University of Surrey

Test tubes in the lab Research in the ATI Dance Research

The Matter Compiler-towards atomically precise engineering and manufacture

Ly, DQ, Paramonov, L, Makatsoris, C, Ramsden, J, Wright, H, Holliman, N, Davidson, C, Heggie, M and Hagon, J (2011) The Matter Compiler-towards atomically precise engineering and manufacture Nanotechnology Perceptions, 7 (3). pp. 199-217.

Full text not available from this repository.

Abstract

The Matter Compiler is a novel framework for a computer toolset that allows the design of arbitrary molecular structures and their assembly by means of radical synthesis pathways that resemble "pick and place". Such synthesis pathways have been demonstrated experimentally in the literature in the recent past using scanning probe microscopes (SPM). The Matter Compiler framework entails first-principles modelling and novel control approaches that together assess the feasibility of userdefined molecular structures, screen alternative options for their assembly and finally suggest synthesis by means of physical equipment such as scanning probe microscopes. Nanoscale structure design is driven by first-principles calculations as well as by any relevant physical and chemical knowledge that can be accessed by the system from chemical databases. The first main consideration is therefore a suitable modelling methodology enabling the design and assessment of user-defined molecular structures. This entails the computer representation of such structures, methods to access and use available chemical and physical knowledge and, subsequently, an overall approach to plan the synthesis of such structures. Currently, it is assumed that assembly takes place on suitable substrates molecule-by-molecule and uses firstprinciples calculations to determine synthesis pathways (plans) on those substrates. The second main consideration is to use those synthesis plans to determine how synthesis will take place within a physical instrument. For scanning probes, for example, this translates to a collection of set points for the instrument controller to follow that collectively comprise the trajectory of the scanning probe for each step of the process. Image processing for monitoring progress, visualization and haptic interaction are also part of the Matter Compiler-they provide insight, feedback and determination of intervention strategies in case of errors. In this paper a description of the Matter Compiler methodology and framework architecture is presented. Some computational results are also presented. © 2011 Collegium Basilea.

Item Type: Article
Authors :
NameEmailORCID
Ly, DQUNSPECIFIEDUNSPECIFIED
Paramonov, LUNSPECIFIEDUNSPECIFIED
Makatsoris, CUNSPECIFIEDUNSPECIFIED
Ramsden, JUNSPECIFIEDUNSPECIFIED
Wright, HUNSPECIFIEDUNSPECIFIED
Holliman, NUNSPECIFIEDUNSPECIFIED
Davidson, CUNSPECIFIEDUNSPECIFIED
Heggie, Mm.heggie@surrey.ac.ukUNSPECIFIED
Hagon, JUNSPECIFIEDUNSPECIFIED
Date : November 2011
Depositing User : Symplectic Elements
Date Deposited : 17 May 2017 12:42
Last Modified : 17 May 2017 12:42
URI: http://epubs.surrey.ac.uk/id/eprint/836420

Actions (login required)

View Item View Item

Downloads

Downloads per month over past year


Information about this web site

© The University of Surrey, Guildford, Surrey, GU2 7XH, United Kingdom.
+44 (0)1483 300800