Deterministic nanoscale transfer printing of compound semiconductor nanowires for large scale device integration.

Compound semiconductor nanowire based devices have significant potential in optoelectronics allowing for miniaturization of optical sources and detectors and functionalization of exposed surfaces. Applications range from photonic integrated circuits as lasers and photodetectors embedded into waveguides on chip to gas and biological sensors. Such devices face significant challenges in terms of fabrication with the positioning of nanowires either requiring slow serial processing of individual nanowires or significant growth challenges in selective area growth. This project seeks to address these difficulties and enable large scale parallel integration of nanowires at large and commercially viable scales. Deterministic transfer printing techniques will be developed to allow the precise positioning and orientation of compound semiconductor nanowires onto foreign substrates in an individual to wafer scale parallel process. These transfer printing techniques will allow the use of low cost, high-density self-assembled nanowire wafers as donor substrates and control of positioning of nanowires in any reconfigurable configuration. Key to achieving transfer printing of nanowire ordering and precision positioning is the development of nanostructured transfer printing stamps and agitation techniques during the transfer printing process. A wide range of processing techniques will be employed including direct write laser lithography to pattern transfer printing stamp moulds. The techniques developed will be used to print GaN and other material nanowires and nanorods by both top down fabrication and MBE growth.

Through our students, following consideration of the consequences of their research and appropriate action informed by their Responsible Innovation training, impact will fall into one of 3 strands:

SOCIETAL:

As a Key Enabling Technology, Compound Semiconductors (CS) bring benefit to society in general through developing the connected society, e.g. the 5G network, the smart phones that use it, satellite communications systems and data server infrastructure;

they contribute to reducing our carbon footprint through e.g. photovoltaics, new energy efficient lighting, and, power electronics for the next generation of electric vehicles.

CS sensor technology is at the heart of early medical diagnosis and CS based light sources are essential for both cosmetic treatments, such as hair removal, and life-saving treatments such as Photodynamic Therapy.

CS based magnetic sensors are being developed for security screening and next generation secure communication.

In total these technologies support our connected world, our health, our security and the environment.

ECONOMIC: The global market for CS is large, currently worth around $33.7Bn, with a compound annual growth rate of 17.3%.

The vision of the CS cluster was first defined in 2015, to build on existing academic and industrial assets, capability and manufacturing excellence to create Europe's 5th Semiconductor Cluster and the first in the world dedicated to Compound Semiconductor Technologies. To date the cluster has secured commitments of >£500M private and public investment with a suite of innovation assets and critical manufacturing infrastructure and a purpose to drive UK growth in the CS sector.

It is absolutely critical to recognise that the formation of clusters need ongoing nurturing, cross fertilisation of people and ideas and most importantly the supply of skilled staff to support rapid growth in order to reach critical mass for sustainability. The predicted PhD level jobs increase in just the current local cluster companies would more than use all of the minimum underwritten CDT output over the next 5 years, and we need to do much more. Our CDT is essential to support the development of key elements of the rapidly emerging Compound Semiconductor Cluster and drive new linkages within the wider UK industrial supply chain. Thus addressing the issue of bringing manufacturing supply chains back to the UK - a key element of the Government's Industrial Strategy.

The EPSRC CS roadmap document , June 2012, identified a concern that the UK CS Research Community is missing an exploitation link that can provide a route to impact and economic leverage EPSRC's >£20M pa CS research investment. Many technological solutions work well in the research laboratory or as one-off demonstrators but fail to translate to industrial production or commercial success. The CDT will directly address this issue by changing the mind-set of the next generation of researchers so that they start from solutions that allow rapid translation to production.

OUTREACH:

It is critical that the public and our politicians understand the excellence and importance of CS manufacturing in the UK. Our CDT cohort will undergo training in elevator pitches and media interactions to influence decision makers and will develop videos explaining how Compound Semiconductors are made and what they can do. They will inform a diverse set of people using a range of innovative formats such as performance and theatre production skills.

A crucial part of the people pipeline, which will support our future manufacturing excellence, is the motivation of our young people. Our CDT cohort will develop a Schools programme and an Undergraduate programme.

This will ensure we attract the very best and widest range of applicants and, most importantly, inform and excite the next generation about the opportunities that CS technology and Manufacturing offers them.