This Hub accelerates progress towards a new "quantum era" by engineering small, high precision quantum systems, and linking them into a network to create the world's first truly scalable quantum computing engine. This new computing platform will harness quantum effects to achieve tasks that are currently impossible. The Hub is an Oxford-led alliance of nine universities with complementary expertise in quantum technologies including Bath, Cambridge, Edinburgh, Leeds, Strathclyde, Southampton, Sussex and Warwick. We have assembled a network of more than 25 companies (Lockheed-Martin, Raytheon BBN, Google, AMEX), government labs (NPL, DSTL, NIST) and SMEs (PureLiFi, Rohde & Schwarz, Aspen) who are investing resources and manpower. Our ambitious flagship goal is the Q20:20 engine - a network of twenty optically-linked ion-trap processors each containing twenty quantum bits (qubits). This 400 qubit machine will be vastly more powerful than anything that has been achieved to date, but recent progress on three fronts makes it a feasible goal. First, Oxford researchers recently discovered a way to build a quantum computer from precisely-controlled qubits linked with low precision by photons (particles of light). Second, Oxford's ion-trap researchers recently achieved a new world record for precision qubit control with 99.9999% accuracy. Third, we recently showed how to control photonic interference inside small silica chips. We now have an exciting opportunity to combine these advances to create a light-matter hybrid network computer that gets the 'best of both worlds' and overcomes long-standing impracticalities like the ever increasing complexity of matter-only systems, or the immense resource requirements of purely photonic approaches. Engineers and scientists with the hub will work with other hubs and partners from across the globe to achieve this. At present proof-of-principle experiments exist in the lab, and the 'grand challenge' is to develop compact manufacturable devices and components to build the Q20:20 engine (and to make it easy to build more). We have already identified more than 20 spin-offs from this work, ranging from hacker-proof communication systems and ultra-sensitive medical and military sensors to higher resolution imaging systems. Quantum ICT will bring great economic benefits and offer technical solutions to as yet unsolveable problems. Just as today's computers allow jet designers to test the aerodynamics of planes before they are built, a quantum computer will model the properties of materials before they've been made, or design a vital drug without the trial and error process. This is called digital quantum simulation. In fact many problems that are difficult using conventional computing can be enhanced with a 'quantum co-processor'. This is a hugely desirable capability, important across multiple areas of science and technology, so much so that even the prospect of limited quantum capabilities (e.g. D-Wave's device) has raised great excitement. The Q20:20 will be an early form of a verifiable quantum computer, the uncompromised universal machine that can ultimately perform any algorithm and scale to any size; the markets and impacts will be correspondingly far greater. In addition to computing there will be uses in secure communications, so that a 'trusted' internet becomes feasible, in sensing - so that we can measure to new levels of precision, and in new components - for instance new detectors that allow us to collect single photons. The hub will ultimately become a focus for an emerging quantum ICT industry, with trained scientists and engineers available to address the problems in industry and the wider world where quantum techniques will be bringing benefits. It will help form new companies, new markets, and grow the UK's knowledge economy.

Digital technologies and services are shaping our lives. Work, education, finance, health, politics and society are all affected. They also raise concomitant and complex challenges relating to the security of and trust in systems and data. TIPS (Trust, Identity, Privacy and Security) issues thus lie at the heart of our adoption of new technologies and are critical to our economic prosperity and the well-being of our citizens. Identifying and addressing such issues requires a coherent, coordinated, multi-disciplinary approach, with strong stakeholder relationships at the centre. SPRITE+ is a vehicle for communication, engagement, and collaboration for people involved in research, practice, and policy relevant to TIPS in digital contexts. Since launching in 2019, we have established ourselves as the go-to point of contact to engage with the broadest UK network of interdisciplinary, cross-sector digital TIPS experts. The second phase of SPRITE+ ('SPRITE+2') will continue to build our membership, whilst expanding the breadth and depth of our innovation, and deepen our impact through proactive engagement. SPRITE+2 will have the following objectives: 1. Expand our TIPS community, harnessing the expertise and collaborative potential of the national and international TIPS communities 2. Identify and prioritise future TIPS research challenges 3. Explore and develop priority research areas to enhance our collective understanding of future global TIPS challenges 4. Stimulate innovative research through sandpits, industry led calls, and horizon scanning 5. Deepen engagement with TIPS research end users across sectors to accelerate knowledge Exchange 6. Understand, inform, and influence policy making and practice at regional, national and international level These will be delivered through four work packages and two cross cutting activities. All work packages will be led by the PI (Elliot) to ensure that connections are made and synergies exploited. Each sub-work package will be led by a member of the Management Team and supported by our Expert Fellows and Project Partners. WP1 Develop the Network We will deliver a set of activities designed to expand, broaden, and engage the network, from expert meetings and workshops to student bootcamps and international conferences. WP2 Engage stakeholders to enhance knowledge exchange and deliver impact. We will be greatly enhancing our purposive engagement activity in SPRITE+2. This activity will include a new business intelligence function and PP engagement grants, designed to enhance mutual understanding between researchers and stakeholders. WP3 Identify, prioritise, and explore future TIPS challenges We will select and then investigate priority areas of future TIPS. Two areas are pre-scoped based on the work we have done so far in SPRITE+ (TIPS in digital cities; trustworthy digital identities) with a further two be identified during the lead up to SPRITE+2. WP4 Drive innovation in research This WP concerns the initiation and production of high-quality impactful research. Through horizon scanning, sandpits and industry-led calls, we will steer ideas through an innovation pipeline ensuring SPRITE+2 is future focused. Cross cutting activities The first cross-cutting activity will accelerate the translation of TIPS research into policy and practice for public and private sector end uses. The second focuses on mechanisms to facilitate communication within our community. The experiences of SPRITE+ and the other DE Network+s demonstrate that it takes years of consistent and considerable effort for a new network to grow membership and develop productive relationships with stakeholders. In SPRITE+2 grant we would hit the ground running and maximise the impact of four additional years of funding. A successful track record, a well-established team, and a raft of ambitious new plans provide a solid foundation for strong delivery in 2023-27.

Plastic Electronics embodies an approach to future electronics in their broadest sense (including electronic, optoelectronic and photonic structures, devices and systems) that combines the low temperature, versatile manufacturing attributes of plastics with the functional properties of semiconductors and metals. At its heart is the development, processing and application of advanced materials encompassing molecular electronic materials, low temperature processed metals, metal oxides and novel hybrids. As such it constitutes a challenging and far-ranging training ground in tune with the needs of a wide spectrum of industry and academia alike. The general area is widely recognised as a rapidly developing platform technology with the potential to impact on multiple application sectors, including displays, signage and lighting, large area electronics, energy generation and storage, logistics, advertising and brand security, distributed sensing and medical devices. The field is a growth area, nationally and globally and the booming organic (AMOLED) display and printed electronics industries have been leading the way, with the emerging opportunities in the photonics area - i.e. innovative solid-state lighting, solar (photovoltaics), energy storage and management now following. The world-leading, agenda-setting UK academic PE research, much of it sponsored by EPSRC, offers enormous potential that is critical for the development and growth of this UK technology sector. PE scientists are greatly in demand: both upstream for materials, process and equipment development; and downstream for device fabrication and wide-ranging applications innovation. Although this potential is recognised by UK government and industry, PE makes a major contribution to the Advanced Materials theme identified in Science Minister David Willet's 'eight great technologies', growth is severely limited by the shortage of trained scientists and engineers capable of carrying ideas forward to application. This is confirmed by industry experts who argue that a comprehensive training programme is essential to deliver the workforce of scientists and engineers needed to create a sustainable UK PE Industry. The aim of the PE-CDT is to provide necessary training to develop highly skilled scientists and engineers, capable both of leading development and of contributing growth in a variety of aspects; materials-focused innovation, translation and manufacturing. The CDT brings together three leading academic teams in the PE area: the Imperial groups, with expertise in the synthesis, materials processing, characterisation, photonics and device physics, the Oxford team with expertise in ultrafast spectroscopes probes, meso and nano-structured composites, vacuum processing and up scaling as well as the material scientists and polymer technologists at QMUL. This compact consortium encompasses all the disciplines relevant to PE, including materials physics, optoelectronics, physical chemistry, device engineering and modelling, design, synthesis and processing as well as relevant industrial experience. The programme captures the essentially multidisciplinary nature of PE combining the low temperature, versatile manufacturing attributes of plastics with the functional properties of semiconductors and metals. Yet, to meet the needs of the PE industry, it also puts in place a deep understanding of basic science along with a strong emphasis on professional skills and promoting interdisciplinary learning of high quality, ranging across all areas of plastic electronics.