Hydrogen Radical Chemistry at High-Symmetry {2Fe2S} Centers Probed Using a Muonium Surrogate.

Redox-active metal hydrides are of central importance in the development of novel hydrogen generation catalysts. Direct insight into open-shell hydrides is, however, difficult to obtain. One approach to gain this information is to use muonium (Mu = μ e) as a surrogate for the hydrogen radical. The chemistry of Mu is analogous to H; however, the species provides a highly sensitive probe through detection of the positrons arising from the muon decay (with a lifetime of ∼2.2 μs) and can therefore provide unique information about hyperfine couplings and thus molecular structure. Using this approach, we demonstrate here that the high-symmetry {2Fe2S} systems Fe(edt)(CO)L (edt = ethane-1,2-dithiolato; L = CO, PMe, CN) form bridging radicals directly on the time scale of the muon experiment. We also extend our computational approach to detail all of the possible addition sites in solid state samples.