Litcius/Paper detail

EMFF-2025: a general neural network potential for energetic materials with C, H, N, and O elements

Mingjie Wen, Jiahe Han, Wenjuan Li, Xiaoya Chang, Qingzhao Chu, Dongping Chen

2025npj Computational Materials35 citationsDOIOpen Access PDF

Abstract

The discovery and optimization of high-energy materials (HEMs) face challenges due to the computational expense and slow iteration of traditional methods. Neural network potentials (NNPs) have emerged as an efficient alternative to first-principles simulations. This study presents EMFF-2025, a general NNP model for C, H, N, and O-based HEMs, leveraging transfer learning with minimal data from DFT calculations. The model achieves DFT-level accuracy, predicting the structure, mechanical properties, and decomposition characteristics of 20 HEMs. Integrating EMFF-2025 with PCA and correlation heatmaps, we map the chemical space and structural evolution of these HEMs across temperatures. Surprisingly, EMFF-2025 uncovers that most HEMs follow similar high-temperature decomposition mechanisms, challenging the conventional view of material-specific behavior. EMFF-2025 offers a versatile computational framework for accelerating HEM design and optimization.

Topics & Concepts

DecompositionArtificial neural networkComputer scienceArtificial intelligenceComputational modelFace (sociological concept)Representation (politics)Machine learningAlgorithmBiological systemChemical spaceSpace (punctuation)Deep learningData modelingMathematical modelComputationPerspective (graphical)Data miningComputational complexity theoryEnergetic Materials and CombustionMachine Learning in Materials ScienceHigh-pressure geophysics and materials
EMFF-2025: a general neural network potential for energetic materials with C, H, N, and O elements | Litcius