Unraveling the mechanism of chemical reactions often requires a detailed understanding of the role of potential reaction intermediates. These intermediates can be quite difficult to characterize because they are often unstable, highly reactive and short-lived. Professor Goodman's research goals involve the experimental challenge of preparing such reactive intermediates and accurately describing their physical and chemical properties (structure, energetics and kinetics). Radicals, biradicals, carbenes, and ion radicals are all highly reactive species that have been postulated as reactive intermediates in organic reactions.
Stereochemistry, effects and kinetics are all diagnostic methods
commonly employed. In addition, several complimentary time-resolved
experimental techniques, pico- and nanosecond absorption spectroscopy
and pulsed time-resolved photoacoustic calorimetry are used.
Photoacoustic calorimetry is a new technique that effectively
listens to chemical 
reactions.
The experimental thermochemical and dynamic information can provide
valuable mechanistic insight into their intermediacy in chemical
reactions.One area of current interest is the chemistry of ion
radicals in solution. Ion radicals are now being recognized as
extremely important reactive intermediates in organic reactions.
However, little is known about their chemistry in solution. Photoinduced
electron transfer is a convenient, efficient method by which
to generate these species. Interestingly, their chemistry and
properties are often quite remarkable. They are often more reactive
and more selective than their neutral precursors. In addition,
the energetics of ion radical reactions is often quite different
than that of the neutral molecules. This relationship can be
exploited to synthesize interesting new novel compounds.
In recent years, we have investigated new strategies to increase the efficiencies of photoinduced electron transfer reactions by decreasing the rate of return electron transfer (RET), or increasing the rates of useful competing processes such as ion pair separation or follow-up ion radical reactions. A recent alternative approach we have explored is to have RET itself do useful work when it is coupled to a chemical reaction such as bond dissociation, Figure 1. This process, termed dissociative return electron transfer (DRET), is highly efficient in several systems we have studied.