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Education
Marcetta Darensbourg was born in Kentucky, USA. She received her bachelor’s degree in Chemistry from Union College, in 1963. Heading to the University of Illinois, Darensbourg completed her Ph.D. degree under the supervision of Professor Thomas Brown in 1967. Her work focused on the kinetic studies of organolithium reactions.

Career
Darensbourg began her independent career as an assistant professor at Vassar College in the years 1967 She then worked as a visiting assistant professor at State University of New York, in Buffalo. She moved to Tulane University, where she was a faculty from 1971 until 1982. In 1982, she moved to Texas A&M University. During Spring of 1999, she was a visiting professor at Harvard University. Since 2010, she became a Distinguished Chemistry Professor at TAMU.

Awards and Honors: (Last Decade)
●American Chemical Society Award in Organometallic Chemistry (2017)

●Texas A&M University College of Science Undergraduate Research Mentoring Award (2016)

●University of California, Los Angeles M. Frederick Hawthorne Endowed Lecturer (2016)

●Royal Society of Chemistry Fellows (2014)

●Riley Schaeffer Endowed Lecturer (2014)

●Gagliardi Distinguished Lecturer (2014)

●Fred Basolo Medal (2013)

●John C. Bailar, Jr. Medalist (2013)

●Texas A&M Association of Former Students Faculty Distinguished Achievement Award in Graduate Mentoring (University-Level, 2012)

●Texas A&M Chapter of Sigma Xi – Distinguished Scientist Award (2011)

●American Academy of Arts & Sciences Fellows (2011)

●American Chemical Society Fellows (2009)

●The Robert A. Welch Lectureship Program (2007-2008)

Research Projects
Organolithium Compounds Investigation During her PhD Darensbourg investigated certain kinetic aspects of organolithium compounds. During the course of these studes, the kinetics of the rate-determining step of tert-butyllithium dissociation from tetramer to a dimer were analyzed. With mass spectroscopy evidence, the existence of cross-association with other organolithium species in the vapor phase could also be viewed.

Nucleophilic Attacks on Metal Carbonyls
Her interest in charge distribution molecules that could be probed with reactivity led to her work on mapping nucleophilic attack on metal carbonyls. Using infrared spectroscopy, nuclear magnetic resonance and electronic spectroscopy of some carbene pentacarbonyl complexes of chromium (0) and tungsten (0) indicated that carbene ligands are better sigma donors than a carbonyl ligand, while simultaneously behaving as strong pi acceptors. Substitutions of iron and cobalt sites were made to see how the CO strength force constants affected the nucleophilic attacks. The substitutions illustrated that the nucleophilic attacks always occurred at the CO group with the greater force constant when there is a choice of carbonyl groups present in a molecule. Her research on organolithium compounds and mapping of nucleophilic attacks on carbonyls had a continuous theme of site specific ion pairing.

Hydrogenase mimics
Darensbourg has pioneered the development of synthetic mimics of Hydrogenase enzymes. These include synthetic complexes featuring Fe-based organometallics species, which serve as precursor for producing iron only Hydrogenase enzyme active site. These enzymes are capable of carry out reaction even in the absence of the protein-based active site organization or carry out the proton production with high efficiencies. However, these Hydrogenase enzymes were found to be highly sensitive with di-oxygen, which can over oxidize and inactivate them. Even after the oxygen was removed, they don’t regain catalytic activity immediately but through multiple processes.

Metallodithiolates Ligands
In the beginning of 2017,Recently, Darensbourg shifted her focus to studying the metallodithiolates ligands, which act as building blocks for the synthesis of various bimetallic enzyme active sites. According to Darensbourg, Tthe ligands can act as a catalyst to carry out different reactions, depending on which transition metal being at the center.

From one of her newest publications, metallodithiolates ligands with nNickel centers can increase the electron density of reductive bond such as Fe – S, which allow them to be cleaved easily. In another recent paper, Darensbourg elucidated that this nNickel center complex associated with a lead atom also plays an important role in the addition of CO and ethylene in the Suzuki-Miyaura reaction, which couples the organic compounds of boron and the halides, along alkyl halides and alkylboranes. Furthermore, with the cCobalt center, the metallodithiolates ligands can catalyze the transfer of NO and nitrosylate moieties, which allows the glycosidase conjugation of DNICs (Dinitrosyl Iron Complex). With this conjugation, other carbohydrates can achieve higher potential in attaching for drug delivery.