17 April 2000 Chiropticenes: molecular chiroptical dipole switches for optical data storage
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Proceedings Volume 3937, Micro- and Nano-photonic Materials and Devices; (2000) https://doi.org/10.1117/12.382795
Event: Symposium on Integrated Optoelectronics, 2000, San Jose, CA, United States
Abstract
Chiropticenes are a novel class of single-molecule chiroptical dipole switches. The fundamental mechanism of the Chiropticene switch is that the combination of light and electric field cause both the chirality and the dipole direction to be simultaneously reversed. The information stored in the Chiropticenes can be read nondestructively with circularly polarized light, which ensures erase-read- write capability. These molecular switches are exceptional in that they have the potential to be exploited on both the molecular and macroscopic scale. The Chiropticene switch has been designed for incorporation into an optical data storage device that will be faster and have a higher capacity than the currently available technology. The organic Chiropticene is molecularly engineered to fulfill all the requirements of a switching device in electronic applications. Its modular structure is able to provide an extraordinary capacity to chemically tune the properties of the switch molecule. The synthesis of the Chiropticenes and characterization of their optical properties will be presented. The design of nanodevice architectures based on Langmuir-Blodgett films and/or self-assembled monolayer swill also be presented.
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Katherine A. Hutchison, Katherine A. Hutchison, James P. Parakka, James P. Parakka, Brenda S. Kesler, Brenda S. Kesler, Robert R. Schumaker, Robert R. Schumaker, } "Chiropticenes: molecular chiroptical dipole switches for optical data storage", Proc. SPIE 3937, Micro- and Nano-photonic Materials and Devices, (17 April 2000); doi: 10.1117/12.382795; https://doi.org/10.1117/12.382795
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