ALBERT

Description / Table of Contents: Electric and plug-in hybrid vehicles (EVs and PHEVs), if coupled with low greenhouse gas (GHG) electricity generation, can help cut energy (particularly petroleum) use and CO2 significantly, especially in the 2030-2050 timeframe – but key actions must begin now to achieve interim targets and thus substantial market shares in the long-term. The vision of this roadmap is to achieve widespread adoption and use of EVs and PHEVs worldwide by 2050, and if possible well before. The primary role of this EV/PHEV Roadmap is to help establish a vision for technology deployment; set approximate, feasible targets; and identify steps required to get there. It also outlines the role for different stakeholders and how they can work together to reach common objectives, and the role for government policy to support the process. The analysis in the roadmap is based on IEA’s ETP 2DS scenario, updated in the IEA report Transport, Energy and CO2: Moving Toward Sustainability (Autumn 2009). This scenario targets a 50% reduction in CO2 worldwide by 2050 relative to 2005 levels. For transport, a 30% reduction is achieved via efficiency improvements, along with the introduction of new types of vehicles and fuels. For EVs and PHEVs, sales begin to grow rapidly after 2015 and reach a combined 7 million per year by 2020, and 100 million by 2050, over half of all cars sold around the world in that year.

Description / Table of Contents: Meeting the enormous challenge of decarbonising world energy systems will require a rapid expansion of investment in clean technologies on a global scale. Mobilising these resources will be a daunting task, and it is important to undertake the transition at the lowest cost possible. This paper seeks to provide some guidance on climate change policy-making within real-world constraints, focusing on the justification of policies to supplement a carbon price, interactions between carbon pricing and supplementary policies, and management of these interactions to enable a least-cost policy response.

Description / Table of Contents: In 90 minutes, enough sunlight strikes the earth to provide the entire planet's energy needs for one year. While solar energy is abundant, it represents a tiny fraction of the world’s current energy mix. But this is changing rapidly and is being driven by global action to improve energy access and supply security, and to mitigate climate change. Around the world, countries and companies are investing in solar generation capacity on an unprecedented scale, and, as a consequence, costs continue to fall and technologies improve. This publication gives an authoritative view of these technologies and market trends, in both advanced and developing economies, while providing examples of the best and most advanced practices. It also provides a unique guide for policy makers, industry representatives and concerned stakeholders on how best to use, combine and successfully promote the major categories of solar energy: solar heating and cooling, photovoltaic and solar thermal electricity, as well as solar fuels. Finally, in analysing the likely evolution of electricity and energy-consuming sectors – buildings, industry and transport – it explores the leading role solar energy could play in the long-term future of our energy system.

Description / Table of Contents: The global energy system faces urgent challenges. Concerns about energy security are growing, as highlighted by the recent political turmoil in Northern Africa and the nuclear incident in Fukushima. At the same time, the need to respond to climate change is more critical than ever. Against this background, many governments have increased efforts to promote deployment of renewable energy – low-carbon sources that can strengthen energy security. This has stimulated unprecedented rise in deployment, and renewables are now the fastest growing sector of the energy mix. This “coming of age” of renewable energy also brings challenges. Growth is focused on a few of the available technologies, and rapid deployment is confined to a relatively small number of countries. In more advanced markets, managing support costs and system integration of large shares of renewable energy in a time of economic weakness and budget austerity has sparked vigorous political debate. The IEA’s new report, Deploying Renewables 2011: Best and Future Policy Practice: - Provides a comprehensive review and analysis of renewable energy policy and market trends; - Analyses in detail the dynamics of deployment and provides best-practice policy principles for different stages of market maturity; - Assesses the impact and cost-effectiveness of support policies using new methodological tools and indicators; - Investigates the strategic reasons underpinning the pursuit of RE deployment by different countries and the prospects for globalisation of RE. This new book builds on and extends a 2008 IEA publication, drawing on recent policy and deployment experience world-wide. It provides guidance for policy makers and other stakeholders to avoid past mistakes, overcome new challenges and reap the benefits of deploying renewables – today and tomorrow.

Description / Table of Contents: G-20 Clean Energy, and Energy Efficiency Deployment and Policy Progress, a report prepared by the International Energy Agency (IEA) in collaboration with the G-20 Clean Energy and Energy Efficiency Working Group, provides an overview of clean energy and energy efficiency technology deployment and summarises support policies in place across G-20 countries. The report highlights that while clean energy technology deployment has made steady progress and energy efficiency improvements have been made, continued reliance on fossil fuels to meet growth in global energy demand presents a significant challenge. Scaling-up the deployment of renewable energy, in addition to improving end-use efficiency, enhancing the efficiency of fossil fuel based power generation, and supporting the widespread deployment of CCS will, therefore, also be crucial aspects of the transition to a cleaner energy future. Reporting to G-20 on Clean Energy and Efficiency Progress. This report was issued on the authority of the IEA Executive Director, it does not necessarily represent the views of IEA Member countries or the G20. G-20 Clean Energy, and Energy Efficiency Deployment and Policy Progress, a report prepared by the International Energy Agency (IEA) in collaboration with the G-20 Clean Energy and Energy Efficiency Working Group, provides an overview of clean energy and energy efficiency technology deployment and summarises support policies in place across G-20 countries. The report highlights that while clean energy technology deployment has made steady progress and energy efficiency improvements have been made, continued reliance on fossil fuels to meet growth in global energy demand presents a significant challenge. Scaling-up the deployment of renewable energy, in addition to improving end-use efficiency, enhancing the efficiency of fossil fuel based power generation, and supporting the widespread deployment of CCS will, therefore, also be crucial aspects of the transition to a cleaner energy future. Because the G-20 group of countries represent close to 80% of energy-related CO₂emissions, by developing and deploying energy efficiency and clean energy technologies, they are presented with a unique opportunity to make collective progress in transitioning the global energy system. IEA Deputy Executive Director Richard Jones emphasised the importance of G-20 efforts, saying, "The IEA welcomes this important collaboration with the G-20. Enhanced deployment of clean energy technologies and of energy efficiency improvements offers energy security and environmental benefits. It will also enable cost savings over the medium and long term – an aspect that is particularly relevant at a time of economic uncertainty. We believe that enhanced policy assessment and analysis, building on this initial report, will enable governments to take more cost effective and efficient policy decisions.”

Description / Table of Contents: Buildings account for almost a third of final energy consumption globally and are an equally important source of CO2 emissions. Currently, both space heating and cooling, as well as hot water are estimated to account for roughly half of global energy consumption in buildings. Energy-efficient and low/zero-carbon heating and cooling technologies for buildings have the potential to reduce CO2 emissions by up to 2 gigatonnes (Gt) and save 710 million tonnes oil equivalent (Mtoe) of energy by 2050. Most of these technologies – which include solar thermal, combined heat and power (CHP), heat pumps and thermal energy storage – are commercially available today. The Energy-Efficient Buildings: Heating and Cooling Equipment Roadmap sets out a detailed pathway for the evolution and deployment of the key underlying technologies. It finds that urgent action is required if the building stock of the future is to consume less energy and result in lower CO2 emissions. The roadmap concludes with a set of near-term actions that stakeholders will need to take to achieve the roadmap’s vision. Buildings account for almost a third of final energy consumption globally and are an equally important source of CO2 emissions. Currently, both space heating and cooling as well as hot water are estimated to account for roughly half of global energy consumption in buildings. Energy-efficient and low/zero-carbon heating and cooling technologies for buildings have the potential to reduce CO2 emissions by up to 2 gigatonnes (Gt) and save 710 million tonnes oil equivalent (Mtoe) of energy by 2050. Most of these technologies – which include solar thermal, combined heat and power (CHP), heat pumps and thermal energy storage – are commercially available today.

Description / Table of Contents: The production of transport fuels from biomass, in either liquid or gaseous form, holds the promise of a low net fossil-energy requirement and low life-cycle greenhouse gas (GHG) emissions. However, there are many hurdles to the expansion of biofuels production, including competition for agricultural commodities and land, and impacts on water resources and biodiversity. The successful development of advanced biofuels technologies, using non-food biomass feedstocks, could help overcome most barriers and achieve sustainable, very low CO2, cost-effective biofuels. The IEA “Biofuels for Transport” roadmap describes the steps necessary to achieve the ambitious biofuel projections presented in the Energy Technology Perspectives 2010 Blue Map scenario. Under this scenario, biofuel demand increases rapidly, reaching approximately 760 Mtoe (32 EJ) in 2050, a share of 27% of total transport fuel. This roadmap identifies major barriers, opportunities, and policy measures for policy makers, industry and financial partners to accelerate RDD&D efforts for sustainable biofuel technologies and ensure sustainable feedstock provision on both a national and international scale.

Description / Table of Contents: This report delves into the major factors or driving forces that decision makers within a large industrial company take into account when deciding to make new investments - the so-called "boardroom perspective". The rationale for an individual company making an investment that will reduce energy consumption varies considerably and depends on a range of factors. This report delves into the major factors or driving forces that decision makers within a large industrial company take into account when deciding to make new investments - the so-called "boardroom perspective". It explores the factors that influence companies to invest in energy savings and proposes a methodology to evaluate the effectiveness of a countrys energy efficiency and greenhouse gas mitigation policies mix from this boardroom perspective. This paper is the product of collaboration between the IEA and the Institute of Industrial Productivity (IIP).

Description / Table of Contents: This report focuses mainly on developments to improve the performance of coal-based power generation technologies, which should be a priority – particularly if carbon capture and storage takes longer to become established than currently projected. A close look is taken of the major ongoing developments in process technology, plant equipment, instrumentation and control. Coal is an important source of energy for the world, particularly for power generation. To meet the growth in demand for energy over the past decade, the contribution from coal has exceeded that of any other energy source. Additionally, coal has contributed almost half of total growth in electricity over the past decade. As a result, CO2 emissions from coal-fired power generation have increased markedly and continue to rise. More than 70% of CO2 emissions that arise from power generation are attributed to coal. To play its role in a sustainable energy future, its environmental footprint must be reduced; using coal more efficiently is an important first step. Beyond efficiency improvement, carbon capture and storage (CCS) must be deployed to make deep cuts in CO2 emissions. This report focuses mainly on developments to improve the performance of coal-based power generation technologies, which should be a priority – particularly if carbon capture and storage takes longer to become established than currently projected. A close look is taken of the major ongoing developments in process technology, plant equipment, instrumentation and control. The need for energy and the economics of producing and supplying it to the end-user are central considerations in power plant construction and operation. Economic and regulatory conditions must be made consistent with the ambition to achieve higher efficiencies and lower emissions. In essence, clean coal technologies must be more widely deployed.

Description / Table of Contents: Nearly one-third of global energy and one-quarter of worldwide carbon dioxide (CO2) emissions are attributable to industrial activities that are not in the power generation sector. If climate change is to be successfully tackled, these sectors will need to transform the way they use energy and significantly reduce their CO2 emissions. In sectors such as iron and steel, oil refining, cement and chemicals and petrochemicals, emission can be reduced through efficiency improvements and integration of low carbon energy sources. Crucially, however, carbon capture and storage (CCS) has been identified as the only large-scale mitigation option available that can deliver the additional CO2 emissions reductions that would be necessary to meet the climate goals in 2050. This roadmap shows that CCS is a key cost-effective option for reducing CO2 emissions in large energy-intensive industries. In fact, much of the promising short-term potential for CCS globally lies not in the power sector but in industrial activities that currently vent highly pure streams of CO2. These activities include hydrogen production for fertilisers or fuel, bioethanol production and natural gas sweetening. Most studies on the potential application of CCS have focused on the power sector, however, even though all existing operational large-scale demonstrations of CCS are in industrial applications. In the longer-term, half of the global economic deployment for CCS by 2050 is shown to be in industrial applications. In certain sectors CCS is shown to be of particular relevance in developing countries, where it could be a highly cost-competitive emissions abatement option, even in the near term. This technology roadmap builds on the initial IEA roadmap on CCS and also the technology roadmap for the cement sector developed by the IEA and the Cement Sustainability Initiative of the World Business Council for Sustainable Development. It paves the way for low-carbon industrial growth in developed and developing countries by providing a vision of CCS in industrial applications up to 2050.