The UK Government the EU and the international community in general have ambitious targets for reduction of Greenhouse Gas Emissions (GHG) and Global Warming. Even though emission reduction targets to 2020 are likely to be met by the UK, longer term targets to 2050 and 2100 are unlikely to be met without substantial changes to policy and technological approaches in the generation, distribution and utilisation of energy. Globally, industrial energy use is responsible for 33% of greenhouse gas emissions. In the UK, industrial emissions have reduced in recent years and are now estimated to contribute between 20-25% of total emissions. Approximately 70% of the energy demand of the industrial sector is for heat. All heating processes result in significant quantities of waste heat, up to 50% in some cases, and is widely acknowledged that there is significant potential for heat recovery, estimated at between 18-40 TWh/yr or £0.18-0.4 billion per year at today's energy prices. As yet, most of this potential has remained unexploited due to technical, economic and organisational factors. Other opportunities for energy efficiency and decarbonisation include the optimisation of steam systems that are responsible for 35% of industrial energy use, the use of bioenergy, particularly from organic and other wastes generated on site, and whole industrial site energy integration and optimisation. To exploit the potential offered by energy efficiency, heat recovery and conversion to electrical or thermal energy at a higher or lower temperature and utilise the opportunities offered by waste to energy conversion and energy integration a number of major challenges need to be addressed. These include: i) development and application of technologies for data acquisition at high enough granularity to enable detailed analysis of performance at component, process and system level, ii) methodologies for the optimal design of technologies to provide confidence in their performance at implementation stage, iii) tools for performance analysis and control optimisation in real time, iv) modelling of energy flows at site level to provide optimisation of energy management based on energy, environmental and economic considerations, and iv) investigation and development of business models that overcome barriers and encourage the adoption of new energy efficient and demand reduction technologies. In the OPTEMIN project we aim to address these challenges by working very closely with our key industrial collaborators to: i) understand the major technical, operational and economic issues associated with the acquisition and analysis of large energy data, ii) use the data to gain insights into the complex energy networks, their interactions and impacts in large industrial manufacturing facilities, iii) critically evaluate the performance of new innovative energy demand reduction and energy conversion technologies using data from demonstration installations, iv) investigate drivers and business models that can facilitate their full development and commercialisation, v) develop methodologies and tools to optimise individual process design, whole site energy integration and management and evaluate their decarbonisation potential within the context of Government policies and decarbonisation roadmaps to 2050. The overall objective is to demonstrate through the research programme and fully documented case studies supported by comprehensive data sets, the potential to achieve energy demand and carbon emission reductions in excess of 15%.

Tackling climate change, providing energy security and delivering sustainable energy solutions are major challenges faced by civil society. The social, environmental and economic cost of these challenges means that it is vital that there is a research focus on improving the conversion and use of thermal energy. A great deal of research and development is continuing to take place to reduce energy consumption and deliver cost-effective solutions aimed at helping the UK achieve its target of reducing greenhouse gas emissions by 80 per cent by 2050. Improved thermal energy performance impacts on industry through reduced energy costs, reduced emissions, and enhanced energy security. Improving efficiency and reducing emissions is necessary to increase productivity, support growth in the economy and maintain a globally competitive manufacturing sector. In the UK, residential and commercial buildings are responsible for approximately 40% of the UK's total non-transport energy use, with space heating and hot water accounting for almost 80% of residential and 60% of commercial energy use. Thermal energy demand has continued to increase over the past 40 years, even though home thermal energy efficiency has been improving. Improved thermal energy conversion and utilisation results in reduced emissions, reduced costs for industrial and domestic consumers and supports a more stable energy security position. In the UK, thermal energy (heating and cooling) is the largest use of energy in our society and cooling demand set to increase as a result of climate change. The need to address the thermal energy challenge at a multi-disciplinary level is essential and consequently this newly established network will support the technical, social, economic and environmental challenges, and the potential solutions. It is crucial to take account of the current and future economic, social, environmental and legislative barriers and incentives associated with thermal energy. The Thermal Energy Challenge Network will support synergistic approaches which offer opportunities for improved sustainable use of thermal energy which has previously been largely neglected. This approach can result in substantial energy demand reductions but collaboration and networking is essential if this is to be achieved. A combination of technological solutions working in a multi-disciplinary manner with engineers, physical scientists, and social scientists is essential and this will be encouraged and supported by the Thermal Energy Challenge Network.

Tackling climate change, providing energy security and delivering sustainable energy solutions are major challenges faced by civil society. The social, environmental and economic cost of these challenges means that it is vital that there is a research focus on improving the conversion and use of thermal energy. A great deal of research and development is continuing to take place to reduce energy consumption and deliver cost-effective solutions aimed at helping the UK achieve its target of reducing greenhouse gas emissions by 80 per cent by 2050. Improved thermal energy performance impacts on industry through reduced energy costs, reduced emissions, and enhanced energy security. Improving efficiency and reducing emissions is necessary to increase productivity, support growth in the economy and maintain a globally competitive manufacturing sector. In the UK, residential and commercial buildings are responsible for approximately 40% of the UK's total non-transport energy use, with space heating and hot water accounting for almost 80% of residential and 60% of commercial energy use. Thermal energy demand has continued to increase over the past 40 years, even though home thermal energy efficiency has been improving. Improved thermal energy conversion and utilisation results in reduced emissions, reduced costs for industrial and domestic consumers and supports a more stable energy security position. In the UK, thermal energy (heating and cooling) is the largest use of energy in our society and cooling demand set to increase as a result of climate change. The need to address the thermal energy challenge at a multi-disciplinary level is essential and consequently this newly established network will support the technical, social, economic and environmental challenges, and the potential solutions. It is crucial to take account of the current and future economic, social, environmental and legislative barriers and incentives associated with thermal energy. The Thermal Energy Challenge Network will support synergistic approaches which offer opportunities for improved sustainable use of thermal energy which has previously been largely neglected. This approach can result in substantial energy demand reductions but collaboration and networking is essential if this is to be achieved. A combination of technological solutions working in a multi-disciplinary manner with engineers, physical scientists, and social scientists is essential and this will be encouraged and supported by the Thermal Energy Challenge Network.

There are significant concerns about the UK's ability to meet national and international climate change targets and long term security of supply. There exists many opportunities to improve the efficient use of thermal energy in existing buildings/plants and modes of transport and to give greater consideration to thermal energy management in future designs. Industrial consumption accounted for 18% of total UK final energy consumption in 2011. Within this industrial sector, heat use (space heating, drying/separation, high/low temperature processing) accounts for over 70% of total UK industrial energy use. The market potential for waste heat is estimated to be between 10TWh - 40TWh per annum. Recent developments in energy processing and the need for CO2 reduction have led to a growing interest in using this heat. SMEs account for 45% of industrial energy use but their processes and plants are often less efficient, largely due to the financial cost of optimisation . It is therefore important to ensure support and focus is given to SMEs, particularly addressing the barriers to effective thermal use applicable to this part of the economy. Commercial and residential buildings are responsible for approximately 40% of the UK's total non-transport energy use, with space heating and hot water accounting for almost 80% of residential and 60% of commercial energy use between sectors. Marine and rail transport contribute over 14 million tonnes of CO2 equivalent to UK annual greenhouse gas (GHG) emissions and similar opportunities to those in the industrial and building sectors to reduce thermal energy demand exist. The adoption of increasingly stringent emissions legislation and increasing fuel costs have made it even more important that the thermal energy in the power and propulsion is optimised, for example through greater energy recovery and storage. The SusTEM Network will build upon the success of the PRO-TEM Network and expanding its remit. This will include the engagement of researchers with social and economic expertise and widening the network through further engagement with industry, particularly SMEs, academia and government and policy makers (local and national) who have not previously participated in the PRO-TEM Network. SusTEM Network will have the following key objectives: 1. Provide a forum to incorporate stakeholder opinions in the area of thermal energy management for the industrial, building, and transport sectors. 2. Engage with multi-disciplinary researchers within the research community at UK HE institutions, including End Use Energy Demand Centres, to maximise dissemination, impact, reach and significance of research outcomes. 3. Stimulate knowledge transfer between academia, industry, government and other stakeholders. 4. Identify and promote future research requirements based on partner contributions, road-mapping and links to Knowledge Transfer Networks (KTN), European Technology Platforms (ETP) and other relevant networks and initiatives. 5. Foster long-term collaboration between outstanding research teams in the UK and China and to ensure there is a two way transfer of knowledge.