Climate Engineering Newsletter for October/November 2013

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Climate Engineering Newsletter for October/November 2013 Dear Climate Engineering Group, please find below our eleventh climate engineering newsletter. You can find daily updated climate engineering news on our news portal www.climate-engineering.eu/news.html. (All newsletters are available on the websites’ home screen under “newsletter”.) We will change the frequency of our newsletter from bi-monthly to weekly. You will get a message before the change. Thank you The Climate Engineering Editors Climate Engineering Newsletter for October/November 2013 Upcoming Events • 17.12.2013, Paris (FR), Workshop: Day of Restitution of the Workshop Reflection Prospective REACT - on geo-environmental engineering • 18.-21.08.2014, Berlin/Germany, Climate Engineering Conference 2014 (CEC14) New Projects • Cambridge Carbon Capture • Convention on Biological Diversity: Climate-related Geoengineering and Biodiversity • Newlight Technologies: Air Carbon Project • Cool Planet Announces Launch of Cool Terra™ Biochar Soil Amendment • Ochen Challenge Mitigating Acidification Impacts • Biochar Bibliography New Publications • Environmental Science & Policy - special issue on deforestation • Bellamy, Rob (2013): Framing Geoengineering Assessment • Heyward, Clare; Rayner, Steve (2013): A Curious Asymmetry. Social Science Expertise and Geoengineering • KIM, Jung-Eun (2013): Implications of Current Developments in International Liability for the Practice of Marine Geo-engineering Activities 1 • Kleidon, A.; Renner, M. (2013): A simple explanation for the sensitivity of the hydrologic cycle to surface temperature and solar radiation and its implications for global climate change • Hoppe, Clara J. M.; et al. (2013): Iron Limitation Modulates Ocean Acidification Effects on Southern Ocean Phytoplankton Communities • Kravitz, Ben; et al. (2013): Sea spray geoengineering experiments in the geoengineering model intercomparison project (GeoMIP): Experimental design and preliminary results • Kravitz, Ben; et al. (2013): An energetic perspective on hydrological cycle changes in the Geoengineering Model Intercomparison Project (GeoMIP) • Jones, Andy; et al. (2013): The impact of abrupt suspension of solar radiation management (termination effect) in experiment G2 of the Geoengineering Model Intercomparison Project (GeoMIP) • Wood, Robert; Ackerman, Thomas P. (2013): Defining success and limits of field experiments to test geoengineering by marine cloud brightening • Ilyina, Tatiana; et al. (2013): Assessing the potential of calcium-based artificial ocean alkalinization to mitigate rising atmospheric CO2 and ocean acidification (online first) • Special Issue: Geoengineering Research and its Limitations. In: Climatic Change • Horton, Joshua B.; et al. (2013): Solar Geoengineering and the Problem of Liability • Stilgoe, Jack; et al. (2013): Public Engagement with Biotechnologies Offers Lessons for the Governance of Geoengineering Research and Beyond • Bronson, Diana; et al. (2012): Retooling the Planet. The False Promise of Geoengineering • Caldeira, Ken; Ricke, Katharine L. (2013): Prudence on solar climate engineering • Fleming, James Rodger (2013): A History of Weather and Climate Control • Boucher, Olivier; et al. (2013): Rethinking climate engineering categorization in the context of climate change mitigation and adaptation • Hardman-Mountford, N. J.; et al (2013): Impacts of light shading and nutrient enrichment geo-engineering approaches on the productivity of a stratified, oligotrophic ocean ecosystem • Tilmes, Simone; et al. (2013): The hydrological impact of geoengineering in the Geoengineering Model Intercomparison Project (GeoMIP) • Robock, Alan; Kravitz, Ben (2013): Use of Models, Analogs and Field-Tests for Geoengineering Research • Keith, David W. (2013): A case for climate engineering • Bryant, Steven L. (2013): The One-Stop Carbon Solution • Huttunen, S.; Hilden, M. (2013): Framing the Controversial: Geoengineering in Academic Literature (online first) • Golkhar, A.; et al. (2013): Investigation of CO2 removal by silica and CNT nanofluids in microporous hollow fiber membrane contactors • Szerszynski, B.; Galarraga, M. (2013): Geoengineering knowledge: interdisciplinarity and the shaping of climate engineering research (preliminary version) • Szerszynski, B.; et al. (2013): Why solar radiation management geoengineering and democracy won’t mix (prelimenary version) • Zhang, Weixin; et al. (2013): Earthworms facilitate carbon sequestration through unequal amplification of carbon stabilization compared with mineralization • Carbon and Climate Law Review (CCLR): Special Issue on Climate Change Geoengineering 2 • Kravitz, Ben; et al. (2013): An overview of the Geoengineering Model Intercomparison Project (GeoMIP) • Niemeier, U.; et al. (2013): Solar irradiance reduction via climate engineering - Impact of different techniques on the energy balance and the hydrological cycle. Political Papers • US Congressional Research Services: Geoengineering: Governance and Technology Policy (update) • German young Think Tank of the Club of Rome: 7 Questions on Climate Engineering • The African Academy of Sciences (AAS) (2013): Governance of Research on Solar Geoengineering. African Perspective Selected Media Responses • Huffington Post: Geoengineering The Sky is Not 'Normal' • Journal de l'environnement: Effective geoengineering? • Inside Science: If You Start Geoengineering To Halt Global Warming, Don't Stop • Geoengineering Politics Blog: Quick Recap of COP19 from a Geoengineering Perspective • the guardian: Climate science: can geoengineering save the world? • CEC 14 Blog: Positive Discussions on Negative Emissions • environmental research web: Geoengineering the climate could reduce vital rains • The Telegraph: Greenhouse gases at record high, UN weather agency says • Huffington Post: Communicating Climate Geoengineering to the Public • NewScientist: Should we give the green light to geoengineers? • NewStatesman: Naomi Klein: How science is telling us all to revolt • ars technica: Geoengineering, through the eyes of the IPCC • Phys.org: Team uses forest waste to develop cheaper, greener supercapacitors • Science News Focus: Dr. Cool • The Independent: Cloudy with a chance of... climate change • NewScientist: Terraforming Earth: Geoengineering megaplan starts now • the guardian: Why we'd be mad to rule out climate engineering • [press review] IPCC Assessment Report on CE To unsubscribe please send short message to [email protected] 3 .
Recommended publications
  • Solar Geoengineering Reduces Atmospheric Carbon Burden David W
    opinion & comment COMMENTARY: Solar geoengineering reduces atmospheric carbon burden David W. Keith, Gernot Wagner and Claire L. Zabel Solar geoengineering is no substitute for cutting emissions, but could nevertheless help reduce the atmospheric carbon burden. In the extreme, if solar geoengineering were used to hold radiative forcing constant under RCP8.5, the carbon burden may be reduced by ~100 GTC, equivalent to 12–26% of twenty-first-century emissions at a cost of under US$0.5 per tCO2. ailure to address the accumulation of between a Representative Concentration carbon cycle feedback under assumptions atmospheric carbon is among the most Pathway (RCP) 8.5 scenario and one in that are similar — though not equal — to frequently noted disadvantages of solar which solar geoengineering is used to hold those that would be used to simulate solar F 1–3 geoengineering , an attempt to reflect a radiative forcing at current levels. This is geoengineering to stabilize radiative forcing small fraction of radiation back into space not a complete analysis, but rather a call for under an RCP8.5 scenario. We then combine to cool the planet. The latest US National further research. It is also a call for assessing the two ranges using equal weights and Academy of Science solar geoengineering solar geoengineering scenarios that go well uncorrelated error propagation to yield report1 states it “does nothing to reduce the beyond oft-modelled extreme scenarios that an overall estimate of the contribution 10 build-up of atmospheric CO2”. offset total anthropogenic radiative forcing . of the terrestrial biosphere and ocean of This is not so.
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  • Preparing for the Worst: the Case for Solar Geoengineering Research
    Preparing for the Worst: The Case for Solar Geoengineering Research and Oversight 2019 AUGUST 6 Bradie S. Crandall American Institute of Chemical Engineers The Case for Solar Geoengineering Research and Oversight | 1 “The Earth is the only world known so far to harbor life. There is nowhere else, at least in the near future, to which our species could migrate. Visit, yes. Settle, not yet. Like it or not, for the moment the Earth is where we make our stand.” -Carl Sagan The Case for Solar Geoengineering Research and Oversight | 2 Table of Contents EXECUTIVE SUMMARY…………………………………………………………………………………………………. 5 FOREWORD………………………………………………………………………………………………………………….. 6 About the Author……………………………………………………………………………………………………. 6 About the WISE program…………………………………………………………………………………………. 6 Acknowledgements…………………………………………………………………………………………………. 6 Acronyms…………………………………………………………………………………………………………………….. 7 1. INTRODUCTION………………………………………………………………………………………………………… 8 1.1 The Climate Crisis…………….………………………………………………………………………………… 8 1.2 Global Decarbonization Efforts………………………………………………………………………….. 9 1.3 Solar Geoengineering………………………………………………………………………………………… 10 2. BACKGROUND………………………………………………………………………………………………….......... 11 2.1 History………………………………………………………………………………………………………………. 11 2.2 Recent Interest…………………………………………………………………………………………………… 11 2.3 Technological Readiness and Feasibility……………………………………………………………… 14 3. KEY CONFLICTS AND CONCERNS………………………………………………………………………………. 16 3.1 Research Echo Chamber…………………………………………………………………………………….. 16 3.2 Research vs Implementation………………………………………………………………………………
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  • Green Moral Hazards
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  • James Rodger Fleming
    Curriculum Vitae James Rodger Fleming Charles A. Dana Professor of Science, Technology, and Society, Emeritus Colby College, Waterville, Maine 04901 USA Email: [email protected]; Phone: 1-207-859-5881; FAX: 1-207-859-5868 CURRENT AFFILIATION Charles A. Dana Professor of Science, Technology and Society, Emeritus, Colby College EMPLOYMENT Colby College, Visiting Assistant to Charles A. Dana Professor of STS 1988-2021 American Meteorological Society, Historical Consultant, 1986-88 Princeton University, Fellow and Preceptor, Department of History, 1982-85 Private Consulting Meteorologist, 1974-82 University of Washington, Research Meteorologist, 1973-74 National Center for Atmospheric Research, Research Meteorologist, 1973 EDUCATION Princeton University, Ph.D. History, 1988; M.A. History of Science, 1984 Colorado State University, M.S. Atmospheric Science, 1973 Pennsylvania State University, B.S. Astronomy, 1971 AWARDS, APPOINTMENTS, HONORS Phi Beta Kappa Visiting Scholar, Department of the History of Science, Harvard University, 2020-21 Consultant, The Goddard Project, Societal implications of negative emissions technologies Advisor, “Making Climate History,” Leverhulme Trust grant to University of Cambridge, 2019-24 International Association of Meteorology and Atmospheric Sciences, keynote speaker, 2019 Distinguished Alumnus Award, Forest Hills School District, PA, 2018 American Geophysical Union, John Tyndall Lecturer in Global Environmental Change, 2017 American Meteorological Society, history editor, Bulletin of the AMS, 2011-21. Smithsonian
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  • Once a Fringe Idea, Geoengineering Moves to Center Stage in Policy Arena
    THE DEBATE IN PRINT Once a Fringe Idea, Geoengineering Moves to Center Stage in Policy Arena limate geoengineering was once the Burns concluded with an overview of the inter- province only of a few radical scientists national institutions that might be applicable Cgaming worst-case scenarios. Today, it is to governing carbon dioxide removal. a dynamic and rapidly emerging suite of poten- Limiting the global average temperature tial responses to climate change. Just a de- increase to below 2 degrees, as envisioned in cade ago considered as on the outer fringes, the Paris Agreement, is already unlikely without deliberate interference in the atmosphere has deploying large-scale technologies that reduce become a credible option as a consequence solar insolation or remove greenhouse gases of increasing evidence of the catastrophic im- from the atmosphere. However, real-world re- plications of a warmer world and the failure of search, let alone deployment at scale, remains the global community to pursue sufficiently ag- deeply controversial, especially given the lack gressive efforts to reduce emissions. of international oversight of these relatively low- ELI convened a webinar bringing together cost technologies that nonetheless have trans- three experts who collectively believe that it is boundary implications affecting all of humanity. time to consider at least two forms of geoengi- Can policymakers addressing climate neering, solar radiation management and car- change today rely upon the technologies of to- bon dioxide removal. Shuchi Talati started with morrow? Which methods seem promising and an overview of the two major genres and some which upon inspection are not? What are the of the research and implementation consid- legal frameworks governing research into geo- erations.
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  • Indigeneity in Geoengineering Discourses: Some Considerations
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  • Science Update
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  • Consensus Study Report MARCH 2021 HIGHLIGHTS
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  • Solar Geoengineering: a Solution Without a Plan Peter Lorenz E-103:The Challenge of Human Induced Climate Change May 8, 2020
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