faculty

Assistant Professor of Chemistry
Ph.D., University of Texas, Austin

Electrochemistry, Semiconductor Photoelectrochemistry, Materials Chemistry, Surface Science, Corrosion, Heterogeneous Electrocatalysis

Phone: (734)   (July, 2008)   
E-mail: smald@umich.edu

Heterogeneous charge transfer is at the heart of microelectronics, many chemical sensing strategies, and energy conversion/storage technologies.   Understanding, designing, and developing more efficient electrode surfaces for systems based on interfacial charge transfer are my group's research interests.  Advancements in these fields requires further understanding of, and control over, the kinetics of charge transfer, stability of the interface, and material properties of the system components.

Our group is particularly interested in developing solar energy conversion and storage systems.   For any system to be capable of converting sunlight into chemical energy (i.e. chemical bonds), sunlight must be efficiently absorbed, photoexcited electrons and holes must be generated, and these charge carriers must be separately directed to reaction sites where they can drive redox reactions.   Inorganic semiconductors are naturally suited for all three of these required tasks.   In fact, a semiconductor electrode in contact with a liquid solution is arguably the simplest design for an artificial, solar-powered fuel generator.   Inorganic semiconductors strongly absorb photons with energies greater than the band gap, support energetically and spatially separated electrons and holes, and are natural platforms for heterogeneous electron transfer.   However, the difficulties associated with simultaneously maximizing the absorption of sunlight, optimizing the thermodynamics and kinetics for interfacial charge transfer, and preserving the longevity of the semiconductor/solution interface have stalled development of such photoelectrochemical systems.  Deliberate and systematic control over the electrical, physical, and electrochemical properties of the surfaces of inorganic semiconductors would greatly improve the viability of such photoelectrochemical systems. 

AWARDS

• Moore Foundation Postdoctoral Fellowship (Summer 2007 - Summer 2008)
• Ford Foundation Postdoctoral Fellowship (Summer 2006 - Summer 2007)
• National Science Foundation Graduate Student Fellowship (Fall 2001- Spring 2003)
• Beckman Scholar Fellowship (Summer 2000 - Summer 2001)

REPRESENTATIVE PUBLICATIONS

1. Maldonado, S., Knapp, D., Lewis, N. S. "Near-Ideal Photodiodes from Sintered Gold Nanoparticle Films and Chemically Modified Silicon" J. Am. Chem. Soc., 2008, 130, 3300-3301


2. Maldonado, S., Plass, K. E., Knapp, D., Lewis, N. S.; "Electrical Properties of Junctions Between Hg and Si(111) Surfaces Functionalized with Short Chain Alkyls" J. Phys. Chem. C , 200, 48, 17690-17699


3. Maldonado, S., Smith, T., Williams, R., Morin, S., Barton, E., Stevenson, K. J., "Surface Modification of Indium Tin Oxide via Electrochemical Reduction of Aryldiazonium Cations" Langmuir, 2006, 22, 2884-2891


4. Maldonado, S., Stevenson, K. J., "Influence of Nitrogen Doping on Oxygen Electrocatalysis at Carbon Nanofiber Electrodes" J. Phys. Chem. B, 2005, 109, 4707-4716