We present a computational study of magnetic-shielding and
quadrupolar-coupling tensors of 43Ca sites in crystalline solids.
A comparison between periodic and cluster-based approaches
for modeling solid-state interactions demonstrates that clusterbased
approaches are suitable for predicting 43Ca NMR parameters.
Several model chemistries, including Hartree–Fock theory
and 17 DFT approximations (SVWN, CA-PZ, PBE, PBE0,
PW91, B3PW91, rPBE, PBEsol, WC, PKZB, BMK, M06-L, M06,
M06-2X, M06-HF, TPSS, and TPSSh), are evaluated for the
prediction of 43Ca NMR parameters. Convergence of NMR
parameters with respect to basis sets of the form cc-pVXZ
(X5D, T, Q) is also evaluated. All DFT methods lead to substantial,
and frequently systematic, overestimations of experimental
chemical shifts. Hartree–Fock calculations outperform
all DFT methods for the prediction of 43Ca chemical-shift tensors.
VC 2017 Wiley Periodicals, Inc.
DOI: 10.1002/jcc.24763
Revised: November 6, 2020 |
Published: May 15, 2017
Citation
Holmes S.T., S. Bai, R.J. Iuliucci, K.T. Mueller, and C. Dybowski. 2017.Calculations of Solid-State 43Ca NMR Parameters: A Comparison of Periodic and Cluster Approaches and an Evaluation of DFT Functionals.Journal of Computational Chemistry 38, no. 13:949-956.PNNL-SA-126295.doi:10.1002/jcc.24763