Project Summary/Abstract Discovery of fundamentally new catalytic reactions, especially enantioselective ones, showing high turnover frequencies (i.e., substrate/ catalyst/unit time), that use readily available precursors, will have a significant impact on medicinal and process chemistry. Through an approach that relies heavily on mechanistic insights and attendant ligand designs, we aim to discover new enantioselective reactions of alkenes and alkynes. For example, use of low-valent chiral (L*)cobalt complexes has enabled heterodimerization between a broad range of 1,3-dienes, and, ethylene and alkyl acrylates, which are feedstock materials. The products of these reactions are synthetically valuable chiral 1,4-skipped dienes (produced in >90% yield and ee) which can be turned into pharmaceutically relevant classes of compounds. Examples cited include anti-microbial and anti- tumor and antifungal agents, GABA analogs, and metalloproteinase inhibitors. On-going mechanistic studies strongly suggest the intermediacy of a cationic [(P~P)Co(L)]+X– species in these exceptionally selective C-C bond-forming reactions that proceed under ambient conditions. Most remarkably, we recently (2020/2021) found that the chiral cationic Co(I) complexes with custom- designed ligands catalyze enantioselective [2+2]-additions of alkynes and vinyl-X derivatives, opening, arguably, the best route to enantiopure 3-substituted cyclobutenes, potential precursors of many other valuable compounds. In sharp contrast to 1,3-dienes, 1,3-enynes form, initially, vinylcyclobutenes and then, in a tandem fashion, highly functionalized cyclobutanes with an all- carbon quaternary centers. Such reactions are highly efficient and uncommon. Preliminary results also indicate that chiral cationic Co(I)-complexes catalyze at least 4 other types of enantioselective reactions (hydroboration, hydroacylation and hydrosilylation of prochiral 1,3-dienes, and, cyclizaion/hydrovinylation of 1,6-enynes). We plan to explore how some of the combinations of reactions can be run in tandem, in attempts to exploit the full potential of the new cobalt chemistry in organic syntheis. Historically some of the reactions we work on had been carried out using precious metals (Rh, Ir, Pd). We expect, when fully devloped, cobalt (which is up to 200 time cheaper than Rh for example), will be able to catalyze some of these basic reactions. Rapid assays of selectivity (-chemo-, regio- and enantioselectivities) are essential for the success of these projects and HPLC is one of the most critical instruments we use. Through this submission we request funds for replacement of an aging instrument (now more than 20 years old) that has been declared obsolete by the manufacturer, thus becoming increasingly difficult to service and maintain.