This proposal seeks funding to create a Centre for Doctoral Training (CDT) in Connected Electronic and Photonic Systems (CEPS). Photonics has moved from a niche industry to being embedded in the majority of deployed systems, ranging from sensing, biophotonics and advanced manufacturing, through communications from the chip-to-chip to transcontinental scale, to display technologies, bringing higher resolution, lower power operation and enabling new ways of human-machine interaction. These advances have set the scene for a major change in commercialisation activity where electronics photonics and wireless converge in a wide range of information, sensing, communications, manufacturing and personal healthcare systems. Currently manufactured systems are realised by combining separately developed photonics, electronic and wireless components. This approach is labour intensive and requires many electrical interconnects as well as optical alignment on the micron scale. Devices are optimised separately and then brought together to meet systems specifications. Such an approach, although it has delivered remarkable results, not least the communications systems upon which the internet depends, limits the benefits that could come from systems-led design and the development of technologies for seamless integration of electronic photonics and wireless systems. To realise such connected systems requires researchers who have not only deep understanding of their specialist area, but also an excellent understanding across the fields of electronic photonics and wireless hardware and software. This proposal seeks to meet this important need, building upon the uniqueness and extent of the UCL and Cambridge research, where research activities are already focussing on higher levels of electronic, photonic and wireless integration; the convergence of wireless and optical communication systems; combined quantum and classical communication systems; the application of THz and optical low-latency connections in data centres; techniques for the low-cost roll-out of optical fibre to replace the copper network; the substitution of many conventional lighting products with photonic light sources and extensive application of photonics in medical diagnostics and personalised medicine. Many of these activities will increasingly rely on more advanced systems integration, and so the proposed CDT includes experts in electronic circuits, wireless systems and software. By drawing these complementary activities together, and building upon initial work towards this goal carried out within our previously funded CDT in Integrated Photonic and Electronic Systems, it is proposed to develop an advanced training programme to equip the next generation of very high calibre doctoral students with the required technical expertise, responsible innovation (RI), commercial and business skills to enable the £90 billion annual turnover UK electronics and photonics industry to create the closely integrated systems of the future. The CEPS CDT will provide a wide range of methods for learning for research students, well beyond that conventionally available, so that they can gain the required skills. In addition to conventional lectures and seminars, for example, there will be bespoke experimental coursework activities, reading clubs, roadmapping activities, responsible innovation (RI) studies, secondments to companies and other research laboratories and business planning courses. Connecting electronic and photonic systems is likely to expand the range of applications into which these technologies are deployed in other key sectors of the economy, such as industrial manufacturing, consumer electronics, data processing, defence, energy, engineering, security and medicine. As a result, a key feature of the CDT will be a developed awareness in its student cohorts of the breadth of opportunity available and the confidence that they can make strong impact thereon.

We seek to exploit the highly advantageous properties of III-V semiconductors to achieve agenda setting advances in the quantum science and technology of solid state materials. We work in the regime of next generation quantum effects such as superposition and entanglement, where III-V systems have many favourable attributes, including strong interaction with light, picosecond control times, and microsecond coherence times before the electron wavefunction is disturbed by the environment. We employ the principles of nano-photonic design to access new regimes of physics and potential long term applications. Many of these opportunities have only opened up in the last few years, due to conceptual and fabrication advances. The conceptual advances include the realisation that quantum emitters emit only in one direction if precisely positioned in an optical field, that wavepackets which propagate without scattering may be achieved by specific design of lattices, and that non-linearities are achievable at the level of one photon and that quantum blockade can be realised where one particle blocks the passage of a second. The time is now right to exploit these conceptual advances. We combine this with fabrication advances which allow for example reconfigurable devices to be realised, with on-chip control of electronic and photonic properties. We take advantage of the highly developed III-V fabrication technology, which underpins most present day solid-state light emitters, to achieve a variety of chip-based quantum physics and device demonstrations. Our headline goals include reconfigurable devices at the single photon level, a single photon logic gate based on the fully confined states in quantum dots positioned precisely in nano-photonic structures, and coupling of states by designed optical fields, taking advantage of the reconfigurable capability, to enhance or suppress optical processes. Quantum dots also have favourable spin (magnetic moments associated with electrons) properties. We plan to achieve spins connected together by photons in an on-chip geometry, a route towards a quantum network, and long term quantum computer applications. As well as quantum dots, III-V quantum wells interact strongly with light to form new particles termed polaritons. We propose to open the new field of topological polaritonics, where the nano-photonic design of lattices leads to states which are protected from scattering and where artificial magnetic fields are generated. This opens the way to new coupled states of matter which mimic the quantised Hall effects, but in a system with fundamentally different wavefunctions from electrons. Finally our programme also depends on excellent crystal growth. We target one of the main issues limiting long term scale up of quantum dot technologies, namely site control. We will employ two approaches, which involve a combination of patterning, cleaning and crystal growth to define precisely the quantum dot location, both based around the formation of pits to seed growth in predetermined locations. Success here will be a major step in bringing semiconductor quantum optics into line with the position enjoyed by the majority of established semiconductor technologies where scalable lithographic processes have been a defining feature of their impact.

With more than 300 papers published on the topic, the Condensed Matter group in Leeds is well known for its work on spintronics - a subject defined by the exploitation of the magnetic moment of electrons instead of charge. Recently the group has appointed two new members of staff bringing us expertise in organic spintronics (Cespedes) and nanomagnetism (Moore). Thus we are one of the first groups to develop high frequency equipment for molecular spintronics in order to research eco-friendly microwave devices. We are also exploring ways of switching magnetisation using the strain developed by an electric field - important for future storage applications. Although we have links among all members of the group, this Platform provides an excellent opportunity to take a strategic look at our activity. Our broad research strategy will concern the general theme of spintronic metamaterials. Metamaterials are artificial in that the functional properties are not a feature of the natural occurring materials that form the building blocks, but emerge through design and engineering of material combinations. The artificial aspect is often introduced through nanostructuring. An early example arises in optics where sub-wavelength features give rise to new properties such as photonic band-gap crystals. Magnetic metamaterials were at the dawn of spintronics - a multilayer composed of alternating magnetic and non-magnetic metals displays giant magnetoresistance. These properties have been exploited to great advantage in computing and communication. We aim to move from common magnetoresistive devices and spin transport physics into microwave nanodevices that manipulate the interactions between electrons with phonons, magnons and other quasiparticles in hybrid structures. Building on our recognised strengths of thin film growth, characterisation and magnetotransport we are proposing a programme of engineering materials in combinations that yield fruitful emergent properties - spintronic metamaterials. Our group has a broad background that includes the ability to structure materials at the nanoscale so that cooperative behaviour arises, e.g. combining superconductors with skyrmion spin textures, or injecting pure spin currents from magnets into organics. We will apply this capability to questions in areas identified as strategic such as quantum effects for new technology, beyond CMOS electronics, energy efficient electronics and new tools for healthcare. We shall pursue this in a way that is very different from a traditional responsive-mode research project. We have identified areas that are scientifically and nationally important and where we can make impact in both academic and technological settings. We will not specify exactly which experiments will be performed, only the type of experiment that is possible. We will use the flexibility of platform funding to develop the independence of researchers beyond that achievable in a normal grant. As an example, there is a controversy at present about the role of heat and magnetic proximity effects in spin currents and their possibilities in non-dissipative, low power consumption electronics. With platform funding we can send a researcher to visit the relevant labs and attend the workshops who would then be in a good position to recommend the best course of action. The researcher would lead those experiments with full support for necessary resources - including and encouraging, if appropriate, the contribution of PhD students and other PDRAs. This general approach can be applied across our whole platform programme to any emerging problems in the field. This is career-enhancing because researchers, at this stage of their research, can usually only gain this level of autonomy if they are independent Research Fellows. This background will fast track them for Research Fellowships or good positions in industry or top level institutions looking for individuals with initiative and vision.

The march of technological progress has given us devices that are ever smaller and more complex: today's smart phones for example are almost unrecognizable in their size and their range of functions from the models of 25 years ago. This progress has taken us to the point where devices must now be understood in terms of the quantum behaviour of their constituent particles, a new frontier in technology that furthermore will lead to completely new applications. However, building fully quantum mechanical models of devices is notoriously difficult: the amount of information needed to describe a quantum system scales exponentially with its size. The situation is even worse when one must consider how the environment interacts with the device, and yet this is a crucial consideration for real devices. However, we have recently developed a new quantum simulation technique with remarkable efficiency: by keeping just the most important information we are able to track the behaviour of a single particle even when it is interacting very strongly with all of the other particles in its environment. In this project, we will exploit this new technique to design, simulate, and optimize four types of nanoscale devices with various technological applications. The functioning of all these devices relies on similar physics, namely how the device interacts with the environment. As such, our new method is ideally suited to all these areas. First, we will model solid state single photon sources. These produce quanta of light - photons - one at a time, and underpin future ideas for secure communication and quantum computing. We will find how the coupling between the photons and the vibrations of the solid determines affects their performance. Understanding this will allow us to determine how devices, either machined as thin wires or membranes or drawn as nanometre patterns in a solid matrix, could create more effective photon sources. Second, solar panels need to first absorb light energy from the sun, and then to transport it to electrodes. We will investigate the quantum mechanics of this energy transport problem, in particular for solar cells made of organic materials. Here, vibrations are very strongly coupled to the excited electrons that transport the energy, and our new technique is ideal for studying how this process works and how it might be improved by informed selection of component organic molecules. Third, a new frontier in electronics will be enabled if we can build circuits using molecules. Electric current is then a consequence of how electrons can tunnel quantum mechanically from one molecule to the next; this depends both on electronic coupling between molecules and how the molecules vibrate. We will use our technique to build models of molecular junctions, and explore how strong electronic and vibrational coupling changes the quantum transport properties of these materials. Fourth, diamonds have recently been at the forefront of a whole new kind of imaging technology. In particular, single electrons in diamond have a tiny magnetic moment, a 'spin', whose motion depends on how strong the magnetic field is at the position of the electron. Remarkably, the spin of a single electron can be measured in diamond, and so magnetic imaging with nanometre accuracy is a possibility. The limit of how well these 'nano-magnetometers' can work is set by how well they can be isolated from their environment. In this project, we will first use our novel approach to understand the dynamics of a spin coupled to its environment, and then show how to isolate spins more effectively. The project will advance several different nanotechnologies, and at the same time we will develop a unique and freely available tool that can be applied to a huge variety of new systems in future.

Most advanced materials are actually composite systems where each part is specifically tailored to provide a particular functionality often via doping. In electronic devices this may be p- or n-type behaviour (the preference to conduct positive of negative charges), in optical devices the ability to emit light at a given wavelength (such as in the infrared for optical fibre communications), or in magnetic materials the ability to store information based on the direction of a magnetic field for example. To enable the realisation of new devices it is essential to increase the density of functionality within a given device volume. Simple miniaturisation (i.e. to fit more devices of the same type but of smaller size) is limited in scope as the nanoscale regime is reached, not only by the well-known emergence of quantum effects, but by the simple capability to control the materials engineering on this scale. Self-assembly methods for example enable the creation of 0D (so called 'quantum dots' or 'artificial atoms'), 1D (wire-like) and 2D (sheet-like) materials with unique properties, but the subsequent control and modification of these is non-trivial and has yet to be demonstrated in many cases. This research aims to establish a Platform for Nanoscale Advanced Materials Engineering (P-NAME) facility that incorporates a new tool which will provide the capability required to deliver a fundamental change in our ability to design and engineer materials. The principle of the technique that we will adapt, is that which revolutionised the micro-electronics industry in the 20th century (ion-doping) but applied on the nanoscale for the first time. Furthermore, the P-NAME tool will be compatible with a scalable technology platform and therefore compatible with its use in high-tech device manufacture. Without this capability the production of increasingly complex materials offering enhance functionality at lower-power consumption will be difficult to achieve. The P-NAME facility will be established within a new UK National Laboratory for Advanced Materials (the Henry Royce Institute) at the University of Manchester. Access to the tool will be made available to UK academics and industry undertaking research into advanced functional materials and devices development.