Christian R. Goldsmith, Ph.D.
Affiliations: | 1998-2004 | Chemistry | Stanford University, Palo Alto, CA |
2004-2007 | Chemistry | Massachusetts Institute of Technology, Cambridge, MA, United States | |
2007- | Chemistry and Biochemistry | Auburn University, Auburn, AL, United States |
Area:
synthetic inorganic and organic chemistryWebsite:
http://www.auburn.edu/academic/cosam/faculty/chemistry/goldsmith/research/Google:
"Christian Goldsmith"Mean distance: 8.36
Parents
Sign in to add mentorRichard Hadley Holm | research assistant | 1998 | Harvard College | |
T. Daniel P. Stack | grad student | 2004 | Stanford | |
(The use of small molecule mimics to provide insight into the reactive mechanism of lipoxygenases.) | ||||
Stephen James Lippard | post-doc | 2004-2007 | MIT |
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Publications
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Boothe R, Oppelt J, Franke A, et al. (2025) Nickel(II) complexes with covalently attached quinols rely on ligand-derived redox couples to catalyze superoxide dismutation. Dalton Transactions (Cambridge, England : 2003) |
Farnum BH, Goldsmith CR. (2024) Use of Intramolecular Quinol Redox Couples to Facilitate the Catalytic Transformation of O and O-Derived Species. Accounts of Chemical Research. 58: 101-112 |
Obisesan SV, Parvin M, Tao M, et al. (2024) Installing Quinol Proton/Electron Mediators onto Non-Heme Iron Complexes Enables Them to Electrocatalytically Reduce O to HO at High Rates and Low Overpotentials. Inorganic Chemistry |
Miliordos E, Moore JL, Obisesan SV, et al. (2024) Computational Analysis of the Superoxide Dismutase Mimicry Exhibited by a Zinc(II) Complex with a Redox-Active Organic Ligand. The Journal of Physical Chemistry. A. 128: 1491-1500 |
Karbalaei S, Franke A, Oppelt J, et al. (2023) A macrocyclic quinol-containing ligand enables high catalase activity even with a redox-inactive metal at the expense of the ability to mimic superoxide dismutase. Chemical Science. 14: 9910-9922 |
Obisesan SV, Rose C, Farnum BH, et al. (2022) Co(II) Complex with a Covalently Attached Pendent Quinol Selectively Reduces O to HO. Journal of the American Chemical Society |
Moore JL, Oppelt J, Senft L, et al. (2022) Diquinol Functionality Boosts the Superoxide Dismutase Mimicry of a Zn(II) Complex with a Redox-Active Ligand while Maintaining Catalyst Stability and Enhanced Activity in Phosphate Solution. Inorganic Chemistry |
Karbalaei S, Franke A, Jordan A, et al. (2022) A Highly Water- and Air-Stable Iron-Containing MRI Contrast Agent Sensor for H O. Chemistry (Weinheim An Der Bergstrasse, Germany). e202201179 |
Senft L, Moore JL, Franke A, et al. (2021) Quinol-containing ligands enable high superoxide dismutase activity by modulating coordination number, charge, oxidation states and stability of manganese complexes throughout redox cycling. Chemical Science. 12: 10483-10500 |
Karbalaei S, Knecht E, Franke A, et al. (2021) A Macrocyclic Ligand Framework That Improves Both the Stability and -Weighted MRI Response of Quinol-Containing HO Sensors. Inorganic Chemistry |