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Major Roles for Fossil Fuels in an Environmentally Constrained World Robert H. Williams Princeton University Sustainability in Energy Production and Utilization in Brazil: The Next Twenty Years Universidade Estadual de Campinas Campinas Sao Paulo, Brazil 18-20 February 2002 OUTLINE OF PRESENTATION • Climate change context to motivate considerations of: --electricity + hydrogen economy --relative roles of renewables and decarbonized fossil energy • • • • • Prospects for geological storage of CO2 H2 production technology, with focus on coal H2 costs as automotive fuel Is decarbonization of natural gas worthwhile? Conclusions and implications for Brazil CLIMATE CLIMATE CHALLENGE (IS92a “BAU” Scenario of IPCC) Increase in global energy use/capita, 1997-2100: For primary energy up 2.0X ( 1/3 US level in 1997) For electricity up 2.6X (½ US level in 1997) For “fuels used directly” up 1.4X (¼ US level in 1997) Global CO2 emissions: Total: 6.2 GtC (1997, actual, 37% coal) 20 GtC (2100, 88% coal) From electricity generation: 1.9 GtC (1997) 5 GtC (2100) From “fuels used directly”: 4.3 GtC (1997) 15 GtC (2100) Cumulative emissions, 1990-2100: 1500 GtC Allowable Cumulative Carbon Emissions to Reach Various Targets 1600 1400 1200 1000 Gt C WRE350a WRE450a 800 WRE550a WRE650a WRE750a 600 400 200 0 1980 2000 2020 2040 2060 2080 2100 2120 Renewables/Decarbonized Fossil Energy Competition, Carbon-Constrained World For electricity: Renewables will be strong competitors for decarbonized fossil fuels—esp. wind (central station), PV (distributed, grid-connected) Electric storage problem “solved” at large scales (CAES) For fuels used directly (2/3 of CO2 emisions today): Biomass--regionally important but limited global potential relative to challenge Poor near-term and long-term economic prospects for making H2 via water-splitting (electrolysis or thermochemical cycles) from renewables—relative to H2 from fossil fuels with CO2 removal and sequestration GLOBAL PERSPECTIVE ON BIOMASS According to World Energy Assessment, long-term biomass energy potential ~ 100 – 300 EJ/y (for comparison: global primary energy use~ 400 EJ/y, 1997) Biomass contributions to energy in IS92a: ~ 130 EJ/y in 2050 (compared to 655 EJ/y from fossil fuels) ~ 205 EJ/y in 2100 (compared to 865 EJ/y from fossil fuels) Although it can make important regional contributions, biomass alone cannot adequately decarbonize fuels used directly to the extent needed to solve climate change problem Implications of Renewable/Fossil Energy Competition for Carbon Management • No carbon problem if fossil fuels = conventional oil/NG • Most of climate change challenge posed by coal [and, to lesser extent, unconventional oil (e.g., tar sands, heavy oils)] • Most of climate change challenge posed by “fuels used directly” and will be severe even if electricity is 100% decarbonized in this century • But gasification-based H2 production/CO2 sequestration technologies offer good prospects for decarbonizing lowquality fossil energy feedstocks at attractive costs • Are there options for storing the CO2 byproduct of H2 production that are adequate to raise the decarbonization/CO2 sequestration strategy to the status of a major contender in the energy race to achieve near-zero emissions of greenhouse gases? OPTIONS FOR CO2 DISPOSAL Deep Ocean Disposal (> 3 km) Most discussed option Reduces rapid transient CO2 buildup in atmosphere Significantly reduces long-term atmospheric CO2 concentration (> 50%) Many environmental concerns (e.g., ocean life impacts of pH changes, impacts of CO2 hydrate particles on benthic organisms, ecosystems) Depleted Oil & Natural Gas Fields Large capacity (~ 500 GtC) Most secure option if original reservoir pressure not exceeded Some opportunities for enhanced oil/natural gas resource recovery Geographically limited option Deep Beds of Unminable Coal CO2 injection can be used for enhanced methane recovery from unminable coal beds CO2 will remain in place (adsorptivity of CO2 on coals much higher than for CH4) Geographically limited option Deep Saline Aquifers Deep saline aquifers (> 800 m) widely available geographically Enormous potential if closed aquifers with structural traps are not required Uncertainties about storage security, but time scales for reaching near-surface fresh-water aquifers are long (~ 2000 y) GLOBAL CAPACITY FOR CO2 STORAGE IN DEEP SALINE AQUIFERS If aquifers with structural traps are needed: ~ 50 GtC (C. Hendriks, Carbon Dioxide Removal from Coal-Fired Power Plants, Dept. of Science, Technology, and Society, Utrecht University, The Netherlands, 1994) If large open aquifers with good top seals can also be used: Up to 2,700 GtC (IEA GHG R&D Programme) ~13,000 GtC (C. Hendriks, Carbon Dioxide Removal from Coal-Fired Power Plants, Dept. of Science, Technology, and Society, Utrecht University, The Netherlands, 1994) For comparison: Projected emissions from fossil fuel burning, 1990-2100, IS92a: ~ 1500 GtC Reasonable target for sequestration, 21st century ~ 600 GtC Carbon content of remaining exploitable fossil fuels (excluding methane hydrates): ~ 5,000 - 7,000 GtC EXPERIENCE WITH CO2 DISPOSAL ENHANCED OIL RECOVERY: 74 projects worldwide; often profitable in mature oil-producing regions; 4% of US oil so produced—mostly using CO2 from natural reservoirs piped up to 800 km, but Weyburn (Canada) uses 1.5 million tonnes/y of CO2 piped 300 km from North Dakota coal gasification plant ENHANCED COAL BED METHANE RECOVERY: 1 commercial project in San Juan Basin (US) ACID GAS DISPOSAL: 31 acid gas (H2S + CO2) disposal projects in Canada TWO PROJECTS FOR AQUIFER DISPOSAL OF CO2 ASSOCIATED WITH OFF-SHORE NATURAL GAS PRODUCTION: Sleipner Project in North Sea (since 1996) Natuna Project in South China Sea (planned for 2005-2010) EXPERIENCE WITH & PLANS FOR AQUIFER CO2 DISPOSAL AT LARGE SCALES NG Field Firm CO2 in gas (%) Disposal Rate t CO2/y t C/y Destination of CO2 OnStream Sleipner West, Norway, North Sea Statoil ($50-$80 million project) 9.5% 1M 0.3 M Sleipner East, Utsira Formation (800 m depth) 1996 (20 y life) Natuna, Indonesia, South China Sea Pertamina & Exxon/ Mobil 71% > 100 M > 30 M Two aquifers north of Natuna field ~ 2005? CAN NEAR-ZERO GHG/AIR POLLUTANT EMISSIONS BE REALIZED AT ACCEPTABLE COST? Plausibly yes, if H2 major energy carrier complementing electricity— (CO2 recovery costs low in H2 manufacture) Requirements: · Large, widely available, secure, and environmentally acceptable storage capacity for CO2—geological storage options promising · Technology for manufacturing H2 from abundant fossil fuel sources · H2 competitive as energy carrier need technologies that: —put high market value on H2 (e.g., fuel cells in transport) —provide H2 at competitive costs · H2 must be produced centrally to minimize cost of CO2 disposal WHY COAL? Coal resources abundant globally: Recoverable coal ~ 200,000 EJ (580 y supply at current fossil energy use rate) Recoverable natural gas Conventional Unconventional ~ 12,000 EJ ~ 33,000 EJ Coal prices low [1997 NG price for US electric generators: 2.1 X coal price; projected (2020): 3.7 X coal price]; not volatile Environmental issues need radical technological innovation Gasification near-zero emissions of air pollutants/GHGs Residual environmental, health, safety problems of coal mining MAKING H2 FROM FOSSIL FUELS Begin with”Syngas” Production: Oxygen-Blown Coal Gasification: Steam-Reforming of Natural Gas CH0.82O0.07 + 0.47 O2 + 0.15 H2O 0.56 H2 + 0.85 CO + 0.15 CO2 CH4 + H2O CO + 3H2 Followed by Syngas Cooling & Water-Gas Shift Reaction: CO + H2O H2 + CO2, Net Effect: CH0.82O0.07 + 0.47 O2 + 1.00 H2O 1.40 H2 + 1.00 CO2 CH4 + 2 H2O CO2 + 4 H2 Followed by CO2/H2 Separation via Physical or Chemical Process HHV efficiency [(H2 output)/(Total primary fuel input)]: ~ 70% for coal ~ 80% for natural gas Separated CO2 Can Be Disposed of at Relatively Low Incremental Cost H2 Production from Coal with CO2/H2S Cosequestration Air separation unit Quench + scrubber Gasifier oxygen air High temp. WGS reactor CO-rich raw syngas coal slurry Syngas expander CO2-lean exhaust gases Steam turbine steam Syngas cooling HRSG H2 product Gas turbine Low temp. WGS reactor H2- and CO2-rich syngas air compressed purge gas Pressure swing adsorption lean solvent N2 for NOx control CO2 + H2S to storage Conventional hydrogen 2 (1-7-02) CO2/H2S physical absorption CO2/H2S drying and compression rich solvent Solvent regeneration NG price: 2.44 $/GJ HHV Hydrogen Cost vs. Carbon Tax 70 bar Hydrogen Cost ($/GJ HHV) 8.5 8.0 CO2 -sulfur co-sequestration 7.5 7.0 6.5 6.0 CO2 venting 5.5 Coal, conventional technology Natural gas, steam reforming 5.0 4.5 0 20 40 60 Carbon Tax ($/tonne C) 80 100 Fig. L2ab • With CO2 venting, cost of H2 from NG SMR always lower than H2 from coal • But, even at today’s low NG prices (2.44 $/GJ), H2 from coal with CO2-sulfur co-sequestration is comparable to H2 from NG • Note: 70 bar conventional technology is commercially available today NG price: 3.4 $/GJ HHV Hydrogen Cost vs. Carbon Tax 70 bar Hydrogen Cost ($/GJ HHV) 8.5 8.0 7.5 CO2 -sulfur co-sequestration 7.0 6.5 6.0 5.5 CO2 venting Natural gas, steam reforming Coal, conventional technology 5.0 4.5 0 20 40 60 Carbon Tax ($/tonne C) • 80 100 Fig. L2ac At NG prices (3.4 $/GJ) likely to be typical 20 y from now, cost of H2 from coal with CO2-sulfur co-sequestration is significantly lower than H2 from NG SMR Consumer Fuel Costs for Gasoline ICE Cars and H2 Fuel Cell Cars (excluding retail fuel taxes) Fuel cost (¢/liter, gasoline equivalent) Cost of driving (¢/km) Production cost Cost to consumer Gasoline ICE (6.7 l/100km) H2 fuel cell car (2.9 l/100 km ge) Gasoline 23 30 2.0 - H2 from coal, CO2 vented 21 50 - 1.4 H2 from coal, CO2 seq. 27 56 - 1.6 Electricity Production via Coal IGCC with CO2/H2S Cosequestration Air separation unit Quench + scrubber Gasifier oxygen air High temp. WGS reactor CO-rich raw syngas coal slurry Syngas expander CO2-lean exhaust gases Steam turbine steam Syngas cooling HRSG Low temp. WGS reactor Gas turbine H2- and CO2-rich syngas air H2-rich syngas lean solvent N2 for NOx control CO2 + H2S to storage Conventional electricity 2 (1-7-02) CO2/H2S physical absorption CO2/H2S drying and compression rich solvent Solvent regeneration Carbon Tax Needed to Induce CO2 Sequestration in the Production of H2 and Electricity ($/tC) Energy Carrier Feedstock for Producing Energy Carrier Natural Gas with CO2 Sequestered Coal with CO2: Sequestered Cosequestered H2 ~ 100 ~ 50 ~ 30 Electricity ~ 250 ~ 80 ~ 50 Remaining Global NG & Conv. Oil Resources Energy Resources (103 EJ) Carbon Content (GtC) Low Med High Low Med High Conv. oil 9.4 11.1 13.7 179 211 260 Conv. NG 8.7 11.9 16.5 118 162 224 Subtotal 18.1 23.0 30.2 297 373 484 Unconv. NG 33.2 452 Total 56.2 824 CONCLUSIONS • Stabilizing atmospheric CO2 at 450-550 ppmv requires decarbonizing both electricity and fuels used directly. • Although there are many uncertainties, potential CO2 storage capacity in geological media is probably large enough to make fossil fuels decarbonization/CO2 sequestration a major energy option for a GHGemissions-constrained world. • In electricity markets renewables and decarbonized energy systems will be strong competitors; renewables might well win the economic race to near-zero emissions. • Biofuels will be regionally important but the global potential is inadequate for biofuels to make more than a modest contribution in addressing the climate change challenge posed by fuels used directly. CONCLUSTIONS (continued) • H2 will probably be needed as a major energy carrier in markets that use fuels directly. • By a wide margin, the least costly route to providing H2 in a GHG -emissions-constrained world will be from carbonaceous feedstocks. • Making H2 from coal will probably be less costly than making it from NG at typical feedstock prices in 2020 timeframe. • If a concerted effort can be directed to decarbonizing coal, it might not be necessary to decarbonize NG energy systems. • The production of H2 from water via electrolysis or complex thermochemical cycles will play at most marginal roles in providing H2 unless geological sequestration of CO2 turns out to be a fatally flawed idea. IMPLICATIONS FOR BRAZIL • Prospect of H2 economy as necessary major component of climate mitigation strategy has major implications for all countries. • Brazil has opportunity to support demonstration projects for H2 fueled vehicles with H2 derived from offpeak hydropower. • Additional H2 supplies might be provided by gasification of petroleum residuals at refineries—e.g., petcoke gasification at Brazilian refineries could support more than 1 million fuel cell cars. • Brazil is one of few places where biomass-derived H2 might eventually become major option—and if CO2 coproduct were sequestered (so that CO2 emissions would be negative), Brazil could thereby plausibly sell profitably emission rights to the atmosphere under a global cap-and-trade regime. Evolving CO2 Plume Front in a Vertical Cross Section of a Disposal Aquifer Modeling from: Eric Lindeberg, Escape of CO2 from aquifers, Energy Conversion and Management, 38 Suppl: 235-240. Escape of CO2 from an Aquifer with a Spill Point Located 8 km from the Injector Modeling from: Eric Lindeberg, Escape of CO2 from aquifers, Energy Conversion and Management, 38 Suppl: 235-240.