Field Effected Aerosol Assisted Chemical Vapour Deposition (FE-AACVD) of Thin Film Materials

Thin inorganic films as seen in metal oxide semiconductors can perform wide-ranging electronic and energy storage applications and possess great potential for both industry and society. Metal oxide materials generated by Aerosol Assisted Chemical Vapour Deposition (AACVD) typically form in a specific orientation of crystallinity and structure, termed a morphology, for each precursor combination and substrate used. The directing effects of electric and magnetic fields on aerosolised precursors in AACVD during transport and deposition will be investigated with the aim of accessing thin inorganic films with novel morphologies of improved efficacy. The initial target will be making semiconducting photoelectrodes of use in water splitting processes.

The chemical synthesis of both known and novel d-block and/or f-block inorganic precursors to be deposited will first be achieved, targeting single source precursor designs where possible. Dipolar and paramagnetic precursors of elements such as vanadium and iron appear promising candidates for maximising synergy with electric and magnetic fields. Work by L. Romero, R. Binions et al. concerning titanium dioxide film synthesis under electric field AACVD will provide a suitable reference point.
Control AACVD depositions will be performed before the morphological impact of introducing electric and magnetic fields during deposition is investigated. Analytical techniques e.g., X-ray diffraction and scanning electron microscopy, will be used to interpret results. The most promising precursor(s) will be taken forwards for an in-depth analysis of aerosol composition and distribution during transport to gain understanding of correlations with morphological control.

Aerosol science has a significant impact on a broad range of disciplines, extending from inhaled drug delivery, to combustion science and its health impacts, aerosol assisted routes to materials, climate change, and the delivery of agricultural and consumer products. Estimates of the global aerosol market size suggest it will reach $84 billion/year by 2024 with products in the personal care, household, automotive, food, paints and medical sectors. Air pollution leads to an estimated 30-40,000 premature deaths each year in the UK, and aerosols transmit human and animal infections. More than 12 million people in the UK live with lung disease such as asthma, and the NHS spends ~£5 billion/year on respiratory therapies. Many of the technological, societal and health challenges central to these areas rely on core skills and knowledge of aerosol science. Despite this, an Industrial Workshop and online survey (held in preparation for this bid) highlighted the current doctoral skills gap in aerosol science in the UK. Participating industries reported that only 15% of their employees working with aerosol science at doctoral-level having received any formal training. A CDT in aerosol science, CAS, will fill this skills gap, impacting on all areas of science where core training in aerosol science is crucial.

Impact on the UK aerosol community: Aerosol scientists work across governmental policy, industrial research and innovation, and in academia. Despite the considerable overlap in training needs for researchers working in these diverse sectors, current doctoral training in aerosol science is fragmentary and ad hoc (e.g. the annual Fundamentals of Aerosol Science course delivered by the Aerosol Society). In addition, training occurs within the context of individual disciplines, reinforcing artificial subject boundaries. CAS will bring coherence to training in the core physical and engineering science of aerosols, catalysing new synergies in research, and providing a focal point for training a multidisciplinary community of researchers. Working with the Aerosol Society, we will establish a legacy by providing training resources for future researchers through an online training portal.

Impact on industry and public-sector partners: 45 organisations have indicated they will act as CAS partners with interests in respiratory therapies, public health, materials manufacturing, consumer and agricultural products, instrumentation, emissions and environment. Establishing CAS will deliver researchers with the necessary skills to ensure the UK establishes and sustains a scientific and technical lead in their sectors. Further, it will provide an ideal mechanism for delivering Continuing Professional Development for the existing workforce practitioners. The activity of CAS is aligned to the Industrial Strategy Challenge Fund (e.g. through developing new healthcare technologies and new materials) and the EPSRC Prosperity Outcomes of a productive, healthy (e.g. novel treatments for respiratory disease) and resilient (e.g. adaptations to climate change, air quality) nation, with both the skilled researchers and their science naturally translating to long-lasting impact. Additionally, rigorous training in responsible innovation and ethical standards will lead to aerosol researchers able to contribute to developing: regulatory standards for medicines; policy on air quality and climate geoengineering; and regulations on manufactured nano-materials.

Public engagement: CAS will provide a focal point for engaging the public on topics in aerosol science that affect our daily lives (consumer products, materials) through to our health (inhalation therapeutics, disease transmission and impacts of pollution) and the future of our planet (geoengineering). Supported by a rigorous doctoral level training in aerosol science, this next generation of researchers will be ideally positioned to lead debates on all of these societal and technological challenges.