S. Cohen, T.O. Sedgwick, et al.
MRS Proceedings 1983
Data-driven synthesis planning has seen remarkable successes in recent years by virtue of modern approaches of artificial intelligence that efficiently exploit vast databases with experimental data on chemical reactions. However, this success story is intimately connected to the availability of existing experimental data. It may well occur in retrosynthetic and synthesis design tasks that predictions in individual steps of a reaction cascade are affected by large uncertainties. In such cases, it will, in general, not be easily possible to provide missing data from autonomously conducted experiments on demand. However, first-principles calculations can, in principle, provide missing data to enhance the confidence of an individual prediction or for model retraining. Here, we demonstrate the feasibility of such an ansatz and examine resource requirements for conducting autonomous first-principles calculations on demand.
S. Cohen, T.O. Sedgwick, et al.
MRS Proceedings 1983
Shiyi Chen, Daniel Martínez, et al.
Physics of Fluids
S.F. Fan, W.B. Yun, et al.
Proceedings of SPIE 1989
J.H. Kaufman, Owen R. Melroy, et al.
Synthetic Metals