Machine learning-based correction for spin-orbit coupling effects in NMR chemical shift calculations.
Julius B StückrathStefan GrimmeMarkus BurschPublished in: Physical chemistry chemical physics : PCCP (2024)
As one of the most powerful analytical methods for molecular and solid-state structure elucidation, NMR spectroscopy is an integral part of chemical laboratories associated with a great research interest in its computational simulation. Particularly when heavy atoms are present, a relativistic treatment is essential in the calculations as these influence also the nearby light atoms. In this work, we present a Δ-machine learning method that approximates the contribution to 13 C and 1 H NMR chemical shifts that stems from spin-orbit (SO) coupling effects. It is built on computed reference data at the spin-orbit zeroth-order regular approximation (ZORA) DFT level for a set of 6388 structures with 38 740 13 C and 64 436 1 H NMR chemical shifts. The scope of the methods covers the 17 most important heavy p-block elements that exhibit heavy atom on the light atom (HALA) effects to covalently bound carbon or hydrogen atoms. Evaluated on the test data set, the approach is able to recover roughly 85% of the SO contribution for 13 C and 70% for 1 H from a scalar-relativistic PBE0/ZORA-def2-TZVP calculation at virtually no extra computational costs. Moreover, the method is transferable to other baseline DFT methods even without retraining the model and performs well for realistic organotin and -lead compounds. Finally, we show that using a combination of the new approach with our previous Δ-ML method for correlation contributions to NMR chemical shifts, the mean absolute NMR shift deviations from non-relativistic DFT calculations to experimental values can be halved.
Keyphrases
- density functional theory
- solid state
- molecular dynamics
- machine learning
- high resolution
- magnetic resonance
- room temperature
- big data
- molecular dynamics simulations
- molecular docking
- artificial intelligence
- electronic health record
- monte carlo
- computed tomography
- electron transfer
- data analysis
- crystal structure
- combination therapy