Quantum Effects in Electronic Nanodevices (QuEEN)

Completed

Energy Efficiency(Residential and commercial)
Not Energy Related
Other Power and Storage Technologies(Electric power conversion)
Other Cross-Cutting Technologies or Research(Environmental, social and economic impacts)

Basic and strategic applied research

PHYSICAL SCIENCES AND MATHEMATICS (Chemistry)
PHYSICAL SCIENCES AND MATHEMATICS (Physics)
ENGINEERING AND TECHNOLOGY (Electrical and Electronic Engineering)

Not Cross-cutting

Professor GAD Briggs
Materials
University of Oxford

Professor HL Anderson
Oxford Chemistry
University of Oxford

Standard

EPSRC

01 January 2016

31 December 2022

84 months

£5,296,044

magn. &quant.fluids; Supercond

South East; South East

NC : Physical Sciences

Professor GAD Briggs, Materials, University of Oxford
Professor HL Anderson, Oxford Chemistry, University of Oxford

Dr L Bogani, Materials, University of Oxford
Professor C Lambert, Physics, Lancaster University

Project Contact, Amadeus Capital Partners Limited
Project Contact, IBM T.J. Watson Research Centre, USA
Project Contact, Oxford Nanopore Technologies
Project Contact, Oxford Instruments plc
Project Contact, Autonomous University of Madrid, Spain
Project Contact, Private Address
Project Contact, Cambridge Display Technology Ltd
Project Contact, Hitachi Cambridge Laboratory
Project Contact, University of Waterloo (Canada)
Project Contact, University of Queensland
Project Contact, MV Portfolios Inc, USA
Project Contact, Argyll College
Project Contact, University of Cambridge

Put your hand under a working laptop computer and you'll find that it's warm, due to the heat produced by the transistors in it. This isn't just a problem for your own computer: nearly 5% of the world's electricity is used by computers and the internet, a figure expected to double over the next decade. Much of this is wasted in generating heat that, according to thermodynamic theory, is not needed for information processing; and over half is for cooling systems to remove the unwanted heat. The resulting carbon emissions are comparable to the total global aviation industry.If we can reduce the energy consumption of logic operations in information technologies, or scavenge just a fraction of the waste heat, the effect on energy use and carbon emissions could be vast. Recent research breakthroughs have opened up new possibilities for making tiny electronic components and circuits, based on individual molecules, which have the potential to do just that (since their behaviour is not constrained by the laws of classical physics). To make this a reality, we must first learn to understand and control quantum effects in electronic nanodevices.We can use a new material, graphene, to make mechanically and chemically stable electrodes and connect them to electrically-active molecules. New methods allow us to make a very small gap in graphene which is just the right size for a molecule or a single strand of DNA (for fast and cheap DNA sequencing). Chemical units have been developed that attach to molecules and adhere like sticky notes to the graphene contacts on each side of the gap.. With graphene electrodes we can also make magnetic connections to single molecules to create molecular memory devices. A phenomenon called quantum interference can dramatically affect the flow of electric current in molecules. Harnessing these quantum effects will enable us to make tiny switches that would consume very little energy, and to generate electricity from small differences in temperature. The time is ripe for a focused research effort, drawing together these advances to transform our understanding and to pave the way for practical applications.Our programme is one of discovery science with a view to practical benefit. QuEEN will first establish the basic platform technology for experiments on single-molecule devices, including selection of the best molecules and control of their quantum interference by a local electric field. It will conclude by seeking to transfer results from rather ideal (cryogenic) laboratory conditions to a real-world environment, at room temperature. In between those two challenges, we shall explore three particularly promising areas for scientific discovery and application: controlling the magnetic property of an electron, known as spin, for quantum interference for potential use in universal computer memories; seeing how much electricity a molecule can generate if its ends are held at different temperatures, offering the potential for energyharvesting; and finding the performance limits of a single-molecule transistor, for potential uses in low-power computing and timer-controllers for the Internet of Things. The research requires four core skill sets, which form a virtuous circle: chemistry, to design and synthesise the molecules at the heart of our devices and stick them reliably to electrodes; nanofabrication, to make molecule-sized gaps in graphene ribbons; measurement techniques and advanced instrumentation to control the environment and characterise the quantum effects; and theory, to predict the effects, screen potential molecules, and interpret the results. QuEEN brings together a research team with exactly the right mix of expertise; an Advisory Board with wide experience of successful technological entrepreneurship; and a group of industrial partners who will not only shape and assist with the research but also provide a pathway to technological innovation and real-world applications

05/01/16