> <h3 id="iqa-informed-neural-network-potentials">IQA-Informed Neural Network Potentials</h3> <p>Classical machine-learned interatomic potentials (NNPs) are trained on total energies and forces, but lack chemical interpretability. We develop NNPs informed by IQA energy components (self-energies and interaction energies), resulting in potentials that:</p> <ul> <li>Decompose into physically meaningful atomic and pairwise contributions.</li> <li>Transfer more reliably to out-of-distribution chemical environments.</li> <li>Naturally encode the correct physics of bonding interactions.</li> </ul> <h3 id="topological-descriptors-as-ml-features">Topological Descriptors as ML Features</h3> <p>QTAIM atomic properties and IQA energy components serve as physically motivated features for machine learning models targeting molecular properties, reaction barriers, and drug–target binding affinities.</p> <h3 id="deep-learning-for-electron-density">Deep Learning for Electron Density</h3> <p>We explore the use of deep learning models to predict electron densities directly, enabling rapid computation of topological properties for large molecular datasets.</p> <h2 id="codes--tools">Codes &amp; Tools</h2> <p>Our ML work builds on open-source frameworks (PyTorch, JAX) and is integrated with our in-house topological analysis codes.</p>