Reduced and excited states of the intermediates (a-diimine)(C5R5)Rh in hydride transfer catalysis schemes: EPR and resonance Raman spectroscopy, and comparative DFT calculations of Co, Rh and Ir analogues. Dalton Transactions, 22:3815--3821, 2004. [PUMA: DFT Raman catalysis cobalt complex;EPR cyclopentadienyl diimine excited hydride intermediate iridium;reduced resonance rhodium spectra state transfer]
Mixed-valence intermediates as ideal targets for spectroelectrochemistry (SEC): Spectroelectrochem. In Wolfgang Kaim, Biprajit Sarkar, und Goutam Kumar. Lahiri (Hrsg.), Royal Society of Chemistry, 2008. [PUMA: ESR IR catalysis electrocatalysis intermediate mixed optical redox review;review spectroelectrochem valence vibrational]
Electron-transfer-catalyzed carbonyl substitution. III. Synthesis and spectroscopy of mono- and binuclear cis-phosphinetetracarbonyltungsten(0) complexes of electron-poor pyridines. Journal of Organometallic Chemistry, (361)3:335--351, 1989. [PUMA: acylpyridine carbonyl catalysis complex deriv phosphine;cyanopyridine phosphine;electron phosphine;redn potential pyridine pyridine;tungsten substitution;isonicotinate transfer tungsten]
Electron transfer catalyzed carbonyl substitution. I. Synthesis and spectroscopy of phosphine tricarbonyl metal complexes of bidiazine. Journal of Organometallic Chemistry, (340)1:71--91, 1988. [PUMA: bidiazine carbonyl catalysis molybdenum phosphine;bipyrazine phosphine;bipyridazine phosphine;bipyrimidine phosphine;electron substitution;spectra transfer tungsten]
NFDI4Cat: Local and overarching data infrastructures. In Vincent Heuveline, und Nina Bisheh (Hrsg.), E-Science-Tage 2021: Share Your Research Data, heiBOOKS, 2022. [PUMA: catalysis cmcs data hlrs hpc metadata myown nfdi nfdi4cat rdm] URL
Hierarchical Silica Inverse Opals as a Catalyst Support for Asymmetric Molecular Heterogeneous Catalysis with Chiral Rh-diene Complexes. ChemCatChem, (13):1-12, Wiley, März 2021. [PUMA: CLSM catalysis inverse opals silica] URL
Electron transfer catalyzed carbonyl substitution. I. Synthesis and spectroscopy of phosphine tricarbonyl metal complexes of bidiazine. Journal of Organometallic Chemistry, (340)1:71--91, 1988. [PUMA: bidiazine carbonyl catalysis molybdenum phosphine;bipyrazine phosphine;bipyridazine phosphine;bipyrimidine phosphine;electron substitution;spectra transfer tungsten]
Electron-transfer-catalyzed carbonyl substitution. III. Synthesis and spectroscopy of mono- and binuclear cis-phosphinetetracarbonyltungsten(0) complexes of electron-poor pyridines. Journal of Organometallic Chemistry, (361)3:335--351, 1989. [PUMA: acylpyridine carbonyl catalysis complex deriv phosphine;cyanopyridine phosphine;electron phosphine;redn potential pyridine pyridine;tungsten substitution;isonicotinate transfer tungsten]
Mixed-valence intermediates as ideal targets for spectroelectrochemistry (SEC): Spectroelectrochem. In Wolfgang Kaim, Biprajit Sarkar, und Goutam Kumar. Lahiri (Hrsg.), Royal Society of Chemistry, 2008. [PUMA: ESR IR catalysis electrocatalysis intermediate mixed optical redox review;review spectroelectrochem valence vibrational]
Reduced and excited states of the intermediates (a-diimine)(C5R5)Rh in hydride transfer catalysis schemes: EPR and resonance Raman spectroscopy, and comparative DFT calculations of Co, Rh and Ir analogues. Dalton Transactions, 22:3815--3821, 2004. [PUMA: DFT Raman catalysis cobalt complex;EPR cyclopentadienyl diimine excited hydride intermediate iridium;reduced resonance rhodium spectra state transfer]