Abstract
Abstract. Here we use an Earth system model with interactive biogeochemistry to project future ocean biogeochemistry impacts from the large-scale deployment of three different radiation management (RM) climate engineering (also known as geoengineering) methods: stratospheric aerosol injection (SAI), marine sky brightening (MSB), and cirrus cloud thinning (CCT). We apply RM such that the change in radiative forcing in the RCP8.5 emission scenario is reduced to the change in radiative forcing in the RCP4.5 scenario. The resulting global mean sea surface temperatures in the RM experiments are comparable to those in RCP4.5, but there are regional differences. The forcing from MSB, for example, is applied over the oceans, so the cooling of the ocean is in some regions stronger for this method of RM than for the others. Changes in ocean net primary production (NPP) are much more variable, but SAI and MSB give a global decrease comparable to RCP4.5 (∼ 6 % in 2100 relative to 1971–2000), while CCT gives a much smaller global decrease of ∼ 3 %. Depending on the RM methods, the spatially inhomogeneous changes in ocean NPP are related to the simulated spatial change in the NPP drivers (incoming radiation, temperature, availability of nutrients, and phytoplankton biomass) but mostly dominated by the circulation changes. In general, the SAI- and MSB-induced changes are largest in the low latitudes, while the CCT-induced changes tend to be the weakest of the three. The results of this work underscore the complexity of climate impacts on NPP and highlight the fact that changes are driven by an integrated effect of multiple environmental drivers, which all change in different ways. These results stress the uncertain changes to ocean productivity in the future and advocate caution at any deliberate attempt at large-scale perturbation of the Earth system.
Highlights
Human emissions of carbon dioxide to the atmosphere are unequivocally causing global warming and climate change (IPCC, 2013)
The projected oxygen reductions do not drop as low as in RCP8.5 after termination of the radiation management (RM) during our simulation period, but had the simulations been continued for some further decades, the oxygen levels would most likely have converged to the RCP8.5 levels
We use the Norwegian Earth system model with a fully interactive carbon cycle to assess the impact of three radiation management (RM) climate engineering methods on marine biogeochemistry
Summary
Human emissions of carbon dioxide to the atmosphere are unequivocally causing global warming and climate change (IPCC, 2013). At the 21st United Nations Framework Convention on Climate Change (UNFCCC) Conference of the Parties, it was agreed to limit the increase in global mean temperature to 2 ◦C above preindustrial levels and to pursue efforts to remain below 1.5 ◦C. Reaching this goal will not be possible without radical social transformation. Solar radiation management (SRM) has been suggested as both a method of offsetting global warming and reducing the risks associated with climate change, substituting some degree of mitigation (Teller et al, 2003; Bickel and Lane, 2009), or buying time to reduce emissions (Wigley, 2006). SRM is an idea to increase the amount of solar radiation reflected by Earth in order to offset changes in the radiation budget due to the increased greenhouse effect from anthropogenic emissions, i.e., a form of climate engineering or geoengineering
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