Applied Physics Seminar Series
Abstract:
For too long the functionality of optical devices and systems has been severely restricted by the very limited range of refractive indices at the disposal of designers. These limitations become especially constricting in the currently most active areas of optics – integrated photonics, photonic crystals, metamaterials and metasurfaces. A simple increase of the value of refractive index by 50% can result in disproportionally large improvement in performance (i.e. smaller size, less cross-talk, higher resolution, and so on, depending on application) With that in mind, I explore what are the fundamental limits that limit the scope of refractive indices as a function of wavelength, explain why higher index materials have not yet materialized and point out a few tentative directions for the search of these elusive materials, be they natural or artificial.
In the second part of the talk, I investigate a closely related issue: changing refractive index to achieve effective modulation. There exist many methods of index modulation, starting with Pockels and Kerr electro-optic effects, acousto-optic and opto-mechanical effect, optical nonlinearities, thermal, carrier injection/depletion, etc. In my talk I will try to provide a comprehensive analysis that will show that independent of the modulation technique, one must supply and maintain (but not necessarily dissipate) anywhere between few times 103 and 105 J/cm3 of energy in order to achieve relative index change on the order of 50-100% (with energy requirements increasing in sync with the decrease of operating wavelength). While the energy requirements are fixed, the required switching power can be decreased by increasing photon matter interaction time as well as miniaturizing the devcies. The general conclusion is that unless radically new material systems are developed, the improvement of the performance of existing modulation techniques will have evolutionary rather than revolutionary character with no order of magnitude improvement in sight. I will try to argue for using collective effects and fast phase transitions to achieve future breakthroughs.
More about the Speaker:
Jacob Khurgin, a professor of electrical and computer engineering, is known for his diverse and eclectic research in the areas of optics, electronics, condensed matter physics, and telecommunications.
Much of Khurgin's work lies at the intersection of optics and solid-state electronics. He has focused on an array of topics during his career, including the optics of semiconductor nanostructures, nonlinear optical devices, lasers, optical communications, microwave photonics, and condensed matter physics. His most recent work involves mid-infrared optical frequency combs, metamaterials, optical refrigeration of solids, and phonon engineering for high-frequency transistors, to name a few.