GGrantIndex
← Search

NIRT- Molecular Assembly for Hybrid Electronics

$1,012,350FY2003CSENSF

Suny At Stony Brook, Stony Brook NY

Investigators

Abstract

NIRT: Molecular Assembly for Hybrid Electronics Abstract This proposal was received in response to Nanoscale Science and Engineering initiative, NSF 02-148, category NIRT. The extension of integrated circuits into sub-10-nm range promises enormous benefits for computing, networking, and signal processing. However, fabrication of such devices using current paradigms based on CMOS and current VLSI technology are not possible. We believe that this crisis may only be resolved by a radical paradigm shift, which would simultaneously change the approach to fabrication of electron devices and to VLSI circuit architecture. Our approach is to use a biologically inspired approach called "Self-Evolving Neuromorphic Networks". This approach is based on artificial models of the neocortex and is structured to have a high degree of parallelism and intrinsic redundancy. In this approach molecular circuit elements, "self-assembled" by molecular chemistry, can be allowed to grow randomly, forming circuit elements (molecular transistors), which connect lithographically patterned metal grids. However, the random aspect of molecular self-assembly has to be carefully understood and controlled. At present, there is no detailed understanding of this process. It is this crucial gap that we address in this proposal. The devices that we are proposing need molecular wires that can switch into and out of a conductive state. The molecules bridge the metal wires with inherent randomness. Our aims are to predict and control the bridging and switching, through deterministic chemistry of the molecule-metal interaction, as well as through a statistical analysis of the assembly process. To accomplish these aims, we have a diverse team, which will interact strongly across the engineering/chemistry/physics boundaries. As part of the outreach of this project we plan to use the NIRT as a forum in which we will provide new types of educational settings for students (undergraduate and graduate) and high school teachers, and adopt a flexible program of research guided by feedback between theory and experiment, chemistry and physics and engineering. Tremendous technological advances in miniaturization have enabled more and more transistors to be packed onto a silicon chip. However, the reduction of feature size on chips is limited not just by the resolution of the fabrication process, but also by the problem of quantum and classical fluctuations. Consequently, below a limiting dimension that we have nearly reached, a new paradigm that goes beyond conventional solid state electronics has to be developed for the next generation of electronics devices. In this project, we propose a new paradigm that is based on an artificial model of the neocortex: In which molecular circuits are assembled in a manner similar to the synaptic connections present in the brain. Our paradigm if realized offers the possibility of the design of the next generation of computational devices, with speeds that, in theory, could be 10 orders of magnitude faster than the fastest existing parallel supercomputer.

View original record on NSF Award Search →