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Carbon-Negative Energy Systems Daniel L. Sanchez Postdoctoral Research Scientist Carnegie Institution for Science Department of Global Ecology Stanford, CA FCEA/CSTMS/ASU Carbon Dioxide Removal Workshop February 8, 2017 BECCS provides important flexibility for stringent climate change mitigation, even with limited biomass resources Increased research, development, and demonstration of BECCS is necessary CCS improves outcomes for bioenergy in lifecycle assessment 2 We can leverage near-term opportunities for BECCS to reach commercial deployment Bioenergy with Carbon Capture and Sequestration (BECCS) Biomass (fixes CO2 from atmosphere) Energy conversion process with carbon capture CO2 for compression and sequestration 3 Carbon-negative energy products 1) Biomass harvesting 4 2) Biomass capture & conversion 3) Energy products Canadell and Schulze (2014) Value of deployment: Western North America • Use high-resolution power sector planning model – SWITCH – High temporal and spatial detail • Constrain to sustainable biomass supply • Understand co-evolution of BECCS with other lowcarbon supply options 5 Representation of limited biomass availability 6 Sanchez et al., Nature Climate Change (2015) 7 Sanchez et al. (2015) 8 Sanchez et al. (2015) RD&D needs R&D • Large-scale biomass logistics • Gasification (high-temperature, oxygen- or steam-blown, pressurized, entrained flow gasification) • Systems integration • Gas cleaning Deployment • Delivery of identified, accessible, and permitted large-scale CO2 storage • Particular challenge in regions without a developed hydrocarbon exploration and production industry 9 Fragmentation, funding, R&D policy Fossil Energy • CCS demonstration • CO2 utilization • Clean coal Not • Standalone biomass gasification BECCS BETO • Feedstock logistics • Conversion processes • Biorefinery demonstration Not • Fossil coconversion • CCS DOE deployment programs should take the form of a crosscutting initiative 10 11 Sanchez et al. (Under Review) Lifecycle assessment: benefits of biomass integration 12 Sanchez and Kammen, Nature Energy (2016) The “best” use of land for climate mitigation Capturing CO2 from bioenergy processes enhances CO2 mitigation potential 13 Evans et al. (2015) Near-term deployment of ethanol+CCS Capture costs: ~$20/tCO2 from fermentation First markets: CA’s Low Carbon Fuel Standard ~$75/ton abated Carbon Capture Utilization and Storage Act $50/ton stored 14 World’s first BECCS facility - Decatur, IL 15 Options to decrease carbon intensity of products 1 - Increase ratio of biomass / coal inputs (a) Sulfur Coal Air O2 CO2 Recycle 2 Steam Air Separation Unit 2 - Increase shift of syngas in WGS reactor 3 Water-Gas Shift (WGS) Gasification 3 - Recycle CO 2 from sulfur removal to AGR Sulfur Removal R Electricity Integrated Gasification Combined Cycle (IGCC) Acid Gas Removal (AGR) H2 O CO + H 2 O -> CO 2 + H 2 N2 Biomass 1 (b) 2 Coal Gasfication Sulfur Fuels (Gasoline, asoline, Diesel) Dies 2 2 Acid Gas Removal (AGR) Tropsch Synthesis Tropsch Refining Combined Cycle Power Island Flexibility to balance product cost and carbon reduction goals Recycle Steam team Biomass Gasification G Tar Cracking and Filtering 1 16 Options to decrease carbon intensity of products 1 - Increase ratio of biomass / coal inputs 2 - Recycle CO 2 from sulfur removal to AGR 3 - Autothermal reforming + shift prior to electricity production S Sulfur Thermochemical conversion enables products with wide range Removal + H O -> CO intensities, +H ofCOcarbon process efficiencies and process scales FischerFischerBypass O2 CO2 Recycle Water-Gas Shift (WGS) 2 Air Separation Unit CO2 (for compression and sequestration) Bypass CO2 (for for c compression omp res and sequestration) sequestratio Electricity Elect 3 Autothermal Reformer Water-Gas Shift CO O2 Removal Sanchez and Kammen, Nature Energy (2016) BECCS provides important flexibility for stringent climate change mitigation, even with limited biomass resources Increased research, development, and demonstration of BECCS is necessary CCS improves outcomes for bioenergy in lifecycle assessment 17 We can leverage near-term opportunities for BECCS to reach commercial deployment Appendix 18 “Negative-emission technologies are not an insurance policy, but rather an unjust and high-stakes gamble.” -Anderson and Peters (2016) The necessity of negative emissions to meet emissions reductions goals provide strong motivation for increased research, development, and demonstration of these technologies. 19 ~3 PgC/yr [GtC/yr]= 30% of current (2014) global emissions Three “stabilization wedges” Cumulative capital investment through 2050: over $1.9 trillion Deployment: 24 GW/yr of BECCS by 2040 20 21 Anderson and Peters, Science (2016) D.L. Sanchez, D.S. Callaway. “Optimal Scale of Bioenergy with Carbon Capture and Storage (BECCS) Facilities” Applied Energy, 170, 437-444 (2016) D.L. Sanchez, et al. “Biomass enables the transition to a carbonnegative power system across western North America.” Nature Climate Change, 5, 230–234 (2015) 22 D.L. Sanchez, D.M. Kammen. “A commercialization strategy for carbon-negative energy” Nature Energy, 1, 1-4 (2016) Why study deployment? • Existing analyses have relatively simple representation of the energy economy • Goals: – Inform near-term efforts to build facilities – Integrate into existing energy systems – Respect regional considerations – Complement existing energy and climate policy 23 Scenario analysis • Technology availability and environmental policy (carbon cap) 86% BECCS No biomass No biomass, no CCS 105% 120% 145% 24 Sanchez et al. (2015) Unit Commitment / Dispatch Time Frame • Short-term (sub hourly to one year) • Long-term (year to decades) Free Variables Operational Constraints Typical output • • • • • • How much generation and transmission to install • Planning regulations • Environmental policy • Annual generation, generation and transmission capacity builds/retirements, emissions, electricity prices, credit/allowance prices • (Mixed integer) linear program Which units to use How much to produce Plant ramping / operation Power flow Sub-hourly unit level generation, powerflow, locational marginal prices, emissions, ancillary service prices, curtailments Typical • Mixed integer non-linear Formulation program 25 Capacity Expansion SWITCH model • SWITCH- a loose acronym for Solar, Wind, Hydro, and Conventional generation and Transmission Investment • Dispatch solved simultaneously with investment decisions (generation and transmission) • Objective: minimize net present cost of meeting demand in all simulated hours in all investment periods • Subject to: carbon and renewable policy constraints, linearized operational constraints, simplified transmission constraints • Typically run from present-day through 2050 26 Role of flexibility in power systems dispatch 27 27 Sanchez et al. (2015) Technology roadmaps • Climate change mitigation requires gigawatt-scale carbon dioxide removal technologies, yet few examples exist beyond niche markets • Goal: Propose commercialization strategy for carbon-negative energy • Framing: Thermochemical conversion of hydrocarbons to electricity and/or fuels • Catalog needs and interventions to support emerging near-zero emissions technologies – research & development, demonstration, finance, policy, and social engagement 28 Sanchez and Kammen, Nature Energy (2016) Conclusions about deployment • BECCS, combined with aggressive renewable deployment and fossil-fuel emission reductions, can enable a carbon-negative power system in western North America by 2050 with up to 145% emissions reduction from 1990 levels • In most scenarios, the offsets produced by BECCS are found to be more valuable to the power system than the electricity it provides • This suggests a different climate change mitigation pathway than others have proposed 29 30 Courtesy of Scott McDonald, ADM 31 Courtesy of Scott McDonald, ADM BECCS deployment can be cost-effective Process simulation Techno-economic analysis + scaling Pipeline routing and optimization Estimate of abatement cost and potential Lifecycle analysis of corn ethanol + CCS Comparison to existing and potential subsidies Compare to: • CA’s Low Carbon Fuel Standard [Executive Order S-1-07] ~$75/ton • Carbon Capture Utilization and Storage Act [S.3179] ~$50/ton 32 Works cited D.L. Sanchez, D.M. Kammen. “A commercialization strategy for carbon-negative energy” Nature Energy, 1, 1-4 (2016). D.L. Sanchez, J.H. Nelson, J. Johnston, A. Mileva, D. Kammen. “Biomass enables the transition to a carbon-negative power system across western North America.” Nature Climate Change, 5, 230–234 (2015). D.L. Sanchez, D.S. Callaway. “Optimal scale of carbon-negative energy facilities.” Applied Energy, 170, 437–444 (2016). D.L. Sanchez, D.M. Kammen. “Removing harmful greenhouse gases from the air using energy from plants.” Frontiers for Young Minds, 3:14, doi: 10.3389/frym.2015.00014. D.L. Sanchez, J.H. Nelson, J. Johnston, A. Mileva, D. Kammen. “Emissions accounting for bioenergy with CCS.” Nature Climate Change, 5, 495–496 (2015). 33 Flexibility and scale • Thermochemical conversion products with wide range of carbon intensities, process efficiencies and process scales • Flexibility to balance product cost and carbon reduction goals • Co-utilization increase efficiency, decrease unit costs, lessen feedstock variability, extend impact of scarce biomass • Smaller systems smaller minimum capital expenditures, greater experimentation 34 Fossil Fuels Biomass Low-carbon & carbonnegative products An agenda for transition • Cumulative capital investment through 2050 >$1.9 trillion (2015$, 4% real) • Deployment of up to 24 GW/yr of BECCS by 2040 • To achieve this within 15-20 years, governments and firms must commit to RD&D on an unprecedented scale • Likely to work best in developed economies “This strategy holds advantage for existing industries, supply chains, and workforces. Here, firms can embrace a gradual transition pathway to deep decarbonization, limiting economic dislocation and increasing transfer of knowledge between the fossil and renewable sectors.” 35 Sanchez and Kammen (2016)