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Ultra-Small, All-Optical Plasmonic Switches Based on Light-Driven Molecular Shuttles

$270,000FY2008ENGNSF

Pennsylvania State Univ University Park, University Park PA

Investigators

Abstract

Abstract ECCS-0801922 T. Huang, PA ST U University Park Objective: The proposal focuses on developing a new class of ultra-small, all-optical plasmonic switches using photoactive rotaxanes as active components. The proposed photoactive rotaxane-based all-optical plasmonic switches could achieve unprecedented performance (size: molecular level; energy consumption: 1-2 eV; excellent reversibility and flexibility) and be integral components for the future ultra-small, ultra-fast plasmonic circuits and very large scale electronics and photonics integration (VLSEPI). Intellectual merits: This project introduces light-driven molecular machines into optical device settings. Molecular machines driven by light have several advantages: they can be switched much faster; they do not produce any waste; light can be used for dual purposes¡Vinducing (writing) as well as detecting (reading) molecular motions. Experimental and numerical investigations will shed some light on the fundamental understanding of controlling plasmonics at molecular level. More importantly, with molecular machines¡¦ advantages in their size, energy consumption, speed, and controllability at molecular level, we expect that once established, the proposed rotaxane-based plasmonic switches will be welcomed in many applications such as optical communication. Broader Impact: The PI will partner with the Penn State Center for Nanoscale Science and develop outreach activities around the theme of ¡¥from molecular shuttles to nanomechanics, nanoelectronics, and nanophotonics¡¦. A suite of demonstrations will imitate molecular machines¡¦ mechanical motions, broadly constructed and idealized in their operation by macroscopic models. The results developed in the past as well as from this proposal will be used to illustrate what molecular machines can achieve, and they will be delivered to museums, high-schools, and summer programs.

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