Reducing carbon emissions and securing energy supplies are crucial international goals to which energy demand reduction must make a major contribution. On a national level, demand reduction, deployment of new and renewable energy technologies, and decarbonisation of the energy supply are essential if the UK is to meet its legally binding carbon reduction targets. As a result, this area is an important theme within the EPSRC's strategic plan, but one that suffers from historical underinvestment and a serious shortage of appropriately skilled researchers. Major energy demand reductions are required within the working lifetime of Doctoral Training Centre (DTC) graduates, i.e. by 2050. Students will thus have to be capable of identifying and undertaking research that will have an impact within their 35 year post-doctoral career. The challenges will be exacerbated as our population ages, as climate change advances and as fuel prices rise: successful demand reduction requires both detailed technical knowledge and multi-disciplinary skills. The DTC will therefore span the interfaces between traditional disciplines to develop a training programme that teaches the context and process-bound problems of technology deployment, along with the communication and leadership skills needed to initiate real change within the tight time scale required. It will be jointly operated by University College London (UCL) and Loughborough University (LU); two world-class centres of energy research. Through the cross-faculty Energy Institute at UCL and Sustainability Research School at LU, over 80 academics have been identified who are able and willing to supervise DTC students. These experts span the full range of necessary disciplines from science and engineering to ergonomics and design, psychology and sociology through to economics and politics. The reputation of the universities will enable them to attract the very best students to this research area.The DTC will begin with a 1 year joint MRes programme followed by a 3 year PhD programme including a placement abroad and the opportunity for each DTC student to employ an undergraduate intern to assist them. Students will be trained in communication methods and alternative forms of public engagement. They will thus understand the energy challenges faced by the UK, appreciate the international energy landscape, develop people-management and communication skills, and so acquire the competence to make a tangible impact. An annual colloquium will be the focal point of the DTC year acting as a show-case and major mechanism for connection to the wider stakeholder community.The DTC will be led by internationally eminent academics (Prof Robert Lowe, Director, and Prof Kevin J Lomas, Deputy Director), together they have over 50 years of experience in this sector. They will be supported by a management structure headed by an Advisory Board chaired by Pascal Terrien, Director of the European Centre and Laboratories for Energy Efficiency Research and responsible for the Demand Reduction programme of the UK Energy Technology Institute. This will help secure the international, industrial and UK research linkages of the DTC.Students will receive a stipend that is competitive with other DTCs in the energy arena and, for work in certain areas, further enhancement from industrial sponsors. They will have a personal annual research allowance, an excellent research environment and access to resources. Both Universities are committed to energy research at the highest level, and each has invested over 3.2M in academic appointments, infrastructure development and other support, specifically to the energy demand reduction area. Each university will match the EPSRC funded studentships one-for-one, with funding from other sources. This DTC will therefore train at least 100 students over its 8 year life.

As a result of global climate change, the UK is expected to experience hotter and drier summers and heatwaves are expected to occur with greater frequency, intensity and duration. According to recent climate change projections by the MetOffice, increases in mean daily temperatures could be up to 5.4 deg. C during the summer months and 4.2 deg. C during winter by 2070 under a High emissions scenario. In 2003, 2,091 heat-related deaths were reported in the UK alone as a result of the European heatwave, meaning future temperature increases could lead to a parallel rise in heat-related mortality. The UK also currently has a rapidly growing number of old people, with people aged 75 or over expected to account for 13% of the total population by 2035, compared with 8% in 2012. Older populations are more vulnerable to climate-induced effects as they are more likely to have underlying, chronic health complications, making them more vulnerable to heat stress. The 2003 heatwave demonstrated that older people in care settings are at the highest risk of heat-related mortality. People aged over 65 years spend more than 80% of their time in residential environments or care settings, and people aged over 85 years more than 90%. Therefore, the indoor environment is a huge moderator of heat exposure in older populations: Poor building design and the lack of effective heat management in care settings may contribute to increased indoor heat exposure with detrimental health impacts falling on the most vulnerable residents. Care facilities function as both a home for residents and a workplace for staff, meaning that the people sharing those spaces can have diverging needs and preferences making overheating prevention measures difficult to enforce. Interactions between staff and residents play an important role in preventing overheating in care settings and it has previously been noted that staff are often made to prioritise warmth due to wide recognition of the detrimental effect cold weather can have on old-age health, leading to overheating risks being overlooked. Understanding factors that contribute to indoor summertime overheating in care homes is crucial in developing methods to prevent overheating and the subsequent negative health impacts. Previous research by the applicants has indicated that care facilities are already overheating even under non-extreme summers, highlighting the need to develop timely prevention measures given the way temperatures are expected to rise in the UK over the next century. A key target for climate adaptation in care settings is to limit such risks by introducing passive cooling strategies via building design and occupant behaviour. Development of passive cooling strategies will reduce the likelihood of uptake of mechanical cooling, which would undermine government efforts to reduce greenhouse gas emissions. Therefore, the principal aim of the project is to undertake preliminary work to develop methods that will support a system of care provision in the UK that is adequately prepared for rising heat stress under climate change. The project will undertake pilot work in five care settings in the UK to monitor the thermal environment and conduct surveys with residents, frontline care staff and care home managers. Within these buildings, it will test novel approaches for understanding the comfort levels of the residents and relating this to the thermal environment. It will also test novel measurement techniques for assessing impact of heat on the health of the residents. Via detailed modelling work, it will then test methods to assess future overheating risks and to evaluate the effectiveness of overheating mitigation strategies. Throughout the project the work will bring together multidisciplinary research perspectives with those of care home practitioners and other stakeholders. Via these packages of work, plans for the large-scale project that is so urgently needed in this area will be developed.

Air conditioning (AC) is one of the major energy systems applied globally with a market size of around £80 billion per annum. Current AC technologies require large amounts of electrical or thermal energy, accounting for 20% global electricity consumption and resulting in 1,100 mega-tons of carbon emission. The project aims to establish a scientific foundation for a pioneering, near-zero-carbon and all-climate-adaptive AC system. Compared to existing AC technologies (i.e. mechanical vapour compression, absorption, and adsorption types), the new AC system leads to over 80%-90% energy bills saving, and near-zero carbon emission. Unlike existing evaporative cooling AC systems which only suit arid climates, the new AC will be all-climate-adaptive. Novelties of the research lie in: (1) The best performing sorption, diffusion, air-tight and light-absorptive materials will be identified and/or refined; (2) A unique sorption/desorption bed comprising an air-flow-interactive sorption layer and a light-absorptive desorption layer will be developed; (3) A bespoke natural light harvesting configuration to deliver a controlled light radiation into the desorption layer surface; (4) The latest Fractal theory in the first attempt to a multi-medium/sized porous block instead of the traditional single medium/sized porous block; (5) A unique multiple-scale light simulation model, which integrate a non-sequential ray tracing method for simulating the macro-scale light and a finite-difference time-domain method for simulating the light-moisture interaction on the porous desorption surface; (6) A novel 'life-cycle-cooling-cost' oriented optimisation method. The project research programme includes: (1) Screening, refinement, characterisation and selection of the sorption/desorption materials, and determination of the composition/combination methods of the selected materials; (2) Establishment of the theoretical foundation for the light collection/transmission/distribution and light-moisture interaction and conduction of associated computer simulation modelling; (3) Establishment of the theoretical foundation and computer models for moisture adsorption, permeation, diffusion and vaporisation within the porous 'moisture-breathing' bed, and optimisation of the structure of the 'moisture-breathing' bed; (4) Optimisation of the integrated operation between the light-driven 'moisture-breathing' bed and dew point air cooler using the 'life-cycle-cooling-cost' oriented method; and investigation of the AC's building integration approach; and (5) Construction/testing of the AC prototype (including microbial hazard control) and validation/refinement of the integrated AC computer model. The proposed research will be carried out by a cross-university and multi-disciplinary team comprising Prof. Xudong Zhao of UHULL who is the world-class academic specialised in heating, cooling, renewable energy and energy efficiency, Prof. Semali Perera of Bath who is a leading scientist specialised in porous sorption/desorption materials, Prof. Barry Crittenden who is a Fellow of Royal Academy of Engineering specialising in adsorption and membranes, Dr Carmelo Herdes who is specialized in molecular simulations, experiments and characterization of sorption/desorption materials and molecular transport with industrial relevance, Prof. Brad Gilbon of UHULL who is an internationally recognised optical scientist, Prof. Jeanette Rotchell of UHULL who is a leading scientist specialised in environmental biology, Dr. Xiaoli Ma of UHULL who has expertise in renewable energy and dew point cooling, and Dr. Zishang Zhu of UHULL who is specialised in integrating renewable energy system into buildings. The project team will be supported by FIVE UK industrial/governmental organisations.

The UK is committed to a target of reducing greenhouse gas emissions by 80% before 2050. With over 40% of fossil fuels used for low temperature heating and 16% of electricity used for cooling these are key areas that must be addressed. The vision of our interdisciplinary centre is to develop a portfolio of technologies that will deliver heat and cold cost-effectively and with such high efficiency as to enable the target to be met, and to create well planned and robust Business, Infrastructure and Technology Roadmaps to implementation. Features of our approach to meeting the challenge are: a) Integration of economic, behavioural, policy and capability/skills factors together with the science/technology research to produce solutions that are technically excellent, compatible with and appealing to business, end-users, manufacturers and installers. b) Managing our research efforts in Delivery Temperature Work Packages (DTWPs) (freezing/cooling, space heating, process heat) so that exemplar study solutions will be applicable in more than one sector (e.g. Commercial/Residential, Commercial/Industrial). c) The sub-tasks (projects) of the DTWPs will be assigned to distinct phases: 1st Wave technologies or products will become operational in a 5-10 year timescale, 2nd Wave ideas and concepts for application in the longer term and an important part of the 2050 energy landscape. 1st Wave projects will lead to a demonstration or field trial with an end user and 2nd Wave projects will lead to a proof-of-concept (PoC) assessment. d) Being market and emission-target driven, research will focus on needs and high volume markets that offer large emission reduction potential to maximise impact. Phase 1 (near term) activities must promise high impact in terms of CO2 emissions reduction and technologies that have short turnaround times/high rates of churn will be prioritised. e) A major dissemination network that engages with core industry stakeholders, end users, contractors and SMEs in regular workshops and also works towards a Skills Capability Development Programme to identify the new skills needed by the installers and operators of the future. The SIRACH (Sustainable Innovation in Refrigeration Air Conditioning and Heating) Network will operate at national and international levels to maximise impact and findings will be included in teaching material aimed at the development of tomorrow's engineering professionals. f) To allow the balance and timing of projects to evolve as results are delivered/analysed and to maximise overall value for money and impact of the centre only 50% of requested resources are earmarked in advance. g) Each DTWP will generally involve the complete multidisciplinary team in screening different solutions, then pursuing one or two chosen options to realisation and test. Our consortium brings together four partners: Warwick, Loughborough, Ulster and London South Bank Universities with proven track records in electric and gas heat pumps, refrigeration technology, heat storage as well as policy / regulation, end-user behaviour and business modelling. Industrial, commercial, NGO and regulatory resources and advice will come from major stakeholders such as DECC, Energy Technologies Institute, National Grid, British Gas, Asda, Co-operative Group, Hewlett Packard, Institute of Refrigeration, Northern Ireland Housing Executive. An Advisory Board with representatives from Industry, Government, Commerce, and Energy Providers as well as international representation from centres of excellence in Germany, Italy and Australia will provide guidance. Collaboration (staff/student exchange, sharing of results etc.) with government-funded thermal energy centres in Germany (at Fraunhofer ISE), Italy (PoliMi, Milan) and Australia (CSIRO) clearly demonstrate the international relevance and importance of the topic and will enhance the effectiveness of the international effort to combat climate change.

It is well known that climate change will have a significant impact on UK building design and energy use. It is also known within the building science and architectural communities that the current weather files used for thermal modeling of buildings only represent average weather rather than heat waves or cold snaps. As was shown by the 14,000 deaths in Paris during the 2003 heat wave, this is a highly serious issue and there is the need to ensure future buildings are designed to deal with future weather, or extremes of current weather. In addition, the current weather files used by the construction industry and building scientists divide the UK into only 14 regions, with, for example, the whole of the South West peninsular (including up-land areas) being assigned the coastal Plymouth weather file. It is known that this can easily lead to a 200% error in the estimation of annual energy demand. The scale of this error is such that it renders many of the dynamic simulations carried out by engineers questionable. This is unfortunate when simulation is used within the framework of the building regulations, but it is fatal when trying to use simulation to estimate how resilient a pre-existing building is, or the danger its vulnerable occupants might be in. The aim of this project will be to see if a method can be devised that is capable of creating local weather from 2015 to 2080 covering the whole UK at a resolution of 5km, and to include within this files that represent various excursions from the mean: e.g. heat waves and cold snaps. An interdisciplinary approach is envisaged with the project separated into six work packages: WP1 We will use a method already published by the team together with the UKCP09 weather generator to produce current and future typical weather at a resolution of approximately 5km. WP2 The work in the previous work package will initially require the creation of thousands of years of weather per site. Within these initial years will reside a large number of weather events of interest to the building scientist or engineer. These files will be used in computer models of 1200 differing architectures and building uses to identify what are the key drivers of weather variable coincidence that defines the likelihood of building system failure or thermal issues for occupants. WP3 Having characterised which events best describe the stresses on a building, its occupants and systems in WP2. Event years (i.e. times series of weather data variables on a one hour time step that represent atypical hot, dry, cold and wet periods) will be created for the whole UK. WP4 Having generated the event years, and simulations from the 1200 buildings, the two will be recombined to produce the first map of UK resilience to a changing climate. Although others have looked at the regional resilience of the built environment using average weather years, the concern is not about the response of building and occupants to such average time series, but to more extreme events. WP5 Given the large number of files proposed, guidance will need to be given on which to use in practice, and how this might be expressed in the building regulations and other documentation. We plan to use case studies as the main guidance tool. This will add greatly to their intellectual validity within the target audience of practicing engineers. In total, we expect the guidance to be tested on >100 real building projects. WP6 Impact. All weather files produced by the project will be publicly available for a minimum of 10 years. A series of road shows will be undertaken at the end of the project. At these events the results of the project will be presented to a large number of users. The idea will be to introduce the whole UK built environment community to the idea of designing resilient buildings aided by the weather data produced by the project. A short film will also be produced for those that cannot attend and for an international audience.