MISSION INNOVATION Accelerating Clean Energy Innovation in the United States by June 30, 2016 www.mission-innovation.net www.energy.gov 1
Agenda Overview of Mission Innovation Dave Turk, Deputy Assistant Secretary for International Climate and Technology, U.S. Department of Energy Context on the U.S. Energy System and Public Investment Priorities in Clean Energy Innovation Joseph Hezir, Chief Financial Officer, U.S. Department of Energy DOE-led Innovation Activities and Opportunities for Additional R&D Franklin (Lynn) Orr, Under Secretary for Science and Energy, U.S. Department of Energy Leveraging the Resources of the Clean Energy Investment Center and Office of Technology Transitions Sanjiv Malhotra, Director of the Clean Energy Investment Center, U.S. Department of Energy Question and Answer Session 2
A Unique Moment in Time All on One Stage – Leaders of 20 Countries Representing over 80% of Global Clean Energy R&D Investment Launched Mission Innovation Each Country Will Seek to Double its Governmental Clean Energy R&D Investment over Next Five Years (www.mission-innovation.net) Mission Innovation Launch was Complemented by Annoucement of Independent Breakthrough Energy Coalition (www.breakthroughenergycoalition.com) 3
Rationale On Climate Change, Time is Running Out: Indexed Cost Reductions Since 2008 Atmospheric Concentrations of GHGs are Land-Based Wind Rising, with Substantial and Growing Impacts 120 Distributed PV Business as Usual Approach is Unacceptable Utility-Scale PV 100 Current Solutions and Nationally Determined Modeled Battery Costs Contributions are Helping, but More Ambition Is Needed LEDs 80 The Pace of Innovation Remains Too Slow 60 Power of Innovation: 40 Costs of Wind, Solar PV, Battery Costs, and LEDs Have Dropped Dramatically 20 More Innovative Ideas Are on Cusp of Realization, but Need a Boost to Market 0 2008 2009 2010 2011 2012 2013 2014 Government and Private Investment Needed Innovation Can Speed Solutions and Mitigate Source: Adapted from DOE, “Revolution…Now: The Future Arrives for Five Clean Energy Technologies – 2015 Update,” http://www.energy.gov/eere/downloads/revolution -now- Climate Change Impacts for Long Haul future-arrives-five-clean-energy-technologies-2015-update 4
Global Scope Norway Sweden Canada United Kingdom Denmark Germany European Union United France Japan China Italy States Saudi Arabia India Republic Mexico of Korea United Arab Emirates Indonesia Brazil Australia Chile Mission Innovation Countries Represent: 5 Most Populous Countries 60% of the World’s Population 68% of the Total Greenhouse Gas Emissions 82% of Global GDP 75% of the CO 2 Emissions from Electricity Well over 80% of Government Investment in Clean Energy R&D 5
Doubling Clean Energy R&D Investment 6
Inaugural Ministerial and Next Steps Announcement of Clean Energy R&D Doubling Plans and Priorities Addition of European Union as 21 st Member Governance and administration outlined in Enabling Framework Compilation of technology roadmaps and meta analysis Business and Investor Engagement Opportunities See the summary video and full livestream video of the Ministerial Beginning of webinar series…..more to come 7
Mission Innovation Joseph Hezir , Chief Financial Officer, U.S. Department of Energy and Franklin (Lynn) Orr , Under Secretary for Science and Energy, U.S. Department of Energy
Scope of Mission Innovation for U.S. FY 17 President’s Budget Request • Mission Innovation consists of early-stage clean energy elements of existing programs that are research, development and demonstration (RD&D) – not deployment • FY 2016 U.S. government-wide baseline is $6.4 billion and, of this, the U.S. Department of Energy (DOE) baseline is $4.8 billion (75%) Clean energy technology is any process, product or system of products and processes, that can be applied at any stage of the energy cycle from production to consumption, whose application will reduce net greenhouse gas emissions, and can meet one or more of the following characteristics: • reduced demand for water resources • reduced waste • reduced emissions of other air pollutants • or reduced concentrations of contaminants in wastewater discharges. Example: US Innovation Pathways 9 9
DOE Mission Innovation FY17 Budget Request ($ millions) FY 2016 FY 2017 % Increase President’s Budget Request TOTAL Mission % MI TOTAL Mission % MI TOTAL Mission Innovation Innovation Innovation Efficiency/Renewables EERE 2,073 1,406 67.8% 2,898 2,108 72.7% 39.8% 49.9% Electricity Office OE 206 153 74.4% 262 177 67.5% 27.3% 15.5% Fossil Energy FE 632 533 84.3% 600 564 94.0% -5.1% 5.8% Nuclear Energy NE 986 862 87.4% 994 804 80.9% 0.8% -6.7% Advanced Projects ARPA-E 291 291 100.0% 350 350 100.0% 20.3% 20.3% Science Office SC 5,350 1,577 29.5% 5,572 1,853 33.3% 4.1% 17.5% 9,538 4,823 50.6% 10,676 5,857 54.9% 11.9% 21.4% TOTAL 10
Energy Frontier Research Centers • Over 100 participating institutions, located in 33 states plus the District of Columbia Lead Institution 1 8 • Advisors from 12 23 countries, 29 states • $2-$4 million for year for five years University DOE Laboratory Non-Profit 11
Energy Research Frontiers Centers California Missouri Light-Material Interactions in Energy Conversion (LMI) Photosynthetic Antenna Research Center (PARC) Catalysis Center for Energy Innovation Montana Center for Biological Electron Transfer and Catalysis (BETCy) District of Columbia Energy Frontier Research in Extreme Environments New Mexico Center for Advanced Solar Photophysics (CASP) Georgia Center for Understanding and Control of Acid Gas-induced New York Evolution of Materials for Energy (UNCAGE-ME) NorthEast Center for Chemical Energy Storage (NECCES) Center for Emergent Superconductivity (CES) Illinois Center for Mesoscale Transport Properties (m2m) Center for Electrochemical Energy Science Center for Geologic Storage of CO 2 (GSCO 2 ) North Carolina Center for Solar Fuels (UNC) Indiana Center for Direct Catalytic Conversion of Biomass to Biofuels Pennsylvania (C3Bio) Center for Lignocellulose Structure and Formation (CLSF) Center for the Computational Design of Functional Layered Maryland Materials (CCDM) Nanostructures for Electrical Energy Storage (NEES) Tennessee Massachusetts Fluid Interface Reactions, Structures and Transport Center Integrated Mesoscale Architectures for Sustainable Catalysis (FIRST) (IMASC) Energy Dissipation to Defect Evolution (EDDE) Center for Excitonics (CE) Solid-State Solar-Thermal Energy Conversion Center (S 3 TEC) Texas Center for Frontiers of Subsurface Energy Security (CFSES) Minnesota Inorganometallic Catalyst Design Center (ICDC) Washington Center for Molecular Electrocatalysis (CME) 12
Energy Frontier Research Centers - Accomplishments 600 8000 EFRC Intellectual Property EFRC Publications Disclosures 6000 400 Patent Applications - USA 4000 200 2000 0 0 1 2 3 4 5 6 7 1 2 3 4 5 6 7 Program Year Program Year 100 Companies that have benefited from EFRCs EFRC Contributions* to Companies 80 60 Science Applications Large Low-Carbon Power 40 Mid Energy Storage Start-up 20 Energy Efficiency 0 1 2 3 4 5 6 7 *Based on 2014 DOE Technology Transfer Report 13 Program Year
Companies that Benefit from EFRC Research 7
Energy Innovation Hubs Dollars in Millions ($M) FY 2016 FY 2017 Energy Innovation Hubs Enacted Request EERE: Critical Materials Institute (AMES) 25 20 Explores ways to address challenges in critical materials, including mineral processing, manufacture, substitution, efficient use, and end-of-life recycling. EERE: Energy-Water Nexus Desalination Hub (TBD) 0 25 Will serve as a center of research focused on developing integrated technological system solutions and enabling technologies for de-energizing, de-carbonizing, and reducing the cost of desalination to provide clean and safe water. NE: Modeling and Simulation of Nuclear Reactors (ORNL) 24 24 Creates a "virtual" version of an existing operating Pressurized Water Reactor, a modeling and simulation tool known as the Virtual Environment for Reactors Analysis (VERA) that is being used to create a better understanding of performance and safety issues with these reactors. SC: Batteries and Energy Storage Hub (ANL) 24 24 Focuses on discovery of new energy storage chemistries through the development of an atomic-level understanding of reaction pathways and development of universal design rules for electrolyte function. SC: Fuels from Sunlight Hub (LBNL) 15 15 Creates critical transformative advances in the development of artificial photosynthetic systems for converting sunlight, water, and carbon dioxide into a range of commercially useful fuels. Total, Energy Innovation Hubs 88 108 15
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