Space technologies, data and services have become indispensable in our everyday lives. Communications satellites (COMSATs), alongside optical fibre, are the main means of global data transmission. In fact, for a vast number of users, such as marine and airways fleets, autonomous cars, remotely located aid camps, and hospitals and schools in less developed areas, satellite communication is the only way to broadcast, navigate or access broadband services. Earth observation satellites provide immediate information in the event of natural disasters, and allow better coordination of emergency and rescue teams. Satellite-based technologies help increase the efficiency of fisheries and agriculture, and play an important role in transport by controlling air and maritime traffic. Both COMSAT and surveying services are critically dependent on the communication links between satellites in orbit and ground control stations. Increasing data capacity of these links and allowing frequency flexibility, which cannot be easily provided by established RF solutions, is long overdue. It is clear that industry needs a step change in technology. Against this backdrop, the project focuses on using key advances in photonic integrated solutions to revolutionise satellite payloads (modules). An integrated photonics approach allows for several optoelectronic functionalities (lasers, photodiodes, etc.) to be monolithically integrated on a single chip. Such integration improves robustness, reduces losses between individual devices and, most importantly, offers ease of scalability, low mass and small footprint, creating great prospects to reduce the cost of satellites. Through close collaboration with academic and industrial partners, this project will develop the world's first integrated, broadly tuneable, photonic-based Frequency Generation Unit (FGU) which can be the heart of satellite communication payloads. The advantage of a photonic FGU over the conventional RF-based solution comes from the great frequency agility of the photonic system, which will allow for the FGU to be included both in communication and earth observation satellites. Firstly, the FGU will form part of innovative communication payloads in communication satellites (transponders), allowing for high-throughput data links from satellites to ground stations and, in the future, between satellites. Furthermore, the FGU will also be deployed in earth observation satellites, allowing for reference-signal distribution inside the satellite using a flexible, lightweight optical fibre rather than a conventional coaxial cable. The use of a photonic FGU would dramatically reduce the weight of a satellite, eliminating the need for tens to hundreds of kilograms of coaxial cables (depending on satellite type), and make a significant monetary saving, given the cost of launching into orbit of $25,000/kg. Secondly, a novel architecture for a complete communications payload based almost entirely on photonics is going to be investigated. Replacing conventional RF components with integrated photonic sub-systems will result in an unprecedented mass and volume reduction, which, in turn, will lead to a reduction in the cost of in-orbit-delivered data capacity.

In a consortium led by Heriot-Watt with St Andrews, Glasgow, Strathclyde, Edinburgh and Dundee, this proposal for an "EPSRC CDT in Industry-Inspired Photonic Imaging, Sensing and Analysis" responds to the priority area in Imaging, Sensing and Analysis. It recognises the foundational role of photonics in many imaging and sensing technologies, while also noting the exciting opportunities to enhance their performance using emerging computational techniques like machine learning. Photonics' role in sensing and imaging is hard to overstate. Smart and autonomous systems are driving growth in lasers for automotive lidar and smartphone gesture recognition; photonic structural-health monitoring protects our road, rail, air and energy infrastructure; and spectroscopy continues to find new applications from identifying forgeries to detecting chemical-warfare agents. UK photonics companies addressing the sensing and imaging market are vital to our economy (see CfS) but their success is threatened by a lack of doctoral-level researchers with a breadth of knowledge and understanding of photonic imaging, sensing and analysis, coupled with high-level business, management and communication skills. By ensuring a supply of these individuals, our CDT will consolidate the UK industrial knowledge base, driving the high-growth export-led sectors of the economy whose photonics-enabled products and services have far-reaching impacts on society, from consumer technology and mobile computing devices to healthcare and security. Building on the success of our CDT in Applied Photonics, the proposed CDT will be configured with most (40) students pursuing an EngD degree, characterised by a research project originated by a company and hosted on their site. Recognizing that companies' interests span all technology readiness levels, we are introducing a PhD stream where some (15) students will pursue industrially relevant research in university labs, with more flexibility and technical risk than would be possible in an EngD project. Overwhelming industry commitment for over 100 projects represents a nearly 100% industrial oversubscription, with £4.38M cash and £5.56M in-kind support offered by major stakeholders including Fraunhofer UK, NPL, Renishaw, Thales, Gooch and Housego and Leonardo, as well as a number of SMEs. Our request to EPSRC for £4.86M will support 35 students, from a total of 40 EngD and 15 PhD researchers. The remaining students will be funded by industrial (£2.3M) and university (£0.93M) contributions, giving an exceptional 2:3 cash gearing of EPSRC funding, with more students trained and at a lower cost / head to the taxpayer than in our current CDT. For our centre to be reactive to industry's needs a diverse pool of supervisors is required. Across the consortium we have identified 72 core supervisors and a further 58 available for project supervision, whose 1679 papers since 2013 include 154 in Science / Nature / PRL, and whose active RCUK PI funding is £97M. All academics are experienced supervisors, with many current or former CDT supervisors. An 8-month frontloaded residential phase in St Andrews and Edinburgh will ensure the cohort gels strongly, and will equip students with the knowledge and skills they need before beginning their research projects. Business modules (x3) will bring each cohort back to Heriot-Watt for 1-week periods, and weekend skills workshops will be used to regularly reunite the cohort, further consolidating the peer-to-peer network. Core taught courses augmented with specialist options will total 120 credits, and will be supplemented by professional skills and responsible innovation training delivered by our industry partners and external providers. Governance will follow our current model, with a mixed academic-industry Management Committee and an independent International Advisory Board of world-leading experts.

What is MASI? We believe that there is a strong link between the looming environmental crisis and the way we use chemical elements. In MASI, a multidisciplinary team of scientists from four UK universities (Nottingham, Cardiff, Cambridge, Birmingham), with 12 industrial and academic partners, is set to revolutionise the ways we use metals in a broad range of technologies, and to break our dependence on critically endangered elements. Simultaneously, MASI will make advances in: the reduction of carbon dioxide (CO2) emissions and its valorisation into useful chemicals; the production of 'green' ammonia (NH3) as an alternative zero-emission fuel and a new vector for hydrogen storage; and the provision of more sustainable fuel cells and electrolyser technologies. At the core of MASI is the fundamental science of metal nanoclusters (MNC), which goes beyond the traditional realm of nanoparticles towards the nanometre and sub-nanometre domain including single metal atoms (SMA). The overall goal of the MASI project is two-fold: (i) to provide a solution for a sustainable use of scarce metals of technological importance (e.g. Pt, Au, Pd), by maximising utilisation of every atom; and (ii) to unlock new properties that emerge in metals only at the atomic scale, allowing for the substitution of critical metals with abundant ones (e.g. Pt with Ni), and provide a platform for the next generation of materials for energy, catalysis and electronics applications. How does it work? We have recently developed the theoretical framework and instrumentation necessary to break bulk metals directly to metal atoms or nanoclusters, with their size, shape and composition precisely controlled. The atomic-scale control of nanocluster fabrication will open the door for programming their chemistry. For example, the electronic, catalytic or electrochemical properties of abundant metals, such as Ni and Co, may imitate endangered metals (Pt or Ru) at the nm and sub-nm scale, or by carefully controlled dispersion of the endangered elements with abundant ones in an alloy nanocluster. Our method allows direct deposition of metal atoms or nanoclusters onto solids (e.g. glass, polymer film, paper etc.), powders (e.g. silica, alumina, carbon etc.) and non-volatile liquids (e.g. oils, ionic liquids) in vacuum with no chemicals, solvents or surfactants and an accurately controlled metal loading. The directness of the MASI approach avoids generating chemical waste and enables a high 'atom economy', surpassing any wet chemistry methods. Moreover, surfaces of our metal nanoclusters are clean and highly active; additionally, being stabilised by interactions with the support material, they can be readily applied wherever electronic, optical or catalytic properties of metals are required. What is unique about these materials and our technology? MASI will offer greener, more sustainable methods of fabrication of metal nanoclusters, without solvents or chemicals, with the maximised active surface area ensuring efficient use of each metal atom. 'Naked', highly active metal surfaces are ready for reactions with molecules, activated by heat, light or electric potential, while tuneable interactions with support materials provide durability and reusability of metals in reactions. In particular, MASI materials will be suitable for the activation of hard-to-crack molecules (e.g. N2, H2 and CO2) in reactions that constitute the backbone of the chemical industry, such as the Haber-Bosch process. Similarly, highly dispersed metals and their intimate contact with the support material, will lead to high capacity for energy storage/conversion required in energy materials and fuel cells technologies. Importantly, MASI nanocluster fabrication technology is fully scalable to kilograms and tons of material, making it ideal for uptake in industrial schemes, potentially leading to a green industrial revolution.

Fatigue is the most pervasive failure mode that affects nearly all industrial sectors - including energy industries involving power plants, anemo-electric and tidal stream generators; transport vehicles and aircraft; national infrastructure such railway and bridges; military equipment from a blade in an engine to a whole ship; medical devices and human body implants. The economic cost of fracture has been enormous, approaching 4% of GDP, whereas 50-90% of all these mechanical failures are due to fatigue. Most fatigue failures are unexpected, and can lead to catastrophic consequences. In safety-critical sectors such as the aero-space and nuclear industries, there are ever increasing demands for better understanding of fatigue with respect to the microstructure of metallic components and the demanding environments that they are placed in. The ultra-small, ultra fast fatigue testing techniques I have created are able to make a breakthrough by addressing the classic needle in haystack problem in fatigue crack initiation (FCI) and short crack growth (SCG). Fatigue at these early stages is localized within a few hundred micro-meters. However, they account for more than 50% life in low cycle fatigue (LCF) and approximately 90% in the high cycle fatigue (HCF) regime, and contribute to the largest portion of scatter. My micro- and meso- cantilever techniques are capable of isolating FCI and SCG in selected microstructure features, allowing for the systematic exploration of slip evolution, slip band decohesion and short crack propagation in the context of an exquisitely well characterised volume of material. The ultra-fast testing rate up to 20 kHz means robust exploration can be achieved to 10^9 cycles and beyond, in hours in contrast to months or years demanded by the conventional method. This proposal, through further development of state-of-the-art extremely small and fast fatigue testing techniques, looks to radically change the technical scope of fatigue analysis by allowing environmental effects to be systematically explored at the levels of FCI and SCG and across the HCF and LCF regimes. In-situ ultrasonic fatigue testing rig will be installed in an advanced scanning electron microscope, enabling in-situ observation of the progression of HCF FCI and SCG at the resolution of ~ 1 nm. I will apply these cutting edge techniques to underpinning major fatigue issues in Ti and Ni alloys of technologically importance to the aero-engine industry and proton accelerators, specifically: (i) To achieve a breakthrough in mechanistic understanding of HCF FCI and SCG in titanium alloys with respect to the environments and deliver essential HCF FCI and SCG properties; (ii) To make groundbreaking study of fatigue in Alpha Case and dwelling fatigue in titanium alloys, which are major issues in aero-engine industry; (iii) To determine the effect of the heavy irradiation on HCF performance of Ti-alloys that will be used in the next generation proton accelerators; (iv) To achieve comprehensively understanding of the environmental effect on fatigue in single-crystal nickel superalloys that have the heterogeneous distribution of gamma' phase and element segregation; (v) To determine the HCF and LCF performance of the multi-functional coatings on the surface of a nickel turbo blade in the context of atmosphere, temperature and pre-corrosion treatment. A Ultrasonic Fatigue Testing Centre will be established to satisfy the frequent HCF assessment requests from the industry. The new functions developed on the ultrasonic fatigue testing rig in this project will be transferred to the national lab at Culham to update the bespoke rig in a 'hot cell', for study of active materials in support of fission and fusion innovation.

Since the discovery of the carbonised papyri at Herculaneum in the 18th century, there has been a great deal of interest in accessing the content contained in the scrolls preserved by the intense heat from the eruption of Mount Vesuvius in 79 CE. The first attempts to open these scrolls were made by hand using a knife, but this caused them to break into fragmented chunks. Subsequently in 1756 a machine was invented to create a safer method of unrolling, which was more successfully applied to numerous scrolls. However, in many cases it was impossible to keep the different layers of papyrus from sticking to each other, and so substantial portions of text remained hidden in even successfully opened scrolls, while hundreds of scrolls remained too firmly carbonised to unroll at all. The content of these fully intact scrolls, together with that of text under the stuck-on layers remains a mystery. New technology offers a solution. In the early 21st century the application of non-invasive CT scanning, a concept already proved by project members, reveals new possibilities. The structure of a scroll can be rendered digitally in three dimensions, revealing the layers of the papyrus in the scroll's circumference. Computational methods for algorithmically separating, unrolling, and flattening these layers have been developed by project members over the past decade. The virtual unrolling method has been successfully applied to P. Herc. 375 and 495. Nevertheless, despite such an achievement, the ink does not appear with any significant clarity. And while faint traces of a handful of Greek letters have been transcribed, there is currently no means to verify and replicate such results. This project aims to address the problem of detecting ink in this non-invasive imaging and thus definitively solve the long-standing problem posed by the Herculaneum papyri. In 2016 project members successfully applied the virtual unrolling method to a carbonised Hebrew scroll from the site of Ein Gedi in Israel. The ink was immediately visible, but this was due to the fact that it was contaminated with heavy trace elements and thus naturally appeared in CT scanning. The carbon-based ink used in Herculaneum papyri cannot be visualised in the same way. However, we now know that the ink is weakly contaminated with lead. We thus propose a new method called Dark Field X-ray Imaging. This reveals ink by isolating and capturing trace elements, such as lead, in its composition. To enhance the resulting ink signal further we introduce a new neural network called Reference-Amplified Computed Tomography (RACT) to amplify both the ink's presence and the shapes of the Greek characters for improved legibility. This method will definitively solve the problem of reading the text hidden in the Herculaneum papyri. To add value, the project will make the data generated by this process accessible to researchers and the curators responsible for these artefacts, by developing a new digital platform, the Augmented Language Interface for Cultural Engagement (ALICE), ensuring that the data produced by the Dark Field X-ray Imaging and RACT processes is accessible, can be properly curated, and that the extracted text can be digitally edited. Moreover, ALICE includes the functionality for integrating 3D models of the original artefact and for recording the metadata that explains both how the text was created and from where in the object's geometry the text originates in the model generated along with its digital edition. This is necessary for scientifically verifying and replicating any subsequent analysis or publication of the data. Significantly, for other cultural heritage artefacts that contain hidden text, our new imaging techniques and digital platform will be built using open architecture standards; the source code will be easily adaptable for non-invasive reading of writing inside other intractable artefacts, such as burnt books, book-bindings, and mummy cartonnage.