Synthesis, Structure and Reactivity of Heterobimetallic Complexes for Small Molecule Activation and Catalysis
Society remains tied to fossil fuels while increasing pressure on the climate suggests a transition to renewable energy resources. However, the efficiency of processes enabling such a transition has considerable room for improvement. Relevantly, natural systems have evolved enzymes that enable a very efficient conversion of small molecules such as H2, CO and CO2,1 and perform these conversions more selectively and under milder conditions than current industrial processes. Many of these enzymes rely on multimetallic, and often heterometallic, active sites of abundant transition metals, for example in [NiFe] or [CuMo] carbon monoxide dehydrogenases.2 In addition, close proximity between metal centers in multimetallic compounds is considered favorable to the occurrence of enhanced catalytic properties for a variety of reactions.3 Thus, I studied the synthesis and properties of homogeneous bimetallic complexes of abundant, primarily first‐row transition metals during my Link Foundation Energy Fellowship.
Nicolay, Amelie, "Synthesis, Structure and Reactivity of Heterobimetallic Complexes for Small Molecule Activation and Catalysis" (2018). Link Foundation Energy Fellowship Reports. 21.
Link Foundation Fellowship for the years 2016-2018