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References

Published online by Cambridge University Press:  02 February 2023

Mark Z. Jacobson
Affiliation:
Stanford University, California
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No Miracles Needed
How Today's Technology Can Save Our Climate and Clean Our Air
, pp. 384 - 412
Publisher: Cambridge University Press
Print publication year: 2023

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References

Green, H., and Lane, W., Particle Clouds, Van Nostrand, 1969.Google Scholar
WHO (World Health Organization), Health statistics and information systems, 2021, www.who.int/health-topics/universal-health-coverage/health-statistics-and-information-systems (accessed November 20, 2021).Google Scholar
WHO (World Health Organization), Air pollution data portal, 2021, www.who.int/data/gho/data/themes/air-pollution (accessed November 20, 2021).Google Scholar
WHO (World Health Organization), Household air pollution and health, 2021, www.who.int/news-room/fact-sheets/detail/household-air-pollution-and-health (accessed January 8, 2022).Google Scholar
Jacobson, M.Z., von Krauland, A.-K., Coughlin, S.J., et al., Low-cost solutions to global warming, air pollution, and energy insecurity for 145 countries, Energy Environ. Sci., https://doi.org/10.1039/d2ee00722c, 2022.CrossRefGoogle Scholar
Jacobson, M.Z., Effects of biomass burning on climate, accounting for heat and moisture fluxes, black and brown carbon, and cloud absorption effects, J. Geophys. Res., 119, 89809002, https://doi.org/10.1002/2014JD021861, 2014.Google Scholar
Canadell, J.G., Monteiro, P.M.S., Costa, M.H., et al., Global Carbon and other Biogeochemical Cycles and Feedbacks. In: Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change, Masson-Delmotte, V., Zhai, P., Pirani, A., et al., eds., Cambridge University Press, 2021.Google Scholar
Jacobson, M.Z., 100% Clean, Renewable Energy and Storage for Everything, Cambridge University Press, 2020.CrossRefGoogle Scholar
Jacobson, M.Z., A physically-based treatment of elemental carbon optics: Implications for global direct forcing of aerosols, Geophys. Res. Lett., 27, 217220, 2000.Google Scholar
Jacobson, M.Z., Strong radiative heating due to the mixing state of black carbon in atmospheric aerosols, Nature, 409, 695697, 2001.Google Scholar
Jacobson, M.Z., Control of fossil-fuel particulate black carbon plus organic matter, possibly the most effective method of slowing global warming, J. Geophys. Res., 107, 4410, https://doi.org/10.1029/2001JD001376, 2002.Google Scholar
Jacobson, M.Z., Short-term effects of controlling fossil-fuel soot, biofuel soot and gases, and methane on climate, Arctic ice, and air pollution health, J. Geophys. Res., 115, D14209, https://doi.org/10.1029/2009JD013795, 2010.Google Scholar
Bond, T.C., Doherty, S.J., Fahey, D.W., et al., Bounding the role of black carbon in the climate system: a scientific assessment, J. Geophys. Res., 118, 53805552, https://doi.org/10.1002/jgrd.50171, 2013.CrossRefGoogle Scholar
Jacobson, M.Z, On the causal link between carbon dioxide and air pollution mortality, Geophys. Res. Lett., 35, L03809, https://doi.org/10.1029/2007GL031101, 2008.CrossRefGoogle Scholar
Jacobson, M.Z., The enhancement of local air pollution by urban CO2 domes, Environ. Sci. Technol., 44, 24972502, https://doi.org/10.1021/es903018m, 2010.Google Scholar
Ritchie, H., and Roser, M., Access to energy, 2020, https://ourworldindata.org/energy-access (accessed November 20, 2021).Google Scholar
Vavrin, J., Power and energy considerations at forward operating bases (FOBs). United States Army Corps of Engineers, Engineer Research and Development Center, Construction Engineering Research Laboratory, 2010 https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.965.2873&rep=rep1&type=pdf (accessed November 20, 2021).Google Scholar
Sambor, D.J., Wilber, M., Whitney, E., and Jacobson, M.Z., Development of a tool for optimizing solar and battery storage for container farming in a remote Arctic microgrid, Energies, 13, 5143, https://doi.org/10.3390/en13195143, 2020.CrossRefGoogle Scholar
Krane, J., and Idel, R., More transitions, less risk: how renewable energy reduces risks from mining, trade and political dependence, Energ. Res. Soc. Sci., 82, 102311, 2021.CrossRefGoogle Scholar
General Electric, Haliade-X offshore wind turbine platform, www.ge.com/renewableenergy/wind-energy/turbines/haliade-x-offshore-turbine, 2018 (accessed November 16, 2018).Google Scholar
Durakovic, A., Fixed bottom offshore wind farms 90 metres deep? Offshoretronics says yes, 2021, www.offshorewind.biz/2021/11/29/fixed-bottom-offshore-wind-farms-90-metres-deep-offshoretronic-says-yes/ (accessed November 29, 2021).Google Scholar
U.S. Department of the Interior, Reclamation: Managing water in the west; Hydroelectric power, 2005, www.usbr.gov/power/edu/pamphlet.pdf (accessed November 22, 2018).Google Scholar
Rahi, O.P., and Kumar, A., Economic analysis for refurbishment and uprating of hydropower plants, Renew. Energy, 86, 11971204, 2016.CrossRefGoogle Scholar
Dictionary, Free, Installed capacity: definition, 2019 https://encyclopedia2.thefreedictionary.com/Installed+Capacity (accessed March 15, 2019).Google Scholar
Corbley, A., These underwater ‘kites’ are generating tidal electricity as they move, 2021, www.goodnewsnetwork.org/faroe-islands-looks-to-tidal-power-with-tis-underwater-kites/ (accessed December 3, 2021).Google Scholar
Lee, K., Um, H.-D., Choi, D., et al., The development of transparent photovoltaics, Cell Rep. Phys. Sci., 1, 100143, https://doi.org/10.1016/j.xcrp.2020.100143, 2020.Google Scholar
Renovagen, Rollable solar panels, 2021, www.renovagen.com (accessed November 20, 2021).Google Scholar
Bellini, E., Flexible solar panel for vehicle-integrated applications, 2021, www.pv-magazine.com/2021/09/02/flexible-solar-panel-for-vehicle-integrated-applications/ (accessed November 20, 2021).Google Scholar
Kougias, I., Bodis, K., Jager-Waldau, A., et al., The potential of water infrastructure to accommodate solar PV systems in Mediterranean islands, Solar Energy, 136, 174182, https://doi.org/10.1016/j.solener.2016.07.003, 2016.CrossRefGoogle Scholar
Hussain, A., Batra, A., and Pachauri, R., An experimental study on effect of dust on power loss in solar photovoltaic module, Renewables: Wind, Water, Solar 4, 9, 2017.Google Scholar
U.S. Department of Energy, Concentrating solar power commercial application study: reducing water consumption of concentrating solar power electricity generation, Report to Congress, 2008, www1.eere.energy.gov/solar/pdfs/csp_water_study.pdf (accessed December 28, 2019).Google Scholar
Nonbol, E., Load-following capabilities of nuclear power plants, Technical University of Denmark, 2013, http://orbit.dtu.dk/files/64426246/Load_following_capabilities.pdf (accessed November 22, 2018).Google Scholar
Utility Dive, Los Angeles considers $3B pumped storage project at Hoover Dam, 2018, www.utilitydive.com/news/los-angeles-considers-3b-pumped-storage-project-at-hoover-dam/528699/ (accessed December 15, 2021).Google Scholar
Blakers, A., Stocks, M., Lu, B., Cheng, C., and Nadolny, A., Global pumped hydro atlas, 2019, http://re100.eng.anu.edu.au/global/ (accessed March 31, 2019).Google Scholar
Willuhn, M., Sonnen battery still running after 28,000 full charge cycles, 2021, www.pv-magazine.com/2021/07/15/sonnen-battery-still-running-after-28000-full-charge-cycles/ (accessed July 15, 2021).Google Scholar
Morrison, R., New ‘iron-air’ battery stores electricity from renewables for days, 2021, www.msn.com/en-us/news/technology/new-iron-air-battery-stores-electricity-from-renewables-for-days/ar-AAMriqB (accessed July 22, 2021).Google Scholar
Aarhus University, Gridscale: Storing renewable energy in stones instead of batteries, 2021, https://scitechdaily.com/gridscale-storing-renewable-energy-in-stones-instead-of-lithium-batteries (accessed July 22, 2021).Google Scholar
Engineering with Rosie, Thermal energy storage tour with Stiesdal Gridscale battery, 2021, www.youtube.com/watch?v=72wkuIvUISs (accessed July 22, 2021).Google Scholar
Boukhalf, S., and Kaul, N., 10 disruptive battery technologies trying to compete with lithium-ion, 2019, www.solarpowerworldonline.com/2019/01/10-disruptive-battery-technologies-trying-to-compete-with-lithium-ion/ (accessed February 2, 2019).Google Scholar
Wang, Y., Zhou, D., Palomares, V., et al., Revitalizing sodium-sulfur batteries for non-high-temperature operation: a crucial review, Energ. Environ. Sci., 13, 38483879, 2020.Google Scholar
Pilkington, B., Introducing an aluminum-ion battery that charges 60 times faster than lithium, 2021, www.azonano.com/article.aspx?ArticleID=5753 (accessed July 22, 2021).Google Scholar
Nithyanandam, K, and Pitchumani, R., Cost and performance analysis of concentrating solar power systems with integrated latent thermal energy storage, Energy 64, 793810, 2014.CrossRefGoogle Scholar
Denholm, P., Wan, Y.-H., Hummon, M., and Mehos, M., The value of CSP with thermal energy storage in the western United States, Energy Procedia, 49, 16221631, 2014.Google Scholar
Chakratec, Flywheel specifications and comparison, 2019, www.chakratec.com/technology/ (accessed March 18, 2019).Google Scholar
Crossley, I., Simplifying and lightening offshore turbines with compressed air energy storage, Wind Power Monthly, 2018, www.windpowermonthly.com/article/1463030/simplifying-lightening-offshore-turbines-compressed-air-energy-storage (accessed April 11, 2022).Google Scholar
Harrabin, R., How liquid air could help keep the lights on, BBC News, 2019, www.bbc.com/news/business-50140110 (accessed October 30, 2019).Google Scholar
Allain, R., How much energy can you store in a stack of cement blocks, Wired, 2018, www.wired.com/story/battery-built-from-concrete/ (accessed April 10, 2019).Google Scholar
Hanley, S., Energy Vault proposes an energy storage system using concrete blocks, Cleantechnica, 2018, https://cleantechnica.com/2018/08/21/energy-vault-proposes-an-energy-storage-system-using-concrete-blocks/ (accessed April 10, 2019).Google Scholar
Gross, B., Efficiency of gravitational mass storage system, 2019, https://twitter.com/Bill_Gross/status/1164617097927806976/photo/1 (accessed August 22, 2019).Google Scholar
Roberts, D., The train goes up, the train goes down: a simple way to store energy, Vox, 2016, www.vox.com/2016/4/28/11524958/energy-storage-rail (accessed April 10, 2019).Google Scholar
Hunt, J.D., Zakeri, B., Falchetta, G., et al., Mountain gravity energy storage: a new solution for closing the gap between existing short- and long-term storage technologies, Energy, https://doi.org/10.1016/j.energy.2019.116419, 2019.Google Scholar
Holnicki, P., Kaluszko, A., Nahorski, Z., and Tainio, M., Intra-urban variability of the intake fraction from multiple emission sources, Atmos. Pollut. Res., 9, 11841193, 2018.CrossRefGoogle ScholarPubMed
Bistak, S., and Kim, S.Y., AC induction motors vs. permanent magnet synchronous motors, 2017, http://empoweringpumps.com/ac-induction-motors-versus-permanent-magnet-synchronous-motors-fuji/ (accessed January 5, 2018).Google Scholar
Rahman, D., Morgan, A.J., Xu, Y., et al., Design methodology for a planarized high power density EV/HEV traction drive using SiC power modules, IEEE Energy Conversion Congress and Exhibition, Sept. 18–22, 2016, https://doi.org/10.1109/ECCE.2016.7855018 (accessed March 2, 2019).Google Scholar
Evarts, E.C., The world’s largest EV never has to be recharged, Green Car Reports, 2019, www.greencarreports.com/news/1124478_world-s-largest-ev-never-has-to-be-recharged (accessed August 20, 2019).Google Scholar
Wilson, K.A., Worth the Watt: a brief history of the electric car, 1830 to present, 2018, www.caranddriver.com/features/g15378765/worth-the-watt-a-brief-history-of-the-electric-car-1830-to-present/ (accessed July 9, 2021).Google Scholar
Matulka, R., The history of the electric car, 2014, www.energy.gov/articles/history-electric-car (accessed July 9, 2021).Google Scholar
Goodwin, A., Ewing, S., and Hyatt, K., Every electric vehicle on sale in the US for 2021 and its range, 2021, www.cnet.com/roadshow/news/electric-car-ev-range-audi-chevy-ford-tesla/Google Scholar
Tesla, Semi, 2021, www.tesla.com/semi (accessed September 8, 2021).Google Scholar
Grasso Macola, I., Electric ships: the world’s top five projects by battery capacity, 2020, www.ship-technology.com/features/electric-ships-the-world-top-five-projects-by-battery-capacity/ (accessed July 12, 2021).Google Scholar
Wilkerson, J.T., Jacobson, M.Z., Malwitz, A., et al., Analysis of emission data from global commercial aviation: 2004 and 2006, Atmos. Chem. Phys., 10, 63916408, 2010.Google Scholar
Jacobson, M.Z., Wilkerson, J.T., Naiman, A.D., and Lele, S.K., The effects of aircraft on climate and pollution. Part II: 20-year impacts of exhaust from all commercial aircraft worldwide treated individually at the subgrid scale, Faraday Discuss., 165, 369382, https://doi.org/10.1039/C3FD00034F, 2013.Google Scholar
Narishkin, A., and Appolonia, A., Inside a $4 million electric plane, the first full-size all-electric passenger aircraft in the world, 2020, www.businessinsider.com/inside-alice-first-full-size-passenger-electric-plane-eviation-2020-10 (accessed July 13, 2021).Google Scholar
Harvey, L.D.D., Resource implications of alternative strategies for achieving zero greenhouse gas emissions from light-duty vehicles by 2060, Appl. Energy, 212, 663679, 2018.Google Scholar
Petitt, J., Inside Redwood Materials, former Tesla CTO’s effort to recycle batteries for rare components, 2021, www.cnbc.com/2021/04/10/tesla-jb-straubel-redwood-materials-battery-recycling.html (accessed June 23, 2021).Google Scholar
Carpenter, S., Salton Sea is key to CA’s EV future, contains 1/3 of global lithium supply, 2021, https://spectrumnews1.com/ca/la-west/environment/2021/05/27/salton-sea-is-key-to-ca-s-ev-future--contains-1-3-of-global-lithium-supply (accessed June 23, 2021).Google Scholar
Richter, A., Lithium for batteries from the Upper Rhine’s Graben’s geothermal resources, 2020, www.thinkgeoenergy.com/lithium-for-batteries-from-the-upper-rhine-grabens-geothermal-resources/ (accessed June 23, 2021).Google Scholar
Martin, P., Part 3: Lithium and cobalt-risky materials, 2017, www.linkedin.com/pulse/part-3-lithium-cobalt-risky-materials-paul-martin/ (accessed June 23, 2021).Google Scholar
Rai-Roche, S., and Stoker, L., Renewables-plus-storage projects for mining operations in Australia, Madagascar for BHP, Rio Tinto, 2021, www.energy-storage.news/news/renewables-plus-storage-projects-for-mining-operations-in-australia-madagas (accessed August 2, 2021).Google Scholar
Parkinson, G., Potash mine to build wind, solar, and battery micro-grid for most of its power needs, 2021, https://reneweconomy.com.au/potash-mine-to-build-wind-solar-and-battery-micro-grid-for-most-of-its-power-needs/ (accessed September 7, 2021).Google Scholar
Wang, J.-P., Environment-friendly bulk Fe16N2 permanent magnet: review and prospective, J. Magn. Magn. Mater., 497, 165962, https://doi.org/10.1016/j.jmmmm.2019.165962, 2020.Google Scholar
Bloom Energy, Specification Bloom electrolyzer, 2021, www.bloomenergy.com/wp-content/uploads/electrolyzer-data-sheet.pdf (accessed September 9, 2021).Google Scholar
Feng, Z., Stationary high-pressure hydrogen storage, 2018, www.energy.gov/sites/prod/files/2014/03/f10/csd_workshop_7_feng.pdf (accessed November 28, 2018).Google Scholar
Daimler, Fuel-cell truck: start of testing of the new GenH2 truck prototype, 2021, www.daimler.com/innovation/drive-systems/hydrogen/start-of-testing-genh2-truck-prototype.html (accessed June 23, 2021).Google Scholar
Jacobson, M.Z., Effects of wind-powered hydrogen fuel cell vehicles on stratospheric ozone and global climate, Geophys. Res. Lett., 35, L19803, https://doi.org/10.1029/2008GL035102, 2008.Google Scholar
Katalenich, S.M., and Jacobson, M.Z., Toward battery electric and hydrogen fuel cell military vehicles for land, air, and sea, Energy, 254, 124355, https://doi.org/10.1016/j.energy.2022.124355, 2022.Google Scholar
Frangoul, A., Norway’s Statkraft lined up to provide green hydrogen for 88-meter long zero-emission ship, 2021, www.cnbc.com/2021/06/24/statkraft-lined-up-to-provide-green-hydrogen-for-zero-emission-ship.html (accessed July 12, 2021).Google Scholar
Jacobson, M.Z., and Delucchi, M.A., Providing all global energy with wind, water, and solar power, Part I: Technologies, energy resources, quantities and areas of infrastructure, and materials, Energy Policy, 39, 11541169, https://doi.org/10.1016/j.enpol.2010.11.040, 2011.Google Scholar
Werner, S., International review of district heating, Energy, 15, 617631, 2017.Google Scholar
Stagner, J., Stanford University’s “fourth-generation” district energy system, District Energy, Fourth Quarter, 2016, https://sustainable.stanford.edu/sites/default/files/IDEA_Stagner_Stanford_fourth_Gen_DistrictEnergy.pdf (accessed November 27, 2018).Google Scholar
Stagner, J., Efficiency and environmental comparisons, Stanford Energy System Innovations, 2017, https://sustainable.stanford.edu/sites/default/files/SESI_Efficiency_Environmental_Comparisons.pdf, (accessed December 31, 2019).Google Scholar
Cornell University, How lake source cooling works, 2019, https://energyandsustainability.fs.cornell.edu/util/cooling/production/lsc/works.cfm (accessed May 1, 2019).Google Scholar
IRENA (International Renewable Energy Agency), Thermal energy storage. IEA-ETSAP and IRENA Technology Brief E17, IRENA, Abu Dhabi, 2013.Google Scholar
Sibbitt, B, McClenahan, D., Djebbar, R., et al., The performance of a high solar fraction seasonal storage district heating system – five years of operation, Energy Procedia, 30, 856865, 2012.CrossRefGoogle Scholar
Sorensen, P.A., and Schmidt, T., Design and construction of large scale heat storages for district heating in Denmark, 14th Int. Conf. on Energy Storage, April 25–28, Adana, Turkey, 2018, http://planenergi.dk/wp-content/uploads/2018/05/Soerensen-and-Schmidt_Design-and-Construction-of-Large-Scale-Heat-Storages-12.03.2018-004.pdf (accessed November 25, 2018).Google Scholar
Arcon/Sunmark, Large-scale showcase projects, 2017, http://arcon-sunmark.com/uploads/ARCON_References.pdf (accessed November 25, 2018).Google Scholar
Damkjaer, L., Gram Fjernvarme 2016, 2016, www.youtube.com/watch?v=PdF8e1t7St8 (accessed November 25, 2018).Google Scholar
Ramboll, Pit thermal energy storage: update from Toftlund, 2020, www.heatstore.eu/documents/20201028_DK-temadag_Rambøll%20PTES%20project.pdf (accessed July 21, 2021).Google Scholar
International Energy Agency, Integrated cost-effective large-scale thermal energy storage for smart district heating and cooling, 2018, www.iea-dhc.org/fileadmin/documents/Annex_XII/IEA_DHC_AXII_Design_Aspects_for_Large_Scale_ATES_PTES_draft.pdf (accessed November 25, 2018).Google Scholar
Butti, K., and Perlin, J., Solar Water Heaters in California, California Energy Commission, 1980.Google Scholar
Dandelion, Geothermal heating and air conditioning is so efficient, it pays for itself, https://dandelionenergy.com, 2018 (accessed November 17, 2018).Google Scholar
Meyers, S., Franco, V., Lekov, A., Thompson, L., and Sturges, A., Do heat pump clothes dryers makes sense for the U.S. market? ACEEE Summer Study on Energy Efficiency in Buildings, 9-240–9-251, 2010, https://aceee.org/files/proceedings/2010/data/papers/2224.pdf (accessed October 29, 2019).Google Scholar
Fischer, D., and Madani, H., On heat pumps in smart grids: a review. Renew. Sustain. Energ. Rev., 70, 342357, 2017.Google Scholar
De Gracia, A., and Cabeza, L.F., Phase change materials and thermal energy storage for buildings, Energy Build., 103, 414419, 2015.Google Scholar
Consumer Reports, Electric lawn mowers that rival gas models, 2017, www.consumerreports.org/push-mowers/electric-lawn-mowers-that-rival-gas-models/ (accessed November 21, 2018).Google Scholar
BONE Structure, https://bonestructure.ca/en/ (accessed December 26, 2021).Google Scholar
U.S. Department of Energy, Quadrennial Technology Review, Chapter 6: Innovative clean energy technologies in advanced manufacturing: Technology assessment, 2015, www.energy.gov/sites/prod/files/2016/06/f32/QTR2015-6I-Process-Heating.pdf (accessed Nov. 17, 2018).Google Scholar
Bellevrat, E., and West, K., Clean and efficient heat for industry, 2018, www.iea.org/newsroom/news/2018/january/commentary-clean-and-efficient-heat-for-industry.html (accessed November 17, 2018).Google Scholar
Barber, H., Chapter 7, Electric heating fundamentals. In: The Efficient Use of Energy, 2nd ed., pp. 94114, Dryden, I.G.C., ed., Butterworth-Heinemann, https://doi.org/10.1016/B978-0-408-01250-8.50016-7, 1982.Google Scholar
Hulls, P.J., Development of the industrial use of dielectric heating in the United Kingdom, J. Microw. Power, 17, 2838, 2016.Google Scholar
Ramaiah, R., and Shekar, K.S.S., Solar thermal energy utilization for medium temperature industrial process heat applications, IOP Conf. Ser. Mater. Sci. Eng., 376, 010235, 2018.Google Scholar
Vogl, V., Ahman, M., and Nilsson, L.J., Assessment of hydrogen direct reduction for fossil-free steelmaking, J. Clean. Prod., 203, 736745, 2018.Google Scholar
Allanore, A., Yin, L., and Sadoway, D., A new anode material for oxygen evolution in molten oxide electrolysis, Nature, 497, 353356, 2013.Google Scholar
Wiencke, J., Lavelaine, H., Panteix, P.-J., Petijean, C., and Rapin, C., Electrolysis of iron in a molten oxide electrolyte, J. Appl. Electrochem., 48, 115126, 2018.Google Scholar
Andrew, R.M., Global CO2 emissions from cement production, 1928–2018, Earth System Science Data, 2019, https://doi.org/10.5194/essd-2019-152.Google Scholar
Choate, W.T., Energy and emission reduction opportunities for the cement industry, 2003, www1.eere.energy.gov/manufacturing/industries_technologies/imf/pdfs/eeroci_dec03a.pdf (accessed July 21, 2021).Google Scholar
Singh, N.B., Kumar, M., and Rai, S., Geopolymer cement and concrete: properties, Mater. Today Proc., 29, 743748, 2020.Google Scholar
Stone, D., Ferrock basics, 2017, http://ironkast.com/wp-content/uploads/2017/11/Ferrock-basics.pdf (accessed November 20, 2018).Google Scholar
Build Abroad, Ferrock: a stronger, more flexible and greener alternative to concrete, 2016, https://buildabroad.org/2016/09/27/ferrock/ (accessed November 20, 2018).Google Scholar
Carbon Cure, Carbon Cure, 2018, www.carboncure.com (accessed November 20, 2018).Google Scholar
Maldonado, S., The importance of new “sand-to-silicon” processes for the rapid future increase of photovoltaics, ACS Energy Lett., 5, 36283632, 2020.Google Scholar
Dong, Y., Slade, T., Stolt, M.J., et al., Low-temperature molten salt production of silicon nanowires by the electrochemical reduction of CaSiO3, Angew. Chem., 56, 1445314457, 2017.Google Scholar
Jacobson, M.Z., The short-term cooling but long-term global warming due to biomass burning, J. Clim., 17, 29092926, 2004.Google Scholar
Colella, W.G., Jacobson, M.Z., and Golden, D.M., Switching to a U.S. hydrogen fuel cell vehicle fleet: the resultant change in emissions, energy use, and global warming gases, J. Power Sources, 150, 150181, 2005.Google Scholar
Howarth, R.W., and Jacobson, M.Z., How green is blue hydrogen? Energy Sci. Eng., 9, 16761687, 2021, https://doi.org/10.1002/ese3.956.Google Scholar
Ussiri, D., and Lal, R., Global Sources of Nitrous Oxide. In: Soil Emission of Nitrous Oxide and Its Mitigation, Springer, pp. 131175, 2012.Google Scholar
Nitric Acid Climate Action Group, Nitrous oxide emissions from nitric acid production, 2014, www.nitricacidaction.org/about/nitrous-oxide-emissions-from-nitric-acid-production/ (accessed December 1, 2018).Google Scholar
Boiocchi, R., Gemaey, K.V., and Sin, G., Control of wastewater N2O emission by balancing the microbial communities using a fuzzy-logic approach, IFAC-PapersOnLine, 49, 11571162, 2016.Google Scholar
Santin, I., Barbu, M., Pedret, C., and Vilanova, R., Control strategies for nitrous oxide emissions reduction on wastewater treatment plants operation, Water Res., 125, 466477, 2017.Google Scholar
Hong, S., Candelone, J.-P., Patterson, C.C., and Boutron, C.F., Greenland ice evidence of hemispheric lead pollution two millennia ago by Greek and Roman civilizations, Science, 265, 18411843, 1994.CrossRefGoogle ScholarPubMed
Nriagu, J.O., A history of global metal pollution, Science, 272, 223224, 1996.Google Scholar
Hong, S., Candelone, J.-P., Patterson, C.C., and Boutron, C.F., History of ancient copper smelting pollution during Roman and Medieval times recorded in Greenland ice, Science, 272, 246248, 1996.Google Scholar
Brimblecombe, P., Air pollution and health history. In Air Pollution and Health, Holgate, S.T., Samet, J.M., Koren, H.S., and Maynard, R.L., eds., Academic, pp. 518, 1999.Google Scholar
Hughes, J.D., Pan’s Travail: Environmental Problems of the Ancient Greeks and Romans, The Johns Hopkins University Press, 1994.Google Scholar
Brimblecombe, P., The Big Smoke, Methuen, 1987.Google Scholar
McNeill, J.R., Something New Under the Sun, W. W. Norton & Company Ltd., 2000.Google Scholar
Rosenberg, N., and Birdzell, L. E., Jr., How the West Grew Rich, Basic Books, Inc., 1986.Google Scholar
Union Gas, Chemical composition of natural gas, 2018, www.uniongas.com/about-us/about-natural-gas/chemical-composition-of-natural-gas (accessed December 5, 2018).Google Scholar
De Boer, J.Z., Hale, J.R., and Chanton, J., New evidence of the geological origins of the ancient Delphic oracle (Greece), Geology, 29, 707710, 2001.2.0.CO;2>CrossRefGoogle Scholar
Intergovernmental Panel on Climate Change, Special Report: Global Warming of 1.5°, 2018, www.ipcc.ch/sr15/ (accessed June 26, 2019).Google Scholar
Jacobson, M.Z., Review of solutions to global warming, air pollution, and energy security, Energy Environ. Sci., 2, 148173, https://doi.org/10.1039/b809990c, 2009.Google Scholar
Frangoul, A., Scandinavia’s biggest offshore wind farm is officially open, 2019, www.cnbc.com/2019/08/23/scandinavias-biggest-offshore-wind-farm-is-officially-open.html?__source=sharebar%7Ctwitter&par=sharebar (accessed July 12, 2021).Google Scholar
Jacobson, M.Z., and Archer, C.L., Saturation wind power potential and its implications for wind energy, Proc. Natl Acad. Sci., 109, 1567915684, https://doi.org/10.1073/pnas.1208993109, 2012.Google Scholar
Jacobson, M.Z., Delucchi, M.A., Cameron, M.A., and Mathiesen, B.V., Matching demand with supply at low cost among 139 countries within 20 world regions with 100 percent intermittent wind, water, and sunlight (WWS) for all purposes, Renewable Energy, 123, 236248, 2018.Google Scholar
Intergovernmental Panel on Climate Change, IPCC Special Report on Carbon Dioxide Capture and Storage. Prepared by Working Group III, Metz, B., Davidson, O., de Coninck, H. C., Loos, M., and Meyer, L.A., eds., Cambridge University Press, http://arch.rivm.nl/env/int/ipcc/, 2005 (accessed June 26, 2019).Google Scholar
U.S. Energy Information Administration, Hydraulically fractured wells provide two-thirds of U.S. natural gas production, 2016, www.eia.gov/todayinenergy/detail.php?id=26112 (accessed December 2, 2018).Google Scholar
Howarth, R.W., Santoro, R., and Ingraffea, A., Methane and the greenhouse gas footprint of natural gas from shale formations, Clim. Change, 106, 679690, 2011.Google Scholar
Howarth, R.W., Is shale gas a major driver of recent increase in global atmospheric methane? Biogeosciences, 16, 30333046, 2019.Google Scholar
Alvarez, R.A., Zavalao-Araiza, D., Lyon, D.R. et al., Assessment of methane emissions from the U.S. oil and gas supply chain, Science, 361, 186188, 2018.Google Scholar
Schneising, O., Buchwitz, M., Reuter, M., et al., Remote sensing of methane leakage from natural gas and petroleum systems revisited, Atmos. Chem. Phys., 20, 91699182, 2020.Google Scholar
Massachusetts Institute of Technology, The Future of Natural Gas, 2011, https://energy.mit.edu/wp-content/uploads/2011/06/MITEI-The-Future-of-Natural-Gas.pdf (accessed December 2, 2018).Google Scholar
U.S. Environmental Protection Agency, 2008 U.S. National Emissions Inventory (NEI), 2011, www.epa.gov/air-emissions-inventories/2008-national-emissions-inventory-nei-data (accessed December 2, 2018).Google Scholar
Jacobson, M.Z., Delucchi, M.A., Bazouin, G., et al., 100 percent clean and renewable wind, water, sunlight (WWS) all-sector energy roadmaps for the 50 United States, Energy Environ. Sci., 8, 20932117, https://doi.org/10.1039/C5EE01283J, 2015.Google Scholar
Geuss, M., Florida utility to close natural gas plants, build massive solar-powered battery, Ars Technica, 2019, https://arstechnica.com/information-technology/2019/03/florida-utility-to-close-natural-gas-plants-build-massive-solar-powered-battery/ (accessed April 1, 2019).Google Scholar
Allred, B.W., Smith, W.K., Twidwell, D., et al., Ecosystem services lost to oil and gas in North America, Science, 348, 401402, 2015.Google Scholar
Reuters, Special Report: Millions of abandoned oil wells are leaking methane, a climate menace, 2020, www.reuters.com/article/us-usa-drilling-abandoned-specialreport/special-report-millions-of-abandoned-oil-wells-are-leaking-methane-a-climate-menace-idUSKBN23N1NL (accessed September 6, 2020).Google Scholar
Jacobson, M.Z., Short-term impacts of the Aliso Canyon natural gas blowout on weather, climate, air quality, and health in California and Los Angeles, Environ. Sci. Technol., 53, 60816093, https://doi.org/10.1021/acs.est.9b01495, 2019.Google Scholar
Jaramillo, P., Griffin, W.M., and McCoy, S.T., Life cycle inventory of CO2 in an enhanced oil recovery system, Environ. Sci. Technol., 43, 80278032, 2009.Google Scholar
Roberts, D., Turns out the world’s first “clean coal” plant is a backdoor subsidy to oil producers, 2015, https://grist.org/climate-energy/turns-out-the-worlds-first-clean-coal-plant-is-a-backdoor-subsidy-to-oil-producers/ (accessed September 7, 2021).Google Scholar
Government of Alberta, Quest CO2 Capture Ratio Performance, Quest Carbon Capture and Storage (CCS) Project, Government of Alberta, Edmonton, Alberta, 2020, https://open.alberta.ca/dataset/f74375f3-3c73-4b9c-af2b-ef44e59b7890/resource/c36cf890-3b27-4e7e-b95b-3370cd0d9f7d/download/energy-quest-co2-capture-ratio-performance-2019.pdf (accessed July 16, 2021).Google Scholar
U.S. Department of Energy, W.A. Parish post-combustion CO2 capture and sequestration demonstration project, Final Scientific and Technical Report, Project DE-FE0003311, 2020, www.osti.gov/servlets/purl/1608572 (accessed July 16, 2021).Google Scholar
Jacobson, M.Z., The health and climate impacts of carbon capture and direct air capture, Energy Environ. Sci., 12, 35673574, https://doi.org/10.1039/C9EE02709B, 2019.Google Scholar
Schlissel, D., Boundary Dam 3 coal plant achieves goal of capturing 4 million metric tons of CO2 but reaches the goal two years late, 2021, http://ieefa.org/wp-content/uploads/2021/04/Boundary-Dam-3-Coal-Plant-Achieves-CO2-Capture-Goal-Two-Years-Late_April-2021.pdf (accessed July 12, 2021).Google Scholar
Morton, A., “A shocking failure”: Chevron criticized for missing carbon capture target at WA gas project, 2021, www.theguardian.com/environment/2021/jul/20/a-shocking-failure-chevron-criticised-for-missing-carbon-capture-target-at-wa-gas-project (accessed August 3, 2021).Google Scholar
U.S. Energy Information Administration, Today in energy, 2017, www.eia.gov/todayinenergy/detail.php?id=33552 (accessed December 4, 2018).Google Scholar
ScottMadden, Billion dollar Petra Nova coal carbon capture project a financial success but unclear if it can be replicated, 2017, www.scottmadden.com/insight/billion-dollar-petra-nova-coal-carbon-capture-project-financial-success-unclear-can-replicated/ (accessed December 3, 2018).Google Scholar
Karam, P.A., How do fast breeder reactors differ from regular nuclear power plants? Sci. Am., October 2006.Google Scholar
IAEA (International Atomic Energy Agency), World’s uranium resources enough for foreseeable future says NEA and IAEA in new report, 2021, www.iaea.org/newscenter/pressreleases/worlds-uranium-resources-enough-for-the-foreseeable-future-say-nea-and-iaea-in-new-report (accessed August 5, 2021).Google Scholar
Lazard’s levelized cost of energy analysis – Version 15.0, 2021, www.lazard.com/media/451881/lazards-levelized-cost-of-energy-version-150-vf.pdf (accessed November 1, 2021).Google Scholar
Koomey, J., and Hultman, N.E., A reactor-level analysis of busbar costs for U.S. nuclear plants, 1970–2005, Energy Policy 35, 56305642, 2007.Google Scholar
Berthelemy, M., and Rengel, L.E., Nuclear reactors’ construction costs: The role of lead-time, standardization, and technological progress, Energy Policy, 82, 118130, 2015.Google Scholar
Morris, C., French nuclear power history – the unknown story, 2015, https://energytransition.org/2015/03/french-nuclear-power-history/ (accessed June 16, 2019).Google Scholar
Bruckner, T., Bashmakov, I.A., Mulugetta, Y., et al., Energy Systems. In: Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change, Edenhofer, O., Pichs-Madruga, R., Sokona, Y., et al., eds., Cambridge University Press, 2014.Google Scholar
Garthwaite, J., What should we do with nuclear waste? Stanford Earth, 2018, https://earth.stanford.edu/news/qa-what-should-we-do-nuclear-waste#gs.1sfx0x (accessed March 20, 2019).Google Scholar
Ten Hoeve, J.E., and Jacobson, M.Z., Worldwide health effects of the Fukushima Daiichi nuclear accident, Energy Environ. Sci., 5, 87438757, 2012.Google Scholar
Denyer, S., Eight years after Fukushima’s meltdown, the land is recovering, but public trust is not, Washington Post, 2019, www.washingtonpost.com/world/asia_pacific/eight-years-after-fukushimas-meltdown-the-land-is-recovering-but-public-trust-has-not/2019/02/19/0bb29756-255d-11e9-b5b4-1d18dfb7b084_story.html?utm_term=.8344c816d5bb (accessed December 21, 2019).Google Scholar
Cebulla, F., and Jacobson, M.Z., Alternative renewable energy scenarios for New York, J. Cleaner Prod., 205, 884894, 2018.Google Scholar
De Coninck, H., Revi, A., Babiker, M., et al., Chapter 4: Strengthening and Implementing the Global Response. In Special Report: Global Warming of 1.5°, Intergovernmental Panel on Climate Change, 2018.Google Scholar
Fuhrmann, M., Spreading temptation: proliferation and peaceful nuclear cooperation agreements (March 9, 2009). Int. Secur., 34, Summer 2009. Available at SSRN: https://ssrn.com/abstract=1356091 (accessed September 9, 2019).Google Scholar
IranWatch, Iran’s nuclear potential before the implementation of the nuclear agreement, 2015, www.iranwatch.org/our-publications/articles-reports/irans-nuclear-timetable (accessed December 9, 2018).Google Scholar
Johnson, G., When radiation isn’t the real risk, New York Times, 2015, www.nytimes.com/2015/09/22/science/when-radiation-isnt-the-real-risk.html (accessed December 8, 2018).Google Scholar
BBC News, Japan confirms first Fukushima worker death from radiation, 2018, www.bbc.com/news/world-asia-45423575 (accessed June 9, 2019).Google Scholar
Henshaw, D.L., Eatough, J.P., and Richardson, R.B., Radon as a causative factor in induction of myeloid leukemia and other cancers, Lancet, 335, 10081012, 1990.Google Scholar
Lagarde, F., Pershagen, G., Akerblom, G., et al., Residential radon and lung cancer in Sweden: risk analysis accounting for random error in the exposure assessment, Health Physics, 72, 269276, 1997.Google Scholar
Center for Disease Control and Prevention, Research on long-term exposure: Uranium miners, 2000, www.cdc.gov/niosh/pgms/worknotify/uranium.html (accessed December 9, 2018).Google Scholar
Hampson, S.E., Andres, J.A., Lee, M.E., et al., Lay understanding of synergistic risk: the case of radon and cigarette smoking, Risk Analysis, 18, 343350, 1998.Google Scholar
Kadiyala, A., Kommalapati, R., and Huque, Z., Evaluation of the lifecycle greenhouse gas emissions from different biomass feedstock electricity generation systems, Sustainability, 8, 11811192, 2016.Google Scholar
Jacobson, M.Z., Effects of ethanol (E85) versus gasoline vehicles on cancer and mortality in the United States, Environ. Sci. Technol., 41, 41504157, https://doi.org/10.1021/es062085v, 2007.Google Scholar
Ginnebaugh, D.L., Liang, J., and Jacobson, M.Z., Examining the temperature dependence of ethanol (E85) versus gasoline emissions on air pollution with a largely-explicit chemical mechanism, Atmos. Environ., 44, 11921199, https://doi.org/10.1016/j.atmosenv.2009.12.024, 2010.Google Scholar
Ginnebaugh, D.L., and Jacobson, M.Z., Examining the impacts of ethanol (E85) versus gasoline photochemical production of smog in a fog using near-explicit gas- and aqueous-chemistry mechanisms, Environ. Res. Lett., 7, 045901, https://doi.org/10.1088/1748-9326/7/4/045901, 2012.Google Scholar
Searchinger, T., Heimlich, R., Houghton, R.A., et al., Use of U.S. cropland for biofuels increases greenhouse gases through emissions from land-use change, Science, 319, 12381240, 2008.Google Scholar
Delucchi, M., A conceptual framework for estimating the climate impacts of land-use change due to energy crop programs, Biomass Bioenergy, 35, 23372360, 2011.CrossRefGoogle Scholar
Chen, W.-H., Lin, M.-R., Lu, J.-J., Chao, Y., and Leu, T.-S., Thermodynamic analysis of hydrogen production from methane via autothermal reforming and partial oxidation followed by water gas shift reaction, Int. J. Hyd. Energy, 35, 11,787–11,797, 2010.Google Scholar
U.S. Drive, Hydrogen production tech team roadmap, 2017, www.energy.gov/sites/prod/files/2017/11/f46/HPTT%20Roadmap%20FY17%20Final_Nov%202017.pdf (accessed August 25, 2021).Google Scholar
Duan, Y., and Sorescu, D.C., CO2 capture properties of alkaline earth metal oxides and hydroxides: a combined density functional theory and lattice phonom dynamics study, J. Chem. Phys., 133, 074508, 2010.Google Scholar
Jacobson, M.Z., and Ten Hoeve, J.E., Effects of urban surfaces and white roofs on global and regional climate, J. Clim., 25, 10281044, https://doi.org/10.1175/JCLI-D-11-00032.1, 2012.Google Scholar
King, G., Edison vs. Westinghouse: a shocking rivalry, Smithsonian Mag., 2011, www.smithsonianmag.com/history/edison-vs-westinghouse-a-shocking-rivalry-102146036/ (accessed July 28, 2021).Google Scholar
Sadovskaia, K., Bogdanov, D., Honkapuro, S., and Breyer, C., Power transmission and distribution loses – a model based on available empirical data and future trends for all countries globally, Int J. Electr. Power Energy Syst., 107, 98109, 2019.Google Scholar
International Electrotechnical Commission, Efficient electrical energy transmission and distribution, 2007, https://basecamp.iec.ch/download/efficient-electrical-energy-transmission-and-distribution (accessed December 31, 2018).Google Scholar
ABB, HVDC technology for energy efficiency and grid reliability, 2005, www02.abb.com/global/abbzh/abbzh250.nsf/0/27c2fdbd96a879a4c12575ee00487a77/$file/HVDC+-+efficiency+and+reliability.pdf (accessed December 31, 2018).Google Scholar
World Bank, Electric power transmission and distribution losses (% of output), 2018, https://data.worldbank.org/indicator/EG.ELC.LOSS.ZS?end=2014&start=2009 (accessed January 1, 2019).Google Scholar
Becquerel, A.E., Memoire sur les effects d’electriques produits soul l’influence des rayons solairee, Annal. Phys. Chem., 54, 3542, 1841.Google Scholar
Adams, W.G., and Day, R.E., The action of light on selenium, Proc. R. Soc. Lond., A25, 113, 1877.Google Scholar
Fritts, C.E., On a new form of selenium photocell, Am. J. Sci., 26, 465, 1883.Google Scholar
Siemens, W., On the electromotive action of illuminated selenium, discovered by Mr. Fritts of New York, Van Nostrands Engineering Magazine, 32, 514516, 1885.Google Scholar
Grondahl, L.O., The copper-cuprous-oxide rectifier and photoelectric cell, Rev. Mod. Phys., 5, 141, 1933.Google Scholar
Green, M.A., Dunlop, E., Hohl-Ebinger, J., et al., Solar cell efficiency tables (Version 58), Prog. Photovolt., https://doi.org/10.1002/pip.3444, 2021.Google Scholar
Bremner, S.P., Levy, M.Y., and Honsberg, C.B., Analysis of tandem solar cell efficiencies under {AM1.5G} spectrum using a rapid flux calculation method, Prog. Photovolt. Res. Appl., 16, 225233, 2008.Google Scholar
Breyer, C., Economics of Hybrid Photovoltaic Power Plants, Pro Business, 2012.Google Scholar
Jacobson, M.Z., Jadhav, V., World estimates of PV optimal tilt angles and ratios of sunlight incident upon tilted and tracked PV panels relative to horizontal panels, Solar Energy, 169, 5566, 2018.Google Scholar
U.S. Department of Energy, How do wind turbines work? 2019, www.energy.gov/eere/wind/wind-energy-technologies-office (accessed March 27, 2019).Google Scholar
Pavel, C.C., Lacal-Arantegui, R., Marmier, A., et al., Substitution strategies for reducing the use of rare earths in wind turbines, Resources Policy, 52, 349357, 2017.Google Scholar
Green Car Congress, Niron Magnetics raises $21.3M to commercialize rare-earth-free iron-nitride magnets, 2021, www.greencarcongress.com/2021/07/20210730-niron.html (accessed October 25, 2021).Google Scholar
Pires, O., Munduate, X., Ceyhan, O., Jacobs, M., and Snel, H., Analysis of high Reynolds numbers effects on a wind turbine airfoil using 2D wind tunnel test data, J. Phys. Conf. Series 753, 022047, 2016.Google Scholar
Schubel, P.J., and Crossley, R.J., Wind turbine blade design, Energies, 5, 34253449, 2012.Google Scholar
Hu, S.-y., and Cheng, J.-h., Performance evaluation of pairing between sites and wind turbines, Renewable Energy, 32, 19341947, 2007.Google Scholar
Sirnivas, S., Musial, W., Bailey, B., and Filippelli, M., Assessment of offshore wind system design, safety, and operation standards, NREL/TP-5000-60573, 2014.Google Scholar
Wiser, R., Bolinger, M., Hoen, B., et al., Land-based wind market report: 2021 edition, U.S. Department of Energy, 2021, www.energy.gov/eere/wind/articles/land-based-wind-market-report-2021-edition-released (accessed December 6, 2021).Google Scholar
Faulstich, S., Hahn, B., and Tavner, P.J., Wind turbine downtime and its importance for offshore deployment, Wind Energy, 14, 327337, 2011.Google Scholar
Zhang, J., Chowdhury, S., and Zhang, J., Optimal preventative maintenance time windows for offshore wind farms subject to wake losses, AIAA 2012–5435, 2012.Google Scholar
Monitoring Analytics, Quarterly state of the market report for PJM: January through June, 2015, www.monitoringanalytics.com/reports/PJM_State_of_the_Market/2015/2015q2-som-pjm-sec5.pdf (accessed January 19, 2019).Google Scholar
Enevoldsen, P., and Jacobson, M.Z., Data investigation of installed and output power densities of onshore and offshore wind turbines worldwide, Energy Sustain. Dev., 60, 4051, 2021.CrossRefGoogle Scholar
Zhou, L., Tian, Y., Roy, S.B., et al., Impacts of wind farms on land surface temperature, Nat. Clim. Change 2, 539543, 2012.Google Scholar
Jacobson, M.Z., Archer, C.L., and Kempton, W., Taming hurricanes with arrays of offshore wind turbines, Nat. Clim. Change, 4, 195200, https://doi.org/10.1038/NCLIMATE2120, 2014.Google Scholar
American Bird Conservancy, https://abcbirds.org 2019 (accessed January 4, 2019).Google Scholar
Sovacool, B.K., Contextualizing avian mortality: a preliminary appraisal of bird and bat fatalities from wind, fossil-fuel, and nuclear electricity, Energy Policy, 37, 22412248, 2009.Google Scholar
National Wind Coordinating Collaborative, Wind turbine interactions with birds, bats, and their habitats, 2010, www1.eere.energy.gov/wind/pdfs/birds_and_bats_fact_sheet.pdf (accessed January 4, 2018).Google Scholar
Smallwood, K.S., Comparing bird and bat fatality rate estimates among North American wind energy projects, Wildlife Society Bulletin, 37, 1933, 2013.Google Scholar
May, R., Nygard, T., Falkdalen, U., et al., Paint it black: efficacy of increased wind turbine rotor blade visibility to reduce avian fatalities, Ecology and Evolution, 10, 89278935, 2020.Google Scholar
Jacobson, M.Z., Delucchi, M.A., Bauer, Z.A.F., et al., 100 percent clean and renewable wind, water, and sunlight (WWS) all-sector energy roadmaps for 139 countries of the world, Joule, 1, 108121, https://doi.org/10.1016/j.joule.2017.07.005, 2017.Google Scholar
von Krauland, A.-K., Permien, F.-H., Enevoldsen, P., and Jacobson, M.Z., Onshore wind energy atlas for the United States accounting for land use restrictions and wind speed thresholds, Smart Energy, 3, 100046, https://doi.org/10.1016/j.segy.2021.100046, 2021.Google Scholar
Moore, M.A., Boardman, A.E., Vining, A.R., Weimer, D.L., and Greenberg, D.H., Just give me a number! Practical values for the social discount rate, J. Policy Anal. Manage. 23, 789812, 2004.Google Scholar
National Center for Environmental Economics, Guidelines for Preparing Economic Analyses, U.S. Environmental Protection Agency, 2014.Google Scholar
U.S. Office of Management and Budget, Circular A-4, Regulatory Analysis, The White House, Washington D.C., September 17, 2003, www.whitehouse.gov/sites/whitehouse.gov/files/omb/circulars/A4/a-4.pdf (accessed January 16, 2019).Google Scholar
Drupp, M., Freeman, M., Groom, B., and Nesje, F., Discounting disentangled: an expert survey on the determinants of the long-term social discount rate. The Centre for Climate Change Economics and Policy Working Paper No. 195 and Grantham Research Institute on Climate Change and the Environment Working Paper No. 172, 2015.Google Scholar
Moore, C., Brown, S., Alparslan, U., Cremona, E., and Alster, G., European electricity review: 6-month update H1-2021, Ember, 2021, https://ember-climate.org/app/uploads/2022/02/European-Electricity-Review-H1-2021.pdf (accessed July 28, 2021).Google Scholar
Batjer, M., Berberich, S., and Hochschild, D. (2020), Letter to Governor Gavin Newsom, www.gov.ca.gov/wp-content/uploads/2020/08/8.17.20-Letter-to-CAISO-PUC-and-CEC.pdf (accessed July 23, 2021).Google Scholar
Swenson, A., and Lajka, A., Texas blackouts fuel false claims about renewable energy, 2021, https://apnews.com/article/false-claims-texas-blackout-wind-turbine-f9e24976e9723021bec21f9a68afe927 (accessed July 23, 2021).Google Scholar
International Energy Agency, Data and statistics, 2021, www.iea.org/statistics/ (accessed July 23, 2021).Google Scholar
Kuhudzai, R.J., Renewables provided 92.3% of Kenya’s electricity generation in 2020, Cleantechnica, 2021, https://cleantechnica.com/2021/11/04/renewables-provided-92-3-of-kenyas-electricity-generation-in-2020/ (accessed November 18, 2021).Google Scholar
Cockburn, H., Scotland generating enough wind energy to power two Scotlands, 2019, www.independent.co.uk/environment/scotland-wind-power-on-shore-renewable-energy-climate-change-uk-a9013066.html (accessed July 26, 2019).Google Scholar
Renewables Now, Chile’s Coquimbo region nears 100% renewables share in H1 2019, 2019, https://renewablesnow.com/news/chiles-coquimbo-region-nears-100-renewables-share-in-h1-2019-663136/ (accessed July 26, 2019).Google Scholar
Vorrath, S., South Australia sets smashing new renewables record in final days of 2021, Renew Economy, 2022, https://reneweconomy.com.au/south-australia-winds-up-2021-with-smashing-new-renewables-record/ (accessed January 12, 2022).Google Scholar
Energy Information Administration, Renewables became the second-most prevalent U.S. electricity source in 2020, 2021, www.eia.gov/todayinenergy/detail.php?id=48896 (accessed July 28, 2021).Google Scholar
Linnerud, K., Mideksa, T., and Eskeland, G.S., The impact of climate change on nuclear power supply, Energy J., 32, 149168, 2011.Google Scholar
Ahmad, A., Increase in frequency of nuclear power outages due to climate change, Nat. Energy, 6, 755762, 2021.Google Scholar
Elliott, D., Schwartz, M., and Scott, G., Wind Resource Base, Encyclopedia of Energy, 465479, Elsevier, 2004.Google Scholar
Jacobson, M.Z., and Kaufmann, Y.J., Wind reduction by aerosol particles, Geophys. Res. Lett., 33, L24814, 2006.Google Scholar
Pryor, S.C., Barthelmie, R.J., Bukovsky, MS., Leung, L.R., and Sakaguchi, K., Climate change impacts on wind power generation, Nat. Rev. Earth Environ., 1, 627643, 2020.Google Scholar
Beyer, H.G., and Niclasen, B.A., Assessment of the option ‘wind power to heat for buildings’ with respect to meteorological conditions, Meteorol. Z., 28, 7985, 2019.Google Scholar
Jacobson, M.Z., On the correlation between building heat demand and wind energy supply and how it helps to avoid blackouts, Smart Energy, 1, 100009, https://doi.org/10.1016/j.segy.2021.100009, 2021Google Scholar
Kahn, E., The reliability of distributed wind generators, Electr. Power Syst. Res., 2, 114, 1979.Google Scholar
Archer, C.L., and Jacobson, M.Z., Spatial and temporal distributions of U.S. winds and wind power at 80 m derived from measurements, J. Geophys. Res., 108, 4289, 2003.Google Scholar
Archer, C.L., and Jacobson, M.Z., Supplying baseload power and reducing transmission requirements by interconnecting wind farms, J. Appl. Meteorol. Climatol., 46, 17011717, https://doi.org/10.1175/2007JAMC1538.1, 2007.Google Scholar
Stoutenburg, E.D., Jenkins, N., and Jacobson, M.Z., Power output variations of co-located offshore wind turbines and wave energy converters in California, Renew. Energy, 35, 27812791, https://doi.org/10.1016/j.renene.2010.04.033, 2010.Google Scholar
Stoutenburg, E.K., and Jacobson, M.Z., Reducing offshore transmission requirements by combining offshore wind and wave farms, IEEE J. Ocean. Eng., 36, 552561, https://doi.org/10.1109/JOE.2011.2167198, 2011.Google Scholar
Jacobson, M.Z., von Krauland, A.-K., Coughlin, S.J., Palmer, F.C., and Smith, M.M., Zero air pollution and zero carbon from all energy at low cost and without blackouts in variable weather throughout the U.S. with 100% wind-water-solar (WWS) and storage, Renew. Energy, 184, 430444, 2022.Google Scholar
Jacobson, M.Z., The cost of grid stability with 100% clean, renewable energy for all purposes when countries are islanded versus interconnected, Renew. Energy, 179, 10651075, 2021.Google Scholar
Kempton, W., and Tomic, J., Vehicle-to-grid power fundamentals: calculating capacity and net revenue, J. Power Sources, 144, 268279, 2005.Google Scholar
Kempton, W., and Tomic, J., Vehicle-to-grid power implementation: from stabilizing the grid to supporting large-scale renewable energy, J. Power Sources, 144, 280294, 2005.Google Scholar
Budischak, C., Sewell, D., Thompson, H., et al., Cost-minimized combinations of wind power, solar power, and electrochemical storage, powering the grid up to 99.9% of the time, J Power Sources, 225, 6074, 2013.Google Scholar
Child, M., Nordling, A., and Breyer, C., The impacts of high V2G participation in a 100% renewable Aland energy system, Energies, 11, 2206, https://doi.org/10.3390/en11092206, 2018.Google Scholar
Hart, E.K., and Jacobson, M.Z., A Monte Carlo approach to generator portfolio planning and carbon emissions assessments of systems with large penetrations of variable renewables, Renew. Energy, 36, 22782286, https://doi.org/10.1016/j.renene.2011.01.015, 2011.Google Scholar
Kirby, B.J., Frequency regulation basics and trends, ORNL/TM-2004/291, 2004, www.consultkirby.com/files/TM2004-291_Frequency_Regulation_Basics_and_Trends.pdf (accessed January 28, 2019).Google Scholar
U.S. National Research Council, Real Prospects for Energy Efficiency in the United States, National Academies Press, p. 251, www.nap.edu/read/12621/chapter/6#251, 2010 (accessed February 2, 2019).Google Scholar
Erlich, I., and Wilch, M., Frequency control by wind turbines, IEEE PES General Meeting, July 25–29, 2010, https://doi.org/10.1109/PES.2010.5589911, https://ieeexplore.ieee.org/document/5589911 (accessed March 2, 2019).Google Scholar
Roselund, C., Inertia, frequency regulation and the grid, PV Magazine, 2019, https://pv-magazine-usa.com/2019/03/01/inertia-frequency-regulation-and-the-grid/ (accessed March 2, 2019).Google Scholar
Sorensen, B., A plan is outlined to which solar and wind energy would supply Denmark’s needs by the year 2050, Science, 189, 255260, 1975.Google Scholar
Lovins, A.B., Energy strategy: the road not taken, Foreign Affairs, 55, 6596, 1976.Google Scholar
Sorensen, B., Scenarios of greenhouse warming mitigation, Energy Convers. Manag., 37, 693698, 1996.Google Scholar
Jacobson, M.Z., and Masters, G.M., Exploiting wind versus coal, Science, 293, 14381438, 2001.Google Scholar
Jacobson, M.Z., Colella, W.G., and Golden, D.M., Cleaning the air and improving health with hydrogen fuel cell vehicles, Science, 308, 19011905, 2005.Google Scholar
Archer, C.L. and Jacobson, M.Z., Evaluation of global wind power, J. Geophys. Res., 110, D12110, https://doi.org/10.1029/2004JD005462, 2005.Google Scholar
Czisch, G., Szenarien zur zukünftigen Stromversorgung, kostenoptimierte Variationen zur Versorgung Europas und seiner Nachbarn mit Strom aus erneuerbaren Energien, Ph.D. Dissertation, University of Kassel, 2005, https://kobra.uni-kassel.de/handle/123456789/200604119596 (accessed February 24, 2019).Google Scholar
Czisch, G., and Giebel, G., Realisable scenarios for a future electricity supply based 100% on renewable energies, Riso-R-1608 (EN), 2007, www.researchgate.net/publication/238787763_Realisable_Scenarios_for_a_Future_Electricity_Supply_based_100_on_Renewable_Energies (accessed April 11, 2022).Google Scholar
Lund, H., Large-scale integration of optimal combinations of PV, wind, and wave power into the electricity supply, Renew. Energy, 31, 503515, 2006.Google Scholar
Hoste, G.R.G., Dvorak, M.J., and Jacobson, M.Z., Matching hourly and peak demand by combining different renewable energy sources, Stanford University Technical Report, 2009, web.stanford.edu/group/efmh/jacobson/Articles/I/CombiningRenew/HosteFinalDraft (accessed January 27, 2019).Google Scholar
Jacobson, M.Z., and Delucchi, M.A., A path to sustainable energy by 2030, Sci. Am. 301, 5865, November 2009.Google Scholar
Lund, H., and Mathiesen, B.V., Energy system analysis of 100% renewable energy systems – the case of Denmark in years 2030 and 2050, Energy, 34, 524531, 2009.Google Scholar
Delucchi, M.Z., and Jacobson, M.Z., Providing all global energy with wind, water, and solar power, Part II: Reliability, system and transmission costs, and policies, Energy Policy, 39, 11701190, https://doi.org/10.1016/j.enpol.2010.11.045, 2011.Google Scholar
Jacobson, M.Z., Howarth, R.W., Delucchi, M.A., et al., Examining the feasibility of converting New York State’s all-purpose energy infrastructure to one using wind, water, and sunlight, Energy Policy, 57, 585601, 2013.CrossRefGoogle Scholar
Jacobson, M.Z., Delucchi, M.A., Ingraffea, A.R., et al., A roadmap for repowering California for all purposes with wind, water, and sunlight, Energy, 73, 875889, https://doi.org/10.1016/j.energy.2014.06.099, 2014.Google Scholar
Jacobson, M.Z., Delucchi, M.A., Bazouin, G., et al., A 100 percent wind, water, sunlight (WWS) all-sector energy plan for Washington State, Renewable Energy, 86, 7588, 2016.Google Scholar
Jacobson, M.Z., Delucchi, M.A., Cameron, M.A., et al., Impacts of Green-New-Deal energy plans on grid stability, costs, jobs, health, and climate in 143 countries, One Earth, 1, 449463, https://doi.org/10.1016/j.oneear.2019.12.003, 2019.Google Scholar
Jacobson, M.Z., Cameron, M.A., Hennessy, E.M., et al., 100 percent clean, and renewable wind, water, and sunlight (WWS) all-sector energy roadmaps for 53 towns and cities in North America, Sustain. Cities Soc., 42, 2237, https://doi.org/10.1016/j.scs.2018.06.031, 2018.Google Scholar
Jacobson, M.Z., von Krauland, A.-K., Burton, Z.F.M., et al., Transitioning all energy in 74 metropolitan areas, including 30 megacities, to 100% clean and renewable wind, water, and sunlight, Energies, 13, 4934, https://doi.org/10.3390/en13184934, 2020.Google Scholar
Mason, I.G., Page, S.C., Williamson, A.G., A 100% renewable energy generation system for New Zealand utilizing hydro, wind, geothermal, and biomass resources, Energy Policy 38, 39733984, 2010.Google Scholar
Connolly, D., Lund, H., Mathiesen, B.V., and Leahy, M., The first step to a 100% renewable energy-system for Ireland, Appl. Energy, 88, 502507, 2011.Google Scholar
Connolly, D., and Mathiesen, B.V., Technical and economic analysis of one potential pathway to a 100% renewable energy system, Int. J. Sustain. Energy Plan. Manag., 1, 728, 2014.Google Scholar
Connolly, D., Lund, H., and Mathiesen, B.V., Smart energy Europe: the technical and economic impact of one potential 100% renewable energy scenario for the European Union, Renew. Sustain. Energy Rev., 60, 16341653, 2016.Google Scholar
Mathiesen, B.V., Lund, H., and Karlsson, K., 100% renewable energy systems, climate mitigation, and economic growth, Appl. Energy, 88, 488501, 2011.Google Scholar
Mathiesen, B.V., Lund, H., Connolly, D., et al., Smart energy systems for coherent 100% renewable energy and transport solutions, Appl. Energy, 145, 139154, 2015.Google Scholar
Hart, E.K., Stoutenburg, E.D., and Jacobson, M.Z., The potential of intermittent renewables to meet electric power demand: a review of current analytical techniques, Proc. IEEE, 100, 322334, https://doi.org/10.1109/JPROC.2011.2144951, 2012.Google Scholar
Hart, E.K., and Jacobson, M.Z., The carbon abatement potential of high penetration intermittent renewables, Energy Environ. Sci., 5, 65926601, https://doi.org/10.1039/C2EE03490E, 2012.Google Scholar
Elliston, B., Diesendorf, M., and MacGill, I., Simulations of scenarios with 100% renewable electricity in the Australian National Electricity Market, Energy Policy, 45, 606613, 2012.Google Scholar
Elliston, B., MacGill, I., and Diesendorf, M., Least cost 100% renewable electricity scenarios in the Australian National Electricity Market, Energy Policy, 59, 270282, 2013.Google Scholar
Elliston, B., MacGill, I., and Diesendorf, M., Comparing least cost scenarios for 100% renewable electricity with low emission fossil fuel scenarios in the Australian National Electricity Market, Renew. Energy, 66, 196204, 2014.Google Scholar
Rasmussen, M.G., Andresen, G.B., and Greiner, M., Storage and balancing synergies in a fully or highly renewable pan-European power system, Energy Policy, 51, 642651, 2012.Google Scholar
Steinke, F., Wolfrum, P., and Hoffmann, C., Grid vs. storage in a 100% renewable Europe, Renew. Energy, 50, 826832, 2013.Google Scholar
Becker, S., Frew, B.A., Andresen, G.B., et al., Features of a fully renewable U.S. electricity-system: optimized mixes of wind and solar PV and transmission grid extensions, Energy, 72, 443458, 2014.Google Scholar
Becker, S., Frew, B.A., Andresen, G.B., et al., Renewable build-up pathways for the U.S.: generation costs are not system costs, Energy, 81, 437445, 2015.CrossRefGoogle Scholar
Jacobson, M.Z., Cameron, M.A., and Frew, B.A., A low-cost solution to the grid reliability problem with 100 percent penetration of intermittent wind, water, and solar for all purposes, Proc. Natl Acad. Sci., 112, 1506015065, https://doi.org/10.1073/pnas.1510028112, 2015.Google Scholar
Frew, B.A., Becker, S., Dvorak, M.J., Andresen, G.B., and Jacobson, M.Z., Flexibility mechanisms and pathways to a highly renewable U.S. electricity future, Energy, 101, 6578, 2016.Google Scholar
Bogdanov, D., and Breyer, C., North-east Asian super grid for 100% renewable energy supply: optimal mix of energy technologies for electricity, gas, and heat supply options, Energy Convers. Manag., 112, 176190, 2016.Google Scholar
Bogdanov, D., Farfan, J., Sadovskaia, K., et al., Radical transformation pathway towards sustainable electricity via evolutionary steps, Nat. Commun., 10, 1077, https://doi.org/10.1038/s41467-019-08855-1, 2019.Google Scholar
Child, M., and Breyer, C., Vision and initial feasibility analysis of a decarbonized Finnish energy system for 2050. Renew. Sustain. Energy Rev., 66, 517536, 2016.Google Scholar
Aghahosseini, A., Bogdanov, D., and Breyer, C., A techno-economic study of an entirely renewable energy-based powers supply for North America for 2030 conditions, Energies, 10, 1171, https://doi.org/10.3390/en10081171, 2016.Google Scholar
Aghahosseini, A., Bogdanov, D., Barbosa, L.S.N.S., and Breyer, C., Analyzing the feasibility of powering the Americas with renewable energy and inter-regional grid interconnections by 2030, Renew. Sustain. Energy Rev., 105, 187205, 2019.Google Scholar
Aghahosseini, A., Bogdanov, D., and Breyer, C., Towards sustainable development in the MENA regions: Analysing the feasibility of a 100% renewable electricity system in 2030, Energy Strategy Rev., 28, 100466, 2020.Google Scholar
Blakers, A., Lu, B., and Socks, M., 100% renewable electricity in Australia, Energy, 133, 471482, 2017.Google Scholar
Blakers, A., Lu, B., Stocks, M., Anderson, K., and Nadolny, A., Pumped hydro storage to support 100% renewable power, Energy News, 36, 1114, 2018.Google Scholar
Barbosa, L.S.N.S., Bogdanov, D., Vainikka, P., and Breyer, C., Hydro, wind, and solar power as a base for a 100% renewable energy supply for South and Central America, PloS ONE, https://doi.org/10.1371/journal.pone.0173820, 2017.Google Scholar
Lu, B., Blakers, A., and Stocks, M., 90–100% renewable electricity for the South West Interconnected System of Western Australia, Energy, 122, 663674, 2017.Google Scholar
Gulagi, A., Bogdanov, D., and Breyer, C., A cost optimized fully sustainable power system for Southeast Asia and the Pacific Rim, Energies, 10, 583, https://doi.org/10.3390/en10050583, 2017.Google Scholar
Gulagi, A., Choudhary, P., Bogdanov, D., and Breyer, C., Electricity system based on 100% renewable energy for India and SAARC, PLoS ONE, https://doi.org/10.1371/journal.pone.0180611, 2017.Google Scholar
Esteban, M., Portugal-Pereira, J., Mclellan, B.C., et al., 100% renewable energy system in Japan: smoothening and ancillary services, Appl. Energy, 224, 698707, 2018.Google Scholar
Zapata, S., Casteneda, M., Jiminez, M., et al., Long-term effects of 100% renewable generation on the Colombian power market, Sustain. Energy Technol. Assess., 30, 183191, 2018.Google Scholar
Sadiqa, A., Gulagi, A., and Breyer, C., Energy transition roadmap towards 100% renewable energy and role of storage technologies for Pakistan by 2050, Energy, 147, 518533, 2018.Google Scholar
Barasa, M., Bogdanov, D., Oyewo, A.S., and Breyer, C., A cost optimal resolution for sub-Saharan Africa powered by 100% renewables in 2030, Renew. Sustain. Energy Rev., 92, 440457, 2018.Google Scholar
Caldera, U., and Breyer, C., Role that battery and water storage play in Saudi Arabia’s transition to an integrated 100% renewable energy power system, J. Energy Storage, 17, 299310, 2018.Google Scholar
Liu, H., Andresen, G.B., and Greiner, M., Cost-optimal design of a simplified highly renewable Chinese network, Energy, 147, 534546, 2018.Google Scholar
Teske, S., Giurco, D., Morris, T., et al., Achieving the Paris Climate Agreement, Miller, J., ed., 2019, https://oneearth.app.box.com/s/hctp4qlk34ygd0mw3yjdtctsymsdtaqs (accessed September 6, 2019).Google Scholar
Ram, M., Bogdanov, D., Aghahosseini, A., et al., Global energy system based on 100% renewable energy – power, heat, transport, and desalination sectors, Lappeenranta University of Technology Research Reports 91, Lappeenranta, 2019, http://energywatchgroup.org/wp-content/uploads/EWG_LUT_100RE_All_Sectors_Global_Report_2019.pdf (accessed September 6, 2019).Google Scholar
Hansen, K., Mathiesen, B., and Skov, I.R., Full energy system transition towards 100% renewable energy in Germany in 2050, Renew. Sustain. Energy Rev., 102, 113, 2019.Google Scholar
Oyewo, A.S., Aghahosseini, A., Ram, M., and Breyer, C., Transition towards decarbonized power systems and its socio-economic impacts in West Africa, Renew. Energy, 154, 10921112, 2020.Google Scholar
Marczinkowski, H.M., and Barros, L., Technical approaches and institutional alignment to 100% renewable energy system transition of Madeira Island – electrification, smart energy and the required flexible market conditions, Energies, 13, 4434, 2020.Google Scholar
Li, M., Lenzen, M., Wang, D., and Nansai, K., GIS-based modelling of electric-vehicle-grid integration in a 100% renewable electricity grid, Appl. Energy, 262, 114577, 2020.Google Scholar
Alves, M., Segurado, R., and Costa, M., On the road to 100% renewable energy systems in isolated islands, Energy, 198, 117321, 2020.Google Scholar
Kiwan, S., and Al-Gharibeh, E., Jordan toward a 100% renewable electricity system, Renew. Energy, 147, 423436, 2020.Google Scholar
Zozmann, E., Goke, L., Kendziorski, M., et al., 100% renewable energy scenarios for North America – spatial distribution and network constraints, Energies, 14, 658, 2021.Google Scholar
Cole, W.J., Greer, D., Denholm, P., et al., Quantifying the challenge of reaching a 100% renewable energy power system for the United States, Joule, 5, 17321748, 2021.Google Scholar
Brown, T.W., Bischof-Niemz, T., Blok, K., et al., Response to ‘Burden of proof: A comprehensive review of the feasibility of 100% renewable electricity systems,’ Renew. Sustain. Energy Rev., 92, 834847, 2018.Google Scholar
Diesendorf, M., and Elliston, B., The feasibility of 100% renewable electricity systems: a response to critics, Renew. Sustain. Energy Rev., 93, 318330, 2018.Google Scholar
Hansen, K., Breyer, C., and Lund, H., Status and perspectives on 100% renewable energy systems, Energy, 175, 471480, 2019.Google Scholar
Edelstein, S., Report: EV battery costs hit a new low in 2021, but they might rise in 2022, Green Car Reports, 2021, www.greencarreports.com/news/1134307_report-ev-battery-costs-might-rise-in-2022 (accessed January 2, 2022).Google Scholar
Irvine, M., and Rinaldo, M., Tesla’s battery day and the energy transition, DNV, 2020, www.dnv.com/feature/tesla-battery-day-energy-transition.html (accessed January 2, 2022).Google Scholar
World Bank, Agricultural and rural development, https://data.worldbank.org/indicator/, 2017 (accessed September 16, 2019).Google Scholar
Macdonald-Smith, A., South Australia’s big battery slashes $40m from grid control costs in first year, 2018, www.afr.com/business/energy/solar-energy/south-australias-big-battery-slashes-40m-from-grid-control-costs-in-first-year-20181205-h18ql1 (accessed January 25, 2019).Google Scholar
Spector, J., ‘Cheaper than a peaker’: NextEra inks massive wind+solar+storage deal in Oklahoma, 2019, www.greentechmedia.com/articles/read/nextera-inks-even-bigger-windsolarstorage-deal-with-oklahoma-cooperative#gs.s8lb02 (accessed July 26, 2019).Google Scholar
Thomas, H., Richard Branson’s disappointing space jaunt, 2021, www.cnn.com/2021/07/12/opinions/richard-branson-jeff-bezos-space-flight-is-a-waste-thomas/index.html (accessed December 8, 2021).Google Scholar
Wilson, M., FERC launches first transmission reforms in a decade, 2021, www.eenews.net/articles/ferc-launches-first-transmission-reforms-in-a-decade/ (accessed July 16, 2021).Google Scholar
Jacobson, M.Z., Developing, Coupling, and Applying a Gas, Aerosol, Transport, and Radiation Model to Study Urban and Regional Air Pollution. Ph.D. Dissertation, University of California, Los Angeles, 1994.Google Scholar
Jacobson, M.Z., Lu, R., Turco, R.P., and Toon, O.B., Development and application of a new air pollution modeling system. Part I: Gas-phase simulations, Atmos. Environ., 30B, 19391963, 1996.Google Scholar
Jacobson, M.Z., Development and application of a new air pollution modeling system. Part II: Aerosol module structure and design, Atmos. Environ., 31A, 131144, 1997.Google Scholar
Jacobson, M.Z., Development and application of a new air pollution modeling system. Part III: Aerosol-phase simulations, Atmos. Environ., 31A, 587608, 1997.Google Scholar
Jacobson, M.Z., Simulations of the rates of regeneration of the global ozone layer upon reduction or removal of ozone-destroying compounds. EOS Suppl., Fall, 1995, F119.Google Scholar
Jacobson, M.Z., Global direct radiative forcing due to multicomponent anthropogenic and natural aerosols, J. Geophys. Res., 106, 15511568, 2001.Google Scholar
Jacobson, M.Z., GATOR-GCMM: A global through urban scale air pollution and weather forecast model. 1. Model design and treatment of subgrid soil, vegetation, roads, rooftops, water, sea ice, and snow, J. Geophys. Res., 106, 53855401, 2001.Google Scholar
Jacobson, M.Z., GATOR-GCMM: 2. A study of day- and nighttime ozone layers aloft, ozone in national parks, and weather during the SARMAP field campaign, J. Geophys. Res., 106, 54035420, 2001.Google Scholar
Jacobson, M.Z., Kaufmann, Y.J, Rudich, Y, Examining feedbacks of aerosols to urban climate with a model that treats 3-D clouds with aerosol inclusions, J. Geophys. Res., 112, D24205, https://doi.org/10.1029/2007JD008922, 2007.Google Scholar
Jacobson, M.Z., Studying the effects of aerosols on vertical photolysis rate coefficient and temperature profiles over an urban airshed, J. Geophys. Res., 103, 1059310604, 1998.Google Scholar
Jacobson, M. Z., Isolating nitrated and aromatic aerosols and nitrated aromatic gases as sources of ultraviolet light absorption, J. Geophys. Res., 104, 35273542, 1999.Google Scholar
New York Times, Text of President Bush’s remarks on global climate, 2001, www.nytimes.com/2001/06/11/world/text-of-president-bushs-remarks-on-global-climate.html (accessed December 8, 2021).Google Scholar
Dvorak, M., Archer, C.L., and Jacobson, M.Z., California offshore wind energy potential, Renew. Energy, 35, 12441254, https://doi.org/10.1016/j.renene.2009.11.022, 2010.Google Scholar
Dvorak, M.J., Stoutenburg, E.D., Archer, C.L., Kempton, W., and Jacobson, M.Z., Where is the ideal location for a U.S. East Coast offshore grid, Geophys. Res. Lett., 39, L06804, https://doi.org/10.1029/2011GL050659, 2012.Google Scholar
Dvorak, M.J., Corcoran, B.A., Ten Hoeve, J.E., McIntyre, N.G., and Jacobson, M.Z., U.S. East Coast offshore wind energy resources and their relationship to peak-time electricity demand, Wind Energy, 16, 977997, https://doi.org/10.1002/we.1524, 2013.Google Scholar
Jacobson, M.Z., Seinfeld, J.H., Carmichael, G.R., and Streets, D.G., The effect on photochemical smog of converting the U.S. fleet of gasoline vehicles to modern diesel vehicles, Geophys. Res. Lett., 31, L02116, https://doi.org/10.1029/2003GL018448, 2004.Google Scholar
TED (Technology, Education, Development), Does the world need nuclear energy? Public debate, Mark Z. Jacobson and Stewart Brand, Long Beach, California, February 11, 2010, www.ted.com/talks/debate_does_the_world_need_nuclear_energy?language=en (accessed December 9, 2021).Google Scholar
Solutions Project, Our 100% Clean Energy Vision, 2019, www.thesolutionsproject.org/why-clean-energy/ (accessed December 8, 2021).Google Scholar
Ruffalo, M.A., Krapels, M., and Jacobson, M.Z., A plan to power the world with wind, water, and sunlight, Talks at Google, Google, Inc., Mountain View, California, June 20, 2012, www.youtube.com/watch?v=N_sLt5gNAQs (accessed December 8, 2021).Google Scholar
Ruffalo, M.Z., Krapels, M., and video from J. Fox, Powering the world, U.S., and New York with wind, water, and sunlight, The Nantucket Project, Nantucket, Massachusetts, October 6, 2012, http://vimeo.com/52038463 (accessed December 8, 2021).Google Scholar
Letterman, D., The Late Show with David Letterman, New York City, October 9, 2013, www.youtube.com/watch?v=AqIu2J3vRJc (accessed December 8, 2021).Google Scholar
California Senate, SB 100 FAQs, 2018, https://focus.senate.ca.gov/sb100/faqs (accessed December 8, 2021).Google Scholar
U.S. House of Representatives, H.Res.540, 2015, www.congress.gov/bill/114th-congress/house-resolution/540/text (accessed December 8, 2021).Google Scholar
O’Malley, M., A jobs agenda for our renewable energy future, 2015, www.p2016.org/omalley/omalley070215climate.html (accessed December 8, 2021).Google Scholar
Clinton, H., Hillary is ready for 100, October 16, 2015, www.c-span.org/video/?c4557641/hillary-readyfor100 (accessed December 8, 2021).Google Scholar
Democratic National Committee, 2016 Democratic Party Platform, July 9, 2016, https://democrats.org/wp-content/uploads/2018/10/2016_DNC_Platform.pdf (accessed December 8, 2021).Google Scholar
Sanders, B., and Jacobson, M., The American people, not big oil, must decide our climate future, The Guardian, April 29, 2017, www.theguardian.com/commentisfree/2017/apr/29/bernie-sanders-climate-change-big-oil (accessed December 8, 2021).Google Scholar
REN21 (Renewable Energy Policy Network for the 21st Century), Renewables 2020 global status report, 2020, www.ren21.net/gsr-2020/tables/table_06/table_06/ (accessed December 8, 2021).Google Scholar
Lillian, B., Orsted survey: Eight out of 10 support 100% global renewable energy, November 13, 2017, https://nawindpower.com/orsted-survey-eight-10-support-100-global-renewable-energy (accessed December 8, 2021).Google Scholar
Sierra Club, Ready for 100, 2021, www.sierraclub.org/ready-for-100/commitments (accessed January 2, 2022).Google Scholar
REN21 (Renewable Energy Policy Network for the 21st Century), Renewables in cities: 2019 global status report, 2019, www.ren21.net/wp-content/uploads/2019/05/REC-2019-GSR_Full_Report_web.pdf (accessed December 8, 2021).Google Scholar
Boyer, G., Appalachian power rolls out 100% renewable option for customers, WFXR News, 2019, www.wfxrtv.com/news/appalachian-power-rolls-out-100-renewable-option-for-va-customers/ (accessed December 8, 2021).Google Scholar
Duke Energy, More renewable energy options available under Duke Energy’s Green Source Advantage, 2019, https://news.duke-energy.com/releases/more-renewable-energy-options-available-under-duke-energys-green-source-advantage?_ga=2.88266651.1875174277.1566405614-658711925.1566405614 (accessed December 8, 2021).Google Scholar
RE100, The world’s most influential companies committed to 100% renewable power, 2022, http://there100.org (accessed January 2, 2022).Google Scholar
Climate Group, EV100 members, 2019, www.theclimategroup.org/ev100-members (accessed December 8, 2021).Google Scholar
Shepherd, M., The climate science behind the green new deal – a layperson’s explanation, 2019, www.forbes.com/sites/marshallshepherd/2019/02/24/the-climate-science-behind-the-green-new-deal-a-laypersons-explanation/?sh=4e0260e36f2a (accessed December 8, 2021).Google Scholar
Green Party US, Green New Deal – Full Language, 2018, www.gp.org/gnd_full (accessed December 8, 2021).Google Scholar

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  • References
  • Mark Z. Jacobson, Stanford University, California
  • Book: No Miracles Needed
  • Online publication: 02 February 2023
  • Chapter DOI: https://doi.org/10.1017/9781009249553.018
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  • References
  • Mark Z. Jacobson, Stanford University, California
  • Book: No Miracles Needed
  • Online publication: 02 February 2023
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  • References
  • Mark Z. Jacobson, Stanford University, California
  • Book: No Miracles Needed
  • Online publication: 02 February 2023
  • Chapter DOI: https://doi.org/10.1017/9781009249553.018
Available formats
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