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Article Abstract
Accurate theoretical prediction of EPR (electron paramagnetic resonance) spectra is crucial for elucidating reaction mechanisms, identifying unknown radicals, and guiding chemical transformations. This study introduces near-DFT (nuclear electron spin density approximation via radial functions for DFT), a novel computational approach that synthesizes two fundamental physical principles into a new predictive framework for the isotropic hyperfine coupling constant (). First, it systematically applies the Kato cusp condition to correctly describe electron spin density near the nucleus. Second, a pseudo-π orbital model, constrained by this condition, reveals that NLP-type (type of nitrogen-centered radical without a lone pair) mononitrogen radicals exhibit a significant SOP (spin orbit polarization) effect compared to the predominantly SP (spin polarization) effect for LP-type (type of nitrogen-centered radical with a lone pair) radicals. Building upon these insights, near-DFT demonstrates high accuracy in predicting EPR parameters (within 5% of experimental values) for both mononitrogen and complex polynitrogen radicals, offering a robust and efficient tool for the precise interpretation of EPR spectra. This method also saves significant calculation time compared to CCSD.
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