Efficient catalyst screening necessitates predictive models for adsorption energy, a key property of reactivity. However, prevailing methods, notably graph neural networks (GNNs), demand precise atomic coordinates for constructing graph representations, while integrating observable attributes remains challenging. This research introduces CatBERTa, an energy prediction Transformer model using textual inputs. Built on a pretrained Transformer encoder, CatBERTa processes human-interpretable text, incorporating target features. Attention score analysis reveals CatBERTa's focus on tokens related to adsorbates, bulk composition, and their interacting atoms. Moreover, interacting atoms emerge as effective descriptors for adsorption configurations,...
Nano-catalyst design, supplanting critical/rare metals with earth-abundant elements, for hydrogen ev...
Accurate prediction of adsorption energies on heterogeneous catalyst surfaces is crucial to predicti...
We present an application of deep-learning convolutional neural network of atomic surface structures...
Computational catalyst screening has the potential to significantly accelerate heterogeneous catalys...
The discovery of new catalysts is one of the significant topics of computational chemistry as it has...
In the last 50 years, increasing human populations have resulted in three times more fossil fuels co...
Computation of adsorption and transition-state energies for a large number of surface intermediates ...
Mitigating the climate crisis requires a rapid transition towards lower carbon energy. Catalyst mate...
The binding energy of small molecules on two‐dimensional (2D) single atom catalysts influences their...
Heterogeneous catalysis is the central pillar of chemical industry, but they are mostly developed vi...
Designing heterogeneous catalysts that have improved activity, selectivity and reduced cost are the ...
Heterogeneous catalysts are rather complex materials that come in many classes (e.g., metals, oxides...
We investigate the graph-based convolutional neural network approach for predicting and ranking gas ...
This work aims to address the challenge of developing interpretable ML-based models when access to l...
The development of machine learned potentials for catalyst discovery has predominantly been focused ...
Nano-catalyst design, supplanting critical/rare metals with earth-abundant elements, for hydrogen ev...
Accurate prediction of adsorption energies on heterogeneous catalyst surfaces is crucial to predicti...
We present an application of deep-learning convolutional neural network of atomic surface structures...
Computational catalyst screening has the potential to significantly accelerate heterogeneous catalys...
The discovery of new catalysts is one of the significant topics of computational chemistry as it has...
In the last 50 years, increasing human populations have resulted in three times more fossil fuels co...
Computation of adsorption and transition-state energies for a large number of surface intermediates ...
Mitigating the climate crisis requires a rapid transition towards lower carbon energy. Catalyst mate...
The binding energy of small molecules on two‐dimensional (2D) single atom catalysts influences their...
Heterogeneous catalysis is the central pillar of chemical industry, but they are mostly developed vi...
Designing heterogeneous catalysts that have improved activity, selectivity and reduced cost are the ...
Heterogeneous catalysts are rather complex materials that come in many classes (e.g., metals, oxides...
We investigate the graph-based convolutional neural network approach for predicting and ranking gas ...
This work aims to address the challenge of developing interpretable ML-based models when access to l...
The development of machine learned potentials for catalyst discovery has predominantly been focused ...
Nano-catalyst design, supplanting critical/rare metals with earth-abundant elements, for hydrogen ev...
Accurate prediction of adsorption energies on heterogeneous catalyst surfaces is crucial to predicti...
We present an application of deep-learning convolutional neural network of atomic surface structures...