Quantum physics describes how nature links the properties of isolated microscopic objects through interactions mediated by so-called quantum entanglement and that apply not just to atoms but also to particles of light, "photons". These discoveries led to the first "quantum revolution", delivering a range of transformative technologies such as the transistor and the laser that we now take for granted. We are now on the cusp of a second "quantum revolution", which will, over the next 5-10 years, yield a new generation of electronic and photonic devices that exploit quantum science. The challenge is to secure a leadership position in the race to the industrialisation of quantum physics to claim a large share of this emerging global market, which is expected to be worth £1 billion to the UK economy. QuantIC, the UK's centre for quantum imaging, was formed over four years ago to apply quantum technologies to the development of new cameras with unique imaging capabilities. Tangible impacts are the creation of 3 new companies (Sequestim, QLM and Raycal), technology translation into products through licencing (Timepix chip - Kromek) and the ongoing development with industry of a further 12 product prototypes. Moving forward, QuantIC will continue to drive paradigm-changing imaging systems such as the ability to see directly inside the human body, the ability to see through fog and smoke, to make microscopes with higher resolution and lower noise than classical physics allows and quantum radars that cannot be jammed or confused by other radars around them. These developments will be enabled by new technologies, such as single-photon cameras, detectors based on new materials and single-photon sensitivity in the mid-infrared spectral regions. Combined with our new computational methods, QuantIC will enable UK industry to lead the global imaging revolution. QuantIC will dovetail into other significant investments in the Quantum technology transfer ecosystem which is emerging in the UK. The University of Glasgow has allocated one floor of the £118M research hub to supporting fundamental research in quantum science and £28M towards the creation of the Clyde Waterfront Innovation Campus, a new £80M development in collaboration with Glasgow City Council and Scottish Enterprise focussing on the translation of nano and quantum science for enabling technologies such as photonics, optoelectronics and quantum. Heriot-Watt has invested over £2M in new quantum optics laboratories and is currently building a £20M Global Research Innovation and Discovery Centre opening in 2019 to drive the translation of emerging technologies. Bristol is creating a £43M Quantum Innovation centre which already has £21M of industrial investment. Strathclyde University is creating a second £150M Technology Innovation Centre around 6 priority areas, one of which is Quantum Technology. All of these form part of the wider UK Quantum Technology Programme which is set to transform the UK's world leading science into commercial reality in line with the UK's drive towards a high productivity and high-skill economy. QuantIC will lead the quantum imaging research agenda and act as the bond between parallel activities and investments, thus ensuring paradigm-changing innovation that will transform tomorrow's society.

Quantum Technologies (QT) are at a pivotal moment with major global efforts underway to translate quantum information science into new products that promise disruptive impact across a wide variety of sectors from communications, imaging, sensing, metrology, simulation, to computation and security. Our world-leading Centre for Doctoral Training in Quantum Engineering will evolve to be a vital component of a thriving quantum UK ecosystem, training not just highly-skilled employees, but the CEOs and CTOs of the future QT companies that will define the field. Due to the excellence of its basic science, and through investment by the national QT programme, the UK has positioned itself at the forefront of global developments. There have been very recent major [billion-dollar] investments world-wide, notably in the US, China and Europe, both from government and leading technology companies. There has also been an explosion in the number of start-up companies in the area, both in the UK and internationally. Thus, competition in this field has increased dramatically. PhD trained experts are being recruited aggressively, by both large and small firms, signalling a rapidly growing need. The supply of globally competitive talent is perhaps the biggest challenge for the UK in maintaining its leading position in QT. The new CDT will address this challenge by providing a vital source of highly-trained scientists, engineers and innovators, thus making it possible to anchor an outstanding QT sector here, and therefore ensure that UK QT delivers long-term economic and societal benefits. Recognizing the nature of the skills need is vital: QT opportunities will be at the doctoral or postdoctoral level, largely in start-ups or small interdisciplinary teams in larger organizations. With our partners we have identified the key skills our graduates need, in addition to core technical skills: interdisciplinary teamwork, leadership in large and small groups, collaborative research, an entrepreneurial mind-set, agility of thought across diverse disciplines, and management of complex projects, including systems engineering. These factors show that a new type of graduate training is needed, far from the standard PhD model. A cohort-based approach is essential. In addition to lectures, there will be seminars, labs, research and peer-to-peer learning. There will be interdisciplinary and grand challenge team projects, co-created and co-delivered with industry partners, developing a variety of important team skills. Innovation, leadership and entrepreneurship activities will be embedded from day one. At all times, our programme will maximize the benefits of a cohort-based approach. In the past two years particularly, the QT landscape has transformed, and our proposed programme, with inputs from our partners, has been designed to reflect this. Our training and research programme has evolved and broadened from our highly successful current CDT to include the challenging interplay of noisy quantum hardware and new quantum software, applied to all three QT priorities: communications; computing & simulation; and sensing, imaging & metrology. Our programme will be founded on Bristol's outstanding activity in quantum information, computation and photonics, together with world-class expertise in science and engineering in areas surrounding this core. In addition, our programme will benefit from close links to Bristol's unique local innovation environment including the visionary Quantum Technology Enterprise Centre, a fellowship programme and Skills Hub run in partnership with Cranfield University's Bettany Centre in the School of Management, as well as internationally recognised incubators/accelerators SetSquared, EngineShed, UnitDX and the recently announced £43m Quantum Technology Innovation Centre. This will all be linked within Bristol's planned £300m Temple Quarter Enterprise Campus, placing the CDT at the centre of a thriving quantum ecosystem.