The process of crystal nucleation from solution requires, as its initial stage, separation of solute and solvent molecules and simultaneous formation of molecular clusters in order to create a new, nano scale, phase which can subsequently grow to become a crystal. Elucidating the fundamental physics and chemistry that govern the structure of this nucleation transition state remains one of the truly unresolved 'grand challenges' of the physical sciences. Individual nucleation events are localised in space but rather infrequent on the time-scale of a molecular vibration making both experimental detection and molecular modelling of the process difficult. In addition to this, available experimental techniques provide data averaged over both time and space so that extracting insights into the nucleation process may only be achieved through a combination of experiment and modelling. We propose a novel approach to this problem in which we scrutinise the crystallisation of two related molecular systems in hitherto unprecedented depth, building on established state-of-the-art experimental and computational techniques, but combining these, for the first time, with in situ synchrotron radiation (SR) X-ray scattering and spectroscopy methodologies capable of probing long range and local electronic and geometric structure at molecular resolution. Our hypothesis is that, by utilising appropriate experimental conditions, applying these state of the art time resolved scattering and spectroscopic techniques and building cluster models that are consistent with macroscopic features of the systems studied (crystal morphology, polymorphic form, solution chemistry, crystal growth rates), we can deduce a structural model of a nucleation event from the change in averaged solution structure as a function of increasing solution supersaturation and time. We thus expect incisive structural information for every step of the nucleation process: measured molecular scale properties can be used to confront computational predictions at molecular, supra-molecular and solid-state levels, so that the structural and size parameters for the nucleation pathway are revealed. A step change in our understanding of this area of science is thus expected.

Recently, an influential American business magazine, Forbes, chose Quantum Engineering as one of its top 10 majors (degree programmes) for 2022. According to Forbes magazine (September 2012): "a need is going to arise for specialists capable of taking advantage of quantum mechanical effects in electronics and other products." We propose to renew the CDT in Controlled Quantum Dynamics (CQD) to continue its success in training students to develop quantum technologies in a collaborative manner between experiment and theory and across disciplines. With the ever growing demand for compactness, controllability and accuracy, the size of opto-electronic devices in particular, and electronic devices in general, is approaching the realm where only fully quantum mechanical theory can explain the fluctuations in (and limitations of) these devices. Pushing the frontiers of the 'very small' and 'very fast' looks set to bring about a revolution in our understanding of many fundamental processes in e.g. physics, chemistry and even biology with widespread applications. Although the fundamental basis of quantum theory remains intact, more recent theoretical and experimental developments have led researchers to use the laws of quantum mechanics in new and exciting ways - allowing the manipulation of matter on the atomic scale for hitherto undreamt of applications. This field not only holds the promise of addressing the issue of quantum fluctuations but of turning the quantum behaviour of nano- structures to our advantage. Indeed, the continued development of high-technology is crucial and we are convinced that our proposed CDT can play an important role. When a new field emerges a key challenge in meeting the current and future demands of industry is appropriate training, which is what we propose to achieve in this CDT. The UK plays a leading role in the theory and experimental development of CQD and Imperial College is a centre of excellence within this context. The team involved in the proposed CDT covers a wide range of key activities from theory to experiment. Collectively we have an outstanding track record in research, training of postgraduate students and teaching. The aim of the proposed CDT is to provide a coherent training environment bringing together PhD students from a wide variety of backgrounds and giving them an appreciation of experiment and theory of related fields under the umbrella of CQD. Students graduating from our programme will subsequently find themselves in high-demand both by industry and academia. The proposed CDT addresses the EPSRC strategic area 'Quantum Information Processing and Quantum Optics" and one of the priority areas of the CDT call, "Towards Quantum Technologies". The excellence of our doctoral training has been recognised by the award of a highly competitive EU Innovative Doctoral Programme (IDP) in Frontiers of Quantum Technology, which will start in October 2013 running for four years with the budget around 3.8 million euros. The new CDT will closely work with the IDP to maximise synergy. It is clear that other high-profile activities within the general area of CQD are being undertaken in a range of other UK universities and within Imperial College. A key aim of our DTC is inclusivity. We operate a model whereby academics from outside of Imperial College can act as co-supervisors for PhD students on collaborative projects whereby the student spends part of the PhD at the partner institution whilst remaining closely tied to Imperial College and the student cohort. Many of the CDT activities including lectures and summer schools will be open to other PhD students within the UK. Outreach and transferable skills courses will be emphasised to provide a set of outreach classes and to organise various outreach activities including the CDT in CQD Quantum Show to the general public and CDT Festivals and to participate in Imperial's Science Festivals.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Abstracts are not currently available in GtR for all funded research. This is normally because the abstract was not required at the time of proposal submission, but may be because it included sensitive information such as personal details.

Dental enamel is the hardest mineralised tissue in the body and its complex hierarchical microstructure allows different structural adaptations against the robust challenges in the oral cavity. However, unlike other tissues, enamel lacks the ability to repair or remodel and under conditions of attack by acid produced from bacteria adhering to tooth structure, it loses its integrity and initiates the progression of dental caries, the most widespread dental disease. Despite tremendous efforts to improve oral hygiene and preventive measures by means of fluoridation, more than 2.3 billion adults suffer from caries (Global burden of Disease 2017) and account for massive expenditure as high as £3.4 billion every year (Public health England 2020, NHS England 2014). These distressing details presented in national reports emphasize the prime importance of this research topic and its significant impact on national economy, scientific community, and society in general. To tackle the problem, modern dentistry now aims to curb this dental disease by promoting enamel repair at the initial/incipient stages of caries development to prevent the need for invasive restorative procedures at later stages. In this research proposal we wish to tackle incipient enamel caries by investigating the hierarchical assembly of enamel structure at different length scales (nano- to micro- to macro-) and based on this understanding, develop and refine a new strategy for repair/remineralisation, and ultimately obtain the ability to regenerate enamel with optimal structure and improved properties directly in patients' mouths. By employing a joint interdisciplinary approach involving specialists in dental research at Birmingham and specialists in multimodal microscopy, spectroscopy and modelling at Oxford, we intend to analyse the enamel demineralisation as well as repair by combining conventional dentistry techniques such as clinical visualisation, tactile perception, radiography, laboratory computed tomography etc. with time-resolved 3D structural (hence 4D) evaluation. This will be done at the spatial resolution ranging from atomic crystal lattice to nano, micro-, and macro-scale by advanced microscopic imaging and spectroscopic techniques integrated with microfluidics. The proposers have worldwide associations with research groups across different universities, companies and practicing dentists. Industrial partnership with GlaxoSmithKline and the long established collaborative link with Diamond Light Source (UK synchrotron), ISIS Neutron and Muon source, Tescan and Oxford instruments will provide access to state-of-the-art research methodologies and ensure delivering broadest national and international impact. The project objectives cover (i) identifying and securing supply of representative samples, (ii) observing ultrastructural evolution of enamel during incipient caries demineralisation, (iii) developing and refining minimally invasive remineralisation procedures, and (iv) developing multi-scale mathematical models. This work plan encompasses all themes of EPSRC Healthcare Technologies Grand Challenges ranging from developing future therapies and frontiers of physical intervention to optimising treatment and transforming community health and care. Additionally, the development of macro- and micro-fluidic systems, remineralisation strategies, multi-modal microscopy, and mathematical modelling of enamel structure and the complete disease process shall contribute to the advancement of Cross-Cutting Research Capabilities in areas of advanced materials, novel imaging technologies, and novel computational and mathematical sciences, respectively. The greatest anticipated outcome from the success of this project will be the introduction of new minimally intrusive means of reversing or preventing enamel caries that will be of massive benefit to individuals and the economy, and the society at large.