David R. Smith

James B. Duke Professor

Faculty Network Member of Energy Initiative and Director of the Center for Metamaterials and Integrated Plasmonics and Chair of the Department of Electrical and Computer Engineering

2527 Ciemas Building, Durham, NC 27708
(919) 660-5376


Numerical tool to take nonlocal effects into account in metallo-dielectric multilayers.
Journal of the Optical Society of America. A, Optics, image science, and vision (2015)

Leveraging Nanocavity Harmonics for Control of Optical Processes in 2D Semiconductors.
Nano letters (2015)

Third-harmonic generation in the presence of classical nonlocal effects in gap-plasmon nanostructures
Physical Review B (2015)

Computational imaging using a mode-mixing cavity at microwave frequencies
Applied Physics Letters (2015)

Ultrafast self-action of surface-plasmon polaritons at an air/metal interface
Physical Review B (2015)

Analytic modeling of metmaterial absorbers
CLEO: QELS - Fundamental Science, CLEO_QELS 2015 (2015)

Scaling of the nonlinear response of the surface plasmon polariton at a metal/dielectric interface
Journal of the Optical Society of America B (2015)

Plasmonic nanopatch antennas for large purcell enhancement
CLEO: QELS - Fundamental Science, CLEO_QELS 2015 (2015)

A constitutive description of nonlinear metamaterials through electric, magnetic, and magnetoelectric nonlinearities
Springer Series in Materials Science (2015)

Scaling of the nonlinear response of metal/dielectric plasmonic waveguides
CLEO: QELS - Fundamental Science, CLEO_QELS 2015 (2015)

Dr. David R. Smith is currently the James B. Duke Professor of Electrical and Computer Engineering Department at Duke University, where he also serves as Department Chair. He is also Director of the Center for Metamaterial and Integrated Plasmonics at Duke and holds the positions of Adjunct Associate Professor in the Physics Department at the University of California, San Diego, and Visiting Professor of Physics at Imperial College, London. Dr. Smith received his Ph.D. in 1994 in Physics from the University of California, San Diego (UCSD). Dr. Smith's research interests include the theory, simulation and characterization of unique electromagnetic structures, including photonic crystals and metamaterials.  

Smith is best known for his theoretical and experimental work on electromagnetic metamaterials. Metamaterials are artificially structured materials, whose electromagnetic properties can be tailored and tuned in ways not easily accomplished with conventional materials. Smith has been at the forefront in the development of numerical methods to design and characterize metamaterials, and has also provided many of the key experiments that have helped to illustrate the potential that metamaterials offer. Smith and his colleagues at UCSD demonstrated the first left-handed (or negative index) metamaterial at microwave frequencies in 2000--a material that had been predicted theoretically more than thirty years prior by Russian physicist Victor Veselago. No naturally occurring material or compound with a negative index-of-refraction had ever been reported until this experiment. In 2001, Smith and colleagues followed up with a second experiment confirming one of Veselago's key conjectures: the 'reversal' of Snell's law. These two papers--the first published in Physical Review Letters and the second in Science--generated enormous interest throughout the community in the possibility of metamaterials to extend and augment the properties of conventional materials. Both papers have now been cited more than 3,000 times each.

Since those first metamaterial experiments, Smith has continued to study the fundamentals and potential applications of negative index media and metamaterials. In 2004, Smith began studying the potential of metamaterials as a means to produce novel gradient index media. By varying the index-of-refraction throughout a material, an entire class of optical elements (such as lenses) can be formed. Smith showed that metamaterials could access a much larger range of design space, since both the magnetic and the electric properties could be graded independently. Smith and colleagues demonstrated several versions of gradient index optics, an activity that continues in his lab today. The introduction of controlled spatial gradients in the electromagnetic properties of a metamaterial flows naturally into the broad concept of transformation optics - a new electromagnetic design approach proposed by Sir John Pendry in 2006. To illustrate of the novelty of this design approach, Pendry, Schurig and Smith suggested in 2006 that an 'invisibility cloak' could be realized by a metamaterial implementation of a transformation optical design. Later that same year, Smith's group at Duke University reported the demonstration of a transformation optical designed 'invisibility cloak' at microwave frequencies. The concept of transformation optics has since attracted the attention of the scientific community, and is now a rapidly emerging sub-discipline in the field.

Smith's work on transformation optics has been featured in nearly every major newspaper, including a cover story in USA Today, The New York Times, The Chicago Tribune, The Wall Street Journal, The Washington Post and many more. Smith and his work on cloaking have also been featured on television news programs inlcuding The Today Show, Countdown with Keith Olbermann, Fox News, CNN and MSNBC. Smith's work has also been highlighted in documentary programs on The History Channel, The Discovery Channel, The Science Channel, the BBC and others.

Please also see Prof. Smith's personal website at http://people.ee.duke.edu/~drsmith for the most frequent updates.

Ph.D. - University of California at San Diego
B.S. - University of California at San Diego
2008 Descartes Prize for Research, European Union
2008 Top 100 Science Accomplishments for 2006, Discover Magazine (Cloaking)
2008 Top 50 Researchers, Scientific American
2008 Top Ten Breakthroughs for 2003, Science Magazine (Negative Index Materials)
2008 Top Ten Breakthroughs for 2006, Science Magazine (Cloaking)
1986 Fellows, Institute for Electrical and Electronics Engineers