Abstract
The deliberate injection of particles into the stratosphere has been suggested as a possible geoengineering scheme to mitigate the global warming aspect of climate change. Injected particles scatter solar radiation back to space and thus reduce the radiative balance of Earth. Previous studies investigating this scheme have focused primarily on sulphuric acid particles to mimic volcanic injections of stratospheric aerosol. However, the composition and size of volcanic sulphuric acid particles are far from optimal for scattering solar radiation. We show that aerosols with other compositions, such as minerals, could be used to dramatically increase the amount of light scatter achieved on a per mass basis, thereby reducing the particle mass required for injection. The chemical consequences of injecting such particles into the stratosphere are discussed with regard to the fate of the ozone layer. Research questions are identified with which to assess the feasibility of such geoengineering schemes.
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Acknowledgements
The project and the authors F.D.P., P.B., R.G.G., M.K., I.M.W. and R.A.C. were funded by EPSRC grant number EP/I01473X/1. P.J.D. was funded by Davidson Technology Limited.
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P.J.D. is employed by Davidson Technology Limited, the company holding the patent application mentioned in ref. 15.
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Pope, F., Braesicke, P., Grainger, R. et al. Stratospheric aerosol particles and solar-radiation management. Nature Clim Change 2, 713–719 (2012). https://doi.org/10.1038/nclimate1528
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DOI: https://doi.org/10.1038/nclimate1528
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