Drivers of Innovation in Energy and Fuel Cell Technology: Supply-Demand and R&D. Madeline Woodruff IEA and Yukiko Fukasaku OECD

Drivers of Innovation in Energy and Fuel Cell Technology: Supply-Demand and R&D Madeline Woodruff IEA and Yukiko Fukasaku OECD 1

Overview Drivers of energy technology innovation Sustained increase in demand Diversification of sources of fossil fuel supply due to growing security and economic concerns Fuel switching and development of new fuels due to efficiency and environmental concerns De-regulation and increasing competition Increasing importance of R&D and technological innovation How the energy innovation system works Focus on fuel cells 2

Part I Supply, Demand, and Investment Trends Role of Fuel Cells in the Energy System 3

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Today s Energy Challenges Energy security to fuel economic growth and mobility and curbing environmental and climate damage from energy use business as usual energy demand is rising inexorably greenhouse gas emissions also stronger policies stabilize OECD emissions only after 2020. Access to modern energy for all 1.6 billion people have no access to electricity, 80% of them in South Asia and sub-saharan Africa Lower costs in deregulated markets; infrastructure stresses Million Tonnes CO2 6,000 5,000 4,000 3,000 2,000 1,000 Reference Word Primary Energy Demand WEO 2002 0 1970 1980 1990 2000 2010 2020 2030 45000 40000 35000 30000 25000 20000 15000 10000 5000 0 Reference Energy-Related CO2 Emissions WEO 2002 1971 1990 2000 2010 2020 2030 5 Oil Gas Coal Nuclear Hydro Other renewables World OECD Transition Economies Developing Countries

Renewables Growing Fast, but From a Low Base Growth of Renewables Supply from 1971 to 2000 12% 10% 32.6% 52.1% 9.4% annual growth rate 8% 6% 4% 2% 8.8% 8.4% Geothermal Solar Wind Tide, other 2.7% 2.1% 2.1% 1.8% 0% TPES Renewables CRW Hydro Other TPES: total primary energy supply CRW: combustible renewables and waste Source: International Energy Agency 6

Meeting the Challenges: What Does it Take? Faster progress in energy technology development is an essential element: more cost-effective solutions capitalize on capital stock turnover as it occurs costs depend on not only development and investment costs but also the extent to which capital stock is retired early How? more resources for technology R&D and demonstration and underlying sciences; identify and fill gaps (as usual) fostering of public/private partnerships, and of international collaboration, especially for large demonstrations (as usual) support and facilitation of technology uptake (as usual, but connection to R&D and technology learning sometimes missed) other efforts to foster and facilitate innovation more specific policy advice to governments 7

What Can Hydrogen Offer? A number of IEA member countries have made commitments to accelerate the development of the hydrogen energy economy: Energy security: reduced dependence on imported fuels (depending on the source) Environmental Security Energy Security H2? Economic Security Climate change: potentially nearemissions-free vehicles and distributed generation (carbon sequestration required if fossilbased; lower-cost production essential) Investment: some heavy demands promising enormous dividends Two main strategies for dealing with climate change: Europe: renewables, energy efficiency North America: carbon capture and storage Both pursuing hydrogen from fossil fuels, nuclear energy, renewable energy 8

Roles for Fuel Cells Stationary, Distributed Generation Local and system benefits, including storage to back up intermittent renewables TODAY: niche markets -- telecommunications, back-up power systems TOMORROW: Natural gas fuel cells: significant contribution to energy supply expected after 2020 -- primarily stationary applications (WEO 2002) Competitive fuel cells (distributed generation): expected when -- capital costs fall below $ 1,000 /kwe (~75% reduction) -- efficiencies approach 60% (>50% increase) N atural gas reforming first -- coal, biomass, water electrolysis not expected to be economically feasible before 2030 Fuel cell/gas turbine combined cycle -- over 70% efficiency? 9

Roles for Fuel Cells Vehicles: transport is responsible for over half of world oil demand fuel cells in vehicles expected to become attractive only around 2020 (WEO 2002) by 2030, only a small share of the vehicle fleet; even under alternative (stronger) policies, less than 5% of the OECD fleet difficult to supply substantial quantities of hydrogen for vehicles before 2050 unless carbon sequestration is applied on a large scale -- only fossil fuels could achieve this at reasonable cost any increase in renewable or nuclear electricity before 2050 would probably best be used to reduce emissions in the power sector 10

Investments in Developing a Hydrogen Economy Iceland, Singapore, others: committed to introducing hydrogen and fuel cell products in the electric utility and transport sectors European Union: recently announced a long- term, 2 billion euro R&D program in hydrogen energy, ren. energy technologies United States: recently announced a five-year, $ 1.2 billion hydrogen energy technology and infrastructure program. Japan: fuel cell and hydrogen technology research program has tripled since 1995, reaching over $ 200 million in 2002 Others: e.g., Italy, Canada, United Kingdom have accelerated and expanded their investments. China: has an organized program intended to lead to development of fuel cell vehicles Private sector: investments in hydrogen energy technology, fuel cells have grown dramatically over the past decade (in developed and developing countries) Several developing countries: financing for demonstrations of hydrogen fueling stations, fuel cellpowered buses 11

Part II Innovation in energy and fuel cell 12

How can innovation influence energy supply and demand? More efficient use of primary energy sources (e.g., combined cycle power generation) Increased efficiency in end-use (e.g., electric appliances, lower-consumption cars) Harnessing emerging sources of energy (e.g., solar, wind, biomass) Developing technologies that address efficiency and environmental concerns (e.g., fuel cells, advanced turbines, advanced exploration and extraction) Putting in place infrastructure that can deliver new energy services (e.g, hydrogen) 13

How can innovation in energy technology be stimulated? Assuring well-functioning markets Assuring well-functioning innovation system Innovation takes place in a system of inter-linked actors, In both public and private sectors. Depends on government policies to: Fund R&D and demonstration including through public-private partnerships, Supply highly qualified S&T human resources and ensure mobility, Put in place appropriate framework conditions including regulations, competition policy and intellectual property protection, Stimulate use of emerging organisational innovations, e.g., industrial clusters and venture capital 14

What are the characteristics of energy technology innovation system? The sector itself is diverse - there is no one characteristic type of innovation system Traditionally a large role of the public sector, but the private sector is growing in importance. Technology rapidly becoming more diverse and complex (nuclear fusion, renewables) Important role of R&D and innovation Requires long time horizon for development and commercialisation Infrastructure dependent tendency for technology lock-in. 15

What are the characteristics of fuel cell innovation system? Rapidly growing energy technology sub-sector for stationary, mobile and portable applications, Co-existence of mature and emerging technology -the innovation system is changing fast, Actors include diverse industrial sectors outside the energy sector, firms of differing sizes and specialisation, and diverse scientific disciplines, Many government programmes and research consortia, Further development highly dependent on a well-functioning innovation system. 16

Public and private energy R&D trends 17

Figure 2 IEA Government Energy R&D Budgets, 1974-2001 US$ M illion, 2001 Prices and Exchange Rates 16000 14000 12000 10000 8000 6000 4000 2000 0 19 74 19 77 19 80 19 83 19 86 19 89 19 92 19 95 19 98 20 01 Conservation Fossil Fuels Renewable Energy Nuclear Fission Nuclear Fusion Power and Storage Other 18

14,000 12,000 10,000 8,000 6,000 4,000 2,000 0 Energy R&D Expenditure in the U.S. (in millions of constant 1995 $) Public Sector Private Sector Total 19 1998 1999 1980 1981 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1974 1975 1976 1977 1978 1979

Energy R&D Expenditure in Japan (in millions of constant 1995 PPP $) 8,000 7,000 6,000 5,000 4,000 Business Research institutes Universities Total 3,000 2,000 1,000 0 1982 1983 1984 1985 1986 1987 1988 1989 1990 1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 20

Private R&D Expenditure of the German Energy Sector (in millions of constant 1995 PPP $) 200 180 160 140 120 100 80 60 40 20 0 1995 1997 1999 2000 2001 21

Challenges in enhancing innovation in energy and fuel cells Sustaining R&D investment levels, in view of the decreasing overall R&D in both public and private sectors, Efficiently channelling R&D funds through public/private partnerships and research consortia, Taking measures to stimulate networking, in view of actors that are dispersed in diverse sectors in the innovation system, Extending the innovation system globally, including non-oecd member economies. 22