First Simulations of Designing Stratospheric Sulfate Aerosol Geoengineering to Meet Multiple Simultaneous Climate Objectives

Kravitz, Ben; MacMartin, Douglas G.; Mills, Michael J.; Richter, Jadwiga H.; Tilmes, Simone; Lamarque, Jean‐François; Tribbia, Joseph; Vitt, Francis

doi:10.1002/2017jd026874

Cited by 175 publications

(344 citation statements)

References 66 publications

(186 reference statements)

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“…Newly formed particles coagulate with existing larger particles, which continuously increases the particle size with SO 2 emission amount. The resulting increase in sedimentation and reduced reflectivity of larger particles leads to reduced scattering of sunlight and efficiency to cool the climate per Tg S injection (e.g., Kravitz et al, ; Niemeier & Timmreck, ; Visioni et al, ).…”

Section: Introductionmentioning

confidence: 99%

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations

et al. 2017

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Injection of SO2 into the stratosphere has been proposed as a method to, in part, counteract anthropogenic climate change. So far, most studies investigated injections at the equator or in a region in the tropics. Here we use Community Earth System Model version 1 Whole Atmosphere Community Climate Model (CESM1(WACCM)) to explore the impact of continuous single grid point SO2 injections at seven different latitudes and two altitudes in the stratosphere on aerosol distribution and climate. For each of the 14 locations, 3 different constant SO2 emission rates were tested to identify linearity in aerosol burden, aerosol optical depth, and climate effects. We found that injections at 15°N and 15°S and at 25 km altitude have equal or greater effect on radiation and surface temperature than injections at the equator. Nonequatorial injections transport SO2 and sulfate aerosols more efficiently into middle and high latitudes and result in particles of smaller effective radius and larger aerosol burden in middle and high latitudes. Injections at 15°S produce the largest increase in global average aerosol optical depth and increase the change in radiative forcing per Tg SO2/yr by about 15% compared to equatorial injections. High‐altitude injections at 15°N produce the largest reduction in global average temperature of 0.2° per Tg S/yr for the last 7 years of a 10 year experiment. Injections at higher altitude are generally more efficient at reducing surface temperature, with the exception of large equatorial injections of at least 12 Tg SO2/yr. These findings have important implications for designing a strategy to counteract global climate change.

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Section: Introductionmentioning

confidence: 99%

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations

et al. 2017

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“…For example, whilst a uniform reduction in incoming sunlight would not offset all warming at high latitudes, stratospheric aerosol geoengineering could be deployed to produce a thicker aerosol cloud at high latitudes to reduce high-latitude temperatures in line with global mean temperatures or to cool them further (Dai et al, 2018;Kravitz et al, 2018). However, it is important to note that the effects of solar geoengineering cannot be limited to the area of application and there would be remote impacts even if strato- spheric aerosol geoengineering was limited just to polar regions .…”

Section: Surface Mass Balancementioning

confidence: 99%

Brief communication: Understanding solar geoengineering's potential to limit sea level rise requires attention from cryosphere experts

2018

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Abstract. Stratospheric aerosol geoengineering, a form of solar geoengineering, is a proposal to add a reflective layer of aerosol to the stratosphere to reduce net radiative forcing and so to reduce the risks of climate change. The efficacy of solar geoengineering at reducing changes to the cryosphere is uncertain; solar geoengineering could reduce temperatures and so slow melt, but its ability to reverse ice sheet collapse once initiated may be limited. Here we review the literature on solar geoengineering and the cryosphere and identify the key uncertainties that research could address. Solar geoengineering may be more effective at reducing surface melt than a reduction in greenhouse forcing that produces the same global-average temperature response. Studies of natural analogues and model simulations support this conclusion. However, changes below the surfaces of the ocean and ice sheets may strongly limit the potential of solar geoengineering to reduce the retreat of marine glaciers. High-quality process model studies may illuminate these issues. Solar geoengineering is a contentious emerging issue in climate policy and it is critical that the potential, limits, and risks of these proposals are made clear for policy makers.

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“…This reduction is larger than the one in G4K relative to the Base case (∆τ =-0.020, -5%), pointing out to the dominant and controlling role of the reduced updraft injected, especially if such efficiency is used to determine the amount of SO 2 that needs to be injected in the stratosphere to achieve climate targets ; Kravitz et al (2017)). …”

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confidence: 99%

“…(2017); Kravitz et al (2017)). However, to properly do so, a clear understanding is needed of how multiple side effects of this technique can modify the net RF (Visioni et al, 2017a).…”

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Upper tropospheric ice sensitivity to sulfate geoengineering

Visioni¹,

Pitari²,

Mancini³

2018

Preprint

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Abstract. Aside from the direct surface cooling sulfate geoengineering (SG) would produce, the investigation on possible sideeffects of this method is still ongoing, as for instance on upper tropospheric cirrus cloudiness. Goal of the present study is to better understand the SG thermo-dynamical effects on the homogeneous freezing ice formation process. This is done by comparing SG model simulations against a RCP4.5 reference case: in one case the aerosol-driven surface cooling is included and coupled to the stratospheric warming resulting from aerosol absorption of longwave radiation. In a second SG perturbed case, 5 surface temperatures are kept unchanged with respect to the reference RCP4.5 case. Surface cooling and lower stratospheric warming, together, tend to stabilize the atmosphere, thus decreasing turbulence and water vapor updraft velocities (-10% in our modeling study). The net effect is an induced cirrus thinning, which may then produce a significant indirect negative radiative forcing (RF). This would go in the same direction as the direct effect of solar radiation scattering by the aerosols, thus influencing the amount of sulfur needed to counteract the positive RF due to greenhouse gases. In our study, given a 8 Tg-SO 2 10 equatorial injection in the lower stratosphere, an all-sky net tropopause RF of -2.13 W/m 2 is calculated, of which -0.96 W/m 2 (45%) from the indirect effect on cirrus thinning (7.5% reduction in ice optical depth). When the surface cooling is ignored, the ice optical depth reduction is lowered to 5%, with an all-sky net tropopause RF of -1.45 W/m ). This highlights the importance of including all dynamical feedbacks of SG aerosols.

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First Simulations of Designing Stratospheric Sulfate Aerosol Geoengineering to Meet Multiple Simultaneous Climate Objectives

Cited by 175 publications

References 66 publications

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations

Brief communication: Understanding solar geoengineering's potential to limit sea level rise requires attention from cryosphere experts

Upper tropospheric ice sensitivity to sulfate geoengineering

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First Simulations of Designing Stratospheric Sulfate Aerosol Geoengineering to Meet Multiple Simultaneous Climate Objectives

Cited by 175 publications

References 66 publications

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO2 Injection Locations

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO2 Injection Locations

Brief communication: Understanding solar geoengineering's potential to limit sea level rise requires attention from cryosphere experts

Upper tropospheric ice sensitivity to sulfate geoengineering

Contact Info

Product

Resources

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Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations

Sensitivity of Aerosol Distribution and Climate Response to Stratospheric SO₂ Injection Locations