Benchmark Calculations of K-Edge Ionization Energies for First-Row Elements Using Scalar-Relativistic Core–Valence-Separated Equation-of-Motion Coupled-Cluster Methods

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“…The reduced absolute shifts from experiments compared to the previously presented CVS-CCSD approach 28 are most likely due to effective error cancellation between the neglect of core correlation in the ground state, its inclusion in the excited states and the neglect of higher-order correlation and excitation effects in the (EOM-)CCSD method. Even if one can argue that triple and higher excitation effects (as well as relativistic effects) are required to attain fully quantitative agreement with experiment, 103,104 we believe that the results reported here give plenty of evidence that our ab initio approach is a useful addition to the toolbox of computational spectroscopy: it offers a robust, black-box, and reliable scheme for the interpretation of modern X-ray experiments, at a lower computational cost and more efficiently than the previously proposed CVS scheme, 28…”

New and Efficient Equation-of-Motion Coupled-Cluster Framework for Core-Excited and Core-Ionized States

“…The reduced absolute shifts from experiments compared to the previously presented CVS-CCSD approach 28 are most likely due to effective error cancellation between the neglect of core correlation in the ground state, its inclusion in the excited states and the neglect of higher-order correlation and excitation effects in the (EOM-)CCSD method. Even if one can argue that triple and higher excitation effects (as well as relativistic effects) are required to attain fully quantitative agreement with experiment, 103,104 we believe that the results reported here give plenty of evidence that our ab initio approach is a useful addition to the toolbox of computational spectroscopy: it offers a robust, black-box, and reliable scheme for the interpretation of modern X-ray experiments, at a lower computational cost and more efficiently than the previously proposed CVS scheme, 28…”

New and Efficient Equation-of-Motion Coupled-Cluster Framework for Core-Excited and Core-Ionized States

“…Solutions using complex‐valued approaches exist but are associated with increased cost . Simply neglecting the continuum coupling altogether using CVS gives good results and is better than using a poor continuum description …”

Efficient calculations of a large number of highly excited states for multiconfigurational wavefunctions

“…The reduced absolute shifts from experiments compared to the previously presented CVS-CCSD approach 28 are most likely due to effective error cancellation between the neglect of core correlation in the ground state, its inclusion in the excited states and the neglect of Theory and Computation 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 can argue that triple and higher excitation effects (as well as relativistic effects) are required to attain fully quantitative agreement with experiment, 103,104 we believe that the results reported here give plenty of evidence that our ab initio approach is a useful addition to the toolbox of computational spectroscopy: it offers a robust, black-box, and reliable scheme for the interpretation of modern X-ray experiments, at a lower computational cost and more efficiently than the previously proposed CVS scheme, 28…”

A New and Efficient Equation-of-Motion Coupled-Cluster Framework for Core-Excited and Core-Ionized States