Encoding and transport of information in molecular and biomolecular systems

Author

Seminario, Jorge M. ; Yan, Liuming ; Ma, Yuefei

Author_Institution

Dept. of Chem. Eng., Texas A&M Univ., College Station, TX, USA

fYear

2005

fDate

11-15 July 2005

Firstpage

65

Abstract

Under the urgency to continue the exponential increase of computational power, which is seriously limited by physical laws, regardless of the materials used, that will not allows us any more to continue the so far successful scaling-down to reach higher performances by simultaneously allowing smaller and faster electronic devices, we have proposed possible scenarios that will solve the need to compromise, because heat dissipation, speed and size of integrated devices. These scenarios based on molecular electrostatic potentials and molecular vibrational modes can be combined to process and code information in nanosized circuits.

Keywords

biomolecular electronics; encoding; integrated circuits; nanotechnology; vibrational states; ab initio; biological systems; biomolecular systems; code information; computational power; density functional theory; digital signal processing; electronic devices; heat dissipation; integrated device; molecular electronics; molecular electrostatic potentials; molecular vibrational modes; nanosized circuits; nanotechnology; physical laws; scenarios; vibrational states; Biological system modeling; Chemical engineering; Circuits; Electrons; Electrostatics; Encoding; Nanobioscience; Nanotechnology; Signal to noise ratio; Temperature;

fLanguage

English

Publisher

ieee

Conference_Titel

Nanotechnology, 2005. 5th IEEE Conference on

Print_ISBN

0-7803-9199-3

Type

conf

DOI

10.1109/NANO.2005.1500693

Filename

1500693