AI Article Synopsis
- A new method is introduced that uses a surrogate Gaussian process regression (GPR) model to enhance the efficiency of nudged elastic band (NEB) calculations for finding transition states.
- This approach removes the dependency on the number of moving images in the NEB process, making the search for transition states more effective and robust.
- The new convergence criteria utilize the uncertainty estimates from the GPR, resulting in significantly faster convergence without sacrificing accuracy in the energy barrier results compared to traditional NEB methods.
Article Abstract
We present the incorporation of a surrogate Gaussian process regression (GPR) atomistic model to greatly accelerate the rate of convergence of classical nudged elastic band (NEB) calculations. In our surrogate model approach, the cost of converging the elastic band no longer scales with the number of moving images on the path. This provides a far more efficient and robust transition state search. In contrast to a conventional NEB calculation, the algorithm presented here eliminates any need for manipulating the number of images to obtain a converged result. This is achieved by inventing a new convergence criteria that exploits the probabilistic nature of the GPR to use uncertainty estimates of all images in combination with the force in the saddle point in the target model potential. Our method is an order of magnitude faster in terms of function evaluations than the conventional NEB method with no accuracy loss for the converged energy barrier values.
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| http://dx.doi.org/10.1103/PhysRevLett.122.156001 | DOI Listing |
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