Related papers: InvDesFlow: An AI search engine to explore possible high-temperature superconductors

InvDesFlow: An AI search engine to explore possible high-temperature superconductors

URL: http://arxiv.org/abs/2409.08065v2
Date: Mon, 02 Dec 2024 14:29:14 GMT
Title: InvDesFlow: An AI search engine to explore possible high-temperature superconductors
Authors: Xiao-Qi Han, Zhenfeng Ouyang, Peng-Jie Guo, Hao Sun, Ze-Feng Gao, Zhong-Yi Lu,
Abstract summary: InvDesFlow is an AI search engine that integrates deep model pre-training and fine-tuning techniques, diffusion models, and physics-based approaches. We have obtained 74 dynamically stable materials with critical temperatures predicted by the AI model to be $T_c geq$ 15 K based on a very small set of samples.
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Abstract: The discovery of new superconducting materials, particularly those exhibiting high critical temperature ($T_c$), has been a vibrant area of study within the field of condensed matter physics. Conventional approaches primarily rely on physical intuition to search for potential superconductors within the existing databases. However, the known materials only scratch the surface of the extensive array of possibilities within the realm of materials. Here, we develop InvDesFlow, an AI search engine that integrates deep model pre-training and fine-tuning techniques, diffusion models, and physics-based approaches (e.g., first-principles electronic structure calculation) for the discovery of high-$T_c$ superconductors. Utilizing InvDesFlow, we have obtained 74 dynamically stable materials with critical temperatures predicted by the AI model to be $T_c \geq$ 15 K based on a very small set of samples. Notably, these materials are not contained in any existing dataset. Furthermore, we analyze trends in our dataset and individual materials including B$_4$CN$_3$ (at 5 GPa) and B$_5$CN$_2$ (at ambient pressure) whose $T_c$s are 24.08 K and 15.93 K, respectively. We demonstrate that AI technique can discover a set of new high-$T_c$ superconductors, outline its potential for accelerating discovery of the materials with targeted properties.

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