sulfate aerosol geoengineering modelled by solar dimming
Tamas Bodai
I would like to ask for some useful references about sulfate aerosol geoengineering. Assuming some uniform aerosol coverage around the globe, at some height, with a certain vertical layer thickness, i would imagine that at higher latitudes the radiative forcing exerted by the aerosols is larger due to the longer distance of travel of sun rays through the aerosol "cloud". As a consequence, the latitude-dependence of the downward-directed radiative forcing should have an even larger gradient than solar irradiance. Therefore, I’m wondering how big mistake it is to model such a geoengineering scenario by dimming the sun.
Any feedback or reference would be much appreciated.
Thank you,
Tamas
Olivier Boucher
Dear Tamas,
there are typically 3 effects that govern RF by stratospheric
aerosols as a function of latitude for a given aerosol burden.
Let's think in terms of solar zenith angle (one has then to
integrate over SZA which is a function of latitude and season)
1/ insolation decreases with SZA as cos(theta) where theta is the
SZA
2/ air mass increases with SZA as 1/cos(theta), of course the effect this has breaks down at some point because of multiple scattering
3/ upscattering function also increases with SZA (because more
forward scattering contributes to upscattering).
You could assume 1/ and 2/ cancel each other at first
approximation, so because of 3/ there is indeed more RF at larger
SZA. In fact there is an optimum around SZA=60° but that depends
on the AOD and how much multiple scattering there is.
Now life is a bit more complicated, as transport and aerosol size
varies also.
In any case, the climate response is not a copy-paste of the
spatial distribution of the RF. It matters but not too much. And
it matters more for rapid adjustments than for feedbacks. See eg https://agupubs.onlinelibrary.wiley.com/doi/full/10.1002/2013JD021110
Regards,
Olivier
Stephen Salter
Hi All
But you also have to consider outgoing long wave radiation especially in winter.
Stephen
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Olivier Boucher
Hi Stephen,
you're correct and I'd think the negative SW RF is more offset by the positive LW RF in the tropics than in the high latitudes (alike the pattern of RF by WMGHG). But again, the pattern of a not-too-inhomogeneous forcing is only moderately important.
Regards
Olivier
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Douglas MacMartin
Agreed that the pattern of response isn’t as inhomogeneous as the forcing is, though it is still true that a uniform aerosol layer will overcool the tropics and undercool the poles, and that choosing your injection locations so that the aerosol layer is not perfectly uniform does actually maintain temperature gradients better. (But the undercooling of the poles of course is still small compared to the warming that would be there without geoengineering.)
doug
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Tamas Bodai
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