Log in
Our research has impacted on UK and international policy on peatland/wetland conservation and restoration for climate change mitigation and water purification, by showing how peatlands function as a major global carbon sink and regulator of climate and water quality. Additionally, our discovery that peatland carbon release, from local to global scales, is controlled by a single enzyme system has provided a tool to prevent carbon loss from degraded peat. Our new methods have been implemented in peatland restoration projects by UK agencies and NGOs, benefiting carbon storage, biodiversity and landscapes; raising public awareness and improving UK water industry management leading to better water quality.
The Scottish Government is aiming to generate all of its electricity through renewable energy sources by 2020. Research by the University of Aberdeen has produced a freely available tool - the Windfarm Carbon Calculator - that has overhauled the planning process for windfarm developments in Scotland. In changing public policy and planning regulations, and informing the public debate, Aberdeen's calculator is helping the Government fulfil its pledge to become "the green energy powerhouse of Europe" while protecting some of the country's most environmentally fragile areas. It continues to guide the actions of politicians, planners, the wind industry, NGOs and community groups.
The claimed impact therefore is on: the environment, economy and commerce, public policies and services, practitioners and services.
International and national political negotiations and public debates about climate change mitigation policies can only progress with accurate and timely updates about the global carbon budget. Annual carbon updates have been supplied over many years, as a result of our work. The "Global Carbon Project" (GCP) has become the definitive source on carbon budgets for political and policy processes dealing with climate change mitigation and the GCP draws heavily on the School's work on the ocean carbon cycle, including ocean iron fertilisation, and its relevance to the contemporary global carbon budget. This is evidenced by its citation and influence on national (e.g. UK, Germany, Australia, USA, Sweden and Canada) and international (e.g. UN Framework Convention on Climate Change) deliberations.
Results from climate physics research at the University of Oxford have demonstrated that targets for cumulative carbon emissions, rather than greenhouse gas concentrations, are a more effective approach to limiting future climate change. This new approach and the resulting `trillionth tonne' concept have had substantial political and economic implications. Impacts since 2009 include (a) stimulus to policy developments; (b) influence on the business decisions of Shell e.g. to invest in a $1.35bn carbon capture and storage facility; and (c) significant public and media debate with a global reach.
Dr Luiz Aragão in Geography at Exeter has, since 2008, led research focused on quantifying the impacts of environmental change on fire risk and carbon dynamics in Amazonian forests. This has had a number of impacts. First, research into drought frequency and intensity and fire occurrence has directly informed the design and implementation of environmental policy and regulation in relation to a `zero fire' policy by the State of Acre in Brazil. Second, the research has led to the development of new monitoring tools to assist policy makers in understanding the interactions between climate, ecosystems, and human health in Amazonia. Third, research into carbon emissions has influenced methodological development within the United Nations REDD (Reducing Emissions from Deforestation and Forest Degradation in Developing Countries) programme in Colombia. Finally, Dr Aragão's research has been widely disseminated in media outlets, thus increasing awareness of the general public and policy makers on drought and fire issues in Amazonia.
In the REF impact period, our research on carbon-rich tropical peat swamp forests in Indonesia has been used to:
Carbon dioxide sequestration is the process by which pressured CO2 is injected into a storage space within the Earth rather than released into the atmosphere. It is one of the major ways that carbon dioxide emissions can be controlled.
Research since 2004 by applied mathematicians at the University of Cambridge into the many different effects that might be encountered during this process has had considerable impact on government and industry groups in determining how the field is viewed and how it should and might be industrially developed. The work played a major role in the CO2CRC conferences and was subsequently reported to the Australian Government by the CO2CRC chair and organisers.
Impacts: I) Development of carbon credit certification schemes, including the expansion by the Gold Standard Foundation into land-use and forestry and the creation of the Natural Forest Standard by Ecometrica Ltd (both in 2012). II) Enhanced cross-sector collaboration for the quantification of forest-loss risks and implications for financing risks, through the 2011 creation of a Forest Finance Risk Network (FFRN).
Significance and reach: The Gold Standard Foundation represents nine forestry projects worldwide (benefiting >8,500 people) and over 1.8million ha. of Brazilian land is managed through two Natural Forest Standard projects. The FFRN connects 80 member organizations globally.
Underpinned by: Research into carbon emissions associated with forest-loss, undertaken at the University of Edinburgh (2005 onwards).
Since 2005 the Agriculture and Environment Research Unit has undertaken an extensive programme of research related to mitigating the climate change impacts arising from agricultural land management policies and practices. The research findings that identified the impact on climate change of various policies, schemes and farming initiatives have been instrumental since 2008 in providing UK policy makers, farmers and their advisors with data and tools that helped to formulate improved climate change mitigation policies. They also contributed to the development of key guidance materials that supported the implementation of these policies on the farm.
Research in the UoA developed a methodology for Carbon Calculations over the Life Cycle of Industrial Activities (CCaLC), providing `cradle to grave' carbon footprint estimates for commercial products. The methodology was embedded in a set of software tools designed to be used by non- experts, allowing companies to perform carbon footprinting in-house. The software is free to download, currently with 3300 users in more than 70 countries. The methodology and software tools have been endorsed by BERR (now BIS), DEFRA and the World Bank, and used widely by industry, across a range of sectors, to reduce carbon footprints of their products. This has resulted in significant environmental and socio-economic benefits, including estimated climate change mitigation gains in excess of £450m.