Marcellus L. Wiedenbeck Collegiate Professor and University Diversity and Social Transformation Professor
4251 Homer A. Neal Lab
Labs: 1208, 1212, SB173 Homer A. Neal Lab
Research in the Clarke group is focused on the role of interfaces in thin films and quantum nanostructures. Several projects are currently underway, investigating the unusual structure and dynamics of condensed matter systems where the boundaries between dissimilar materials determine the physical properties. Examples include multilayer heterostructures of magnetic and semiconducting materials, quantum dots and nanowires, and atomic-layer superlattices. Complex oxide heterostructures are of particular interest because of the unusually broad range of correlated electron behavior they exhibit, including superconductivity, coupled dielectric and magnetic ordering (multiferroicity), metal-insulator transitions and spintronic transport.
Experiments at the ultrafast/ultrasmall temporal/spatial scales require specialized instrumentation to probe nanoscale properties: x-ray synchrotron radiation from accelerator-based sources (e.g., the Advanced Photon Source at Argonne National Laboratory); ultrafast optical pump-probe spectroscopy using dual mode-locked fiber lasers in asynchronous sampling mode; femtosecond time-resolved photoluminescence spectroscopy (Center for Nanoscale Materials, Argonne National Lab); and nanoscale materials modification and deposition using femtosecond laser pulses (Center for Ultrafast Optics).
Specific projects currently include:
- ferroelectric heterostructures containing ultrathin layers of BaTiO3
- the conducting interface between LaAlO3 and SrTiO3
- effects of lattice mismatch strain on ultrathin BiFeO3 and BiCrO3 films
- dynamics of spin waves in LaSrMnO3 heterostructures
- nanostructured Bi2Te3 and Sb2Te3 films
- core-shell structures in III-V quantum dots made by droplet epitaxy
- carbon nanostructures produced by ultrafast laser-matter interactions
Some of these projects have direct practical applications, including energy storage and conversion. These aspects of the research are pursued in the Center for Solar and Thermal Energy Conversion, an Energy Frontiers Research Center (EFRC) funded by the Department of Energy. The Clarke group is also actively involved in entrepreneurship resulting in several recent inventions and tech transfers, including the development of real-time, in-situ thin-film metrology approaches for the semiconductor industry.
The group’s work is currently funded by the National Science Foundation, the Department of Energy, the Air Force Office of Scientific Research, and the Michigan Economic Development Corporation.
Professor Clarke is a Fellow of the American Physical Society and received the Presidential Award for Excellence in Science, Mathematics, and Engineering Mentoring in 2011. He is also a Fellow of the National Center for Institutional Diversity.
Coherent Control of GHz Resonant Modes by an Integrated Acoustic Etalon, (H. Sun, V. Stoica, M. Shtein, R. Clarke, and K. Pipe), Physical Review Letters 110, 086109 (2013).
Structural Investigation of ZnO O-Polar Surfaces and Schottky Interfaces, (Y. Yang, C.M. Schlepütz, F. Bellucci, M.W. Allen, S.M Durbin, R. Clarke), Surface Science 610, 22 (2013).
The Presence of a (1x1) Oxygen Overlayer on ZnO(0001) Surfaces and at Schottky Interfaces, (Christian M. Schlepütz, Yongsoo Yang, Naji S. Husseini, Robert Heinhold, Hyung-Suk Kim, Martin W. Allen, Steven M. Durbin, and Roy Clarke), J. Phys.: Condensed Matter 24, 095007 (2012).
Femtosecond Laser-induced Nanostructure Formation in Sb2Te3, (Yuwei Li, Vladimir A. Stoica, Lynn Endicott, Guoyu Wang, Huarui Sun, Kevin P. Pipe, Ctirad Uher, and Roy Clarke), Applied Physics Letters 99, 121903 (2011).
Surface X-ray Diffraction Results on the III-V Droplet Heteroepitaxy Growth Process for Quantum Dots: Recent Understanding and Open Questions, (Eyal Cohen, Naomi Elfassy, Guy Koplovitz, Shira Yochelis, Sergey Shusterman, Divine P. Kumah, Yizhak Yacoby, Roy Clarke and Yossi Paltiel), Sensors 11, 10624 (2011).
Correlating Structure, Strain and Morphology of Self-assembled InAs Quantum Dots on GaAs, (D.P. Kumah, J.H. Wu, N.S. Husseini, V.D. Dasika, R.S. Goldman, Y. Yacoby, and R. Clarke), Applied Physics Letters 98, 021903 (2011).
Magnetic Confinement of Brownian Rotation to a Single Axis and Application to Janus and Cluster Microparticles, (B. H. McNaughton, M. Shlomi, P. Kinnunen, C. Cionca, S. N. Pei, R. Clarke, P. Argyrakis, and R. Kopelman), Applied Physics Letters 97, 144103 (2010).
Atomic-scale Mapping of Quantum Dots formed by Droplet Epitaxy, (D. P. Kumah, S. Shusterman, Y. Paltiel, Y. Yacoby, R. Clarke), Nature Nanotechnology 4 835-838 (2009).
Wideband Detection of Transient Solid-state Dynamics using Ultrafast Fiber Lasers and Asynchronous Optical Sampling, (Vladimir A. Stoica, Yu-Miin Sheu, David A. Reis, and Roy Clarke), Optics Express 16, 2322 (2008).
Structural Basis for the Conducting Interface Between LaAlO3 and SrTiO3, (P.R. Willmott, S.A. Pauli, R. Herger, C.M. Schlepütz, D. Martoccia, B.D. Patterson, B. Delley, R. Clarke, D. Kumah, C. Cionca, Y. Yacoby), Physical Review Letters 99, 155502 (2007).
Field(s) of Study
- Condensed Matter Experiment
- Materials Physics
- Applied Physics