Add to ORKGWe present a new method for computing NMR chemical shifts and magnetic susceptibilities in extended systems through an ab initio density functional perturbation theory approach. The method is applicable to crystalline and amorphous insulators under periodic boundary conditions, as well as to isolated molecules. The formalism exploits the exponentially decaying nature of localized Wannier orbitals. We have implemented the method in the context of a plane wave pseudopotential approach. The results are in good agreement with experiment and with calculations that use other theoretical methods. I
We present an implementation of time-dependent density functional perturbation theory for spin fluct...
Computational methods are increasingly used to support interpreting, assigning and predicting the so...
A method for the ab initio prediction of the EPR g tensor for paramagnetic defects in systems under ...
A recently developed ab-initio method for the calculation of NMR chemical shifts and magnetic suscep...
In dieser Dissertation wird eine neue Methode zur Berechnung von NMR chemischen Verschiebungen und m...
We present a theory for the ab initio computation of NMR chemical shifts (sigma) in condensed matter...
A theory for the ab initio calculation of all-electron NMR chemical shifts in insulators using pseud...
We review the development of electronic structure methods for the calculation of nuclear magnetic re...
A DFT-based method is presented which allows the computation of all-electron NMR shifts of metallic ...
We extend the recently developed converse NMR approach [Thonhauser et al., J. Chem. Phys. 131, 10110...
We introduce a method for the all-electron calculation of the NMR chemical shifts and the EPR g tens...
The conceptual and numerical problems involved in the computation of reliable NMR chemical shifts fo...
We present a scheme for the calculation of magnetic response parameters in insulators using ultrasof...
We present a theoretical investigation of the hydrogen nuclear magnetic resonance (NMR) chemical shi...
We propose a new hybrid approach combining quantum chemistry and statistical mechanics of liquids fo...
We present an implementation of time-dependent density functional perturbation theory for spin fluct...
Computational methods are increasingly used to support interpreting, assigning and predicting the so...
A method for the ab initio prediction of the EPR g tensor for paramagnetic defects in systems under ...
A recently developed ab-initio method for the calculation of NMR chemical shifts and magnetic suscep...
In dieser Dissertation wird eine neue Methode zur Berechnung von NMR chemischen Verschiebungen und m...
We present a theory for the ab initio computation of NMR chemical shifts (sigma) in condensed matter...
A theory for the ab initio calculation of all-electron NMR chemical shifts in insulators using pseud...
We review the development of electronic structure methods for the calculation of nuclear magnetic re...
A DFT-based method is presented which allows the computation of all-electron NMR shifts of metallic ...
We extend the recently developed converse NMR approach [Thonhauser et al., J. Chem. Phys. 131, 10110...
We introduce a method for the all-electron calculation of the NMR chemical shifts and the EPR g tens...
The conceptual and numerical problems involved in the computation of reliable NMR chemical shifts fo...
We present a scheme for the calculation of magnetic response parameters in insulators using ultrasof...
We present a theoretical investigation of the hydrogen nuclear magnetic resonance (NMR) chemical shi...
We propose a new hybrid approach combining quantum chemistry and statistical mechanics of liquids fo...
We present an implementation of time-dependent density functional perturbation theory for spin fluct...
Computational methods are increasingly used to support interpreting, assigning and predicting the so...
A method for the ab initio prediction of the EPR g tensor for paramagnetic defects in systems under ...