Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model

<p>Historically, aerosols of anthropogenic origin have offset some of the warming from increased atmospheric greenhouse gas concentrations. The strength of this negative aerosol forcing, however, is highly uncertain – especially the part originating from cloud–aerosol interactions. An importan...

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Autores principales: S. M. Blichner, M. K. Sporre, T. K. Berntsen
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Publicado: Copernicus Publications 2021
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spelling oai:doaj.org-article:67704069f4a248cfaa16b3ea4b43f1212021-11-29T11:08:11ZReduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model10.5194/acp-21-17243-20211680-73161680-7324https://doaj.org/article/67704069f4a248cfaa16b3ea4b43f1212021-11-01T00:00:00Zhttps://acp.copernicus.org/articles/21/17243/2021/acp-21-17243-2021.pdfhttps://doaj.org/toc/1680-7316https://doaj.org/toc/1680-7324<p>Historically, aerosols of anthropogenic origin have offset some of the warming from increased atmospheric greenhouse gas concentrations. The strength of this negative aerosol forcing, however, is highly uncertain – especially the part originating from cloud–aerosol interactions. An important part of this uncertainty originates from our lack of knowledge about pre-industrial aerosols and how many of these would have acted as cloud condensation nuclei (CCN). In order to simulate CCN concentrations in models, we must adequately model secondary aerosols, including new particle formation (NPF) and early growth, which contributes a large part of atmospheric CCN. In this study, we investigate the effective radiative forcing (ERF) from cloud–aerosol interactions (<span class="inline-formula">ERF<sub>aci</sub></span>) with an improved treatment of early particle growth, as presented in <span class="cit" id="xref_text.1"><a href="#bib1.bibx9">Blichner et al.</a> (<a href="#bib1.bibx9">2021</a>)</span>. We compare the improved scheme to the default scheme, OsloAero, which are both embedded in the atmospheric component of the Norwegian Earth System Model v2 (NorESM2). The improved scheme, OsloAeroSec, includes a sectional scheme that treats the growth of particles from 5–39.6 <span class="inline-formula">nm</span> in diameter, which thereafter inputs the particles to the smallest mode in the pre-existing modal aerosol scheme. The default scheme parameterizes the growth of particles from nucleation up to the smallest mode, a process that can take several hours. The explicit treatment of early growth in OsloAeroSec, on the other hand, captures the changes in atmospheric conditions during this growth time in terms of air mass mixing, transport, and condensation and coagulation.</p> <p>We find that the <span class="inline-formula">ERF<sub>aci</sub></span> with the sectional scheme is <span class="inline-formula">−</span>1.16 <span class="inline-formula">W m<sup>−2</sup></span>, which is 0.13 <span class="inline-formula">W m<sup>−2</sup></span> weaker compared to the default scheme. This reduction originates from OsloAeroSec producing more particles than the default scheme in pristine, low-aerosol-concentration areas and fewer NPF particles in high-aerosol areas. We find, perhaps surprisingly, that NPF inhibits cloud droplet activation in polluted and/or high-aerosol-concentration regions because the NPF particles increase the condensation sink and reduce the growth of the larger particles which may otherwise activate. This means that in these high-aerosol regions, the model with the lowest NPF – OsloAeroSec – will have the highest cloud droplet activation and thus more reflective clouds. In pristine and/or low-aerosol regions, however, NPF enhances cloud droplet activation because the NPF particles themselves tend to activate.</p> <p>Lastly, we find that sulfate emissions in the present-day simulations increase the hygroscopicity of secondary aerosols compared to pre-industrial simulations. This makes NPF particles more relevant for cloud droplet activation in the present day than the pre-industrial atmosphere because increased hygroscopicity means they can activate at smaller sizes.</p>S. M. BlichnerM. K. SporreT. K. BerntsenCopernicus PublicationsarticlePhysicsQC1-999ChemistryQD1-999ENAtmospheric Chemistry and Physics, Vol 21, Pp 17243-17265 (2021)
institution DOAJ
collection DOAJ
language EN
topic Physics
QC1-999
Chemistry
QD1-999
spellingShingle Physics
QC1-999
Chemistry
QD1-999
S. M. Blichner
M. K. Sporre
T. K. Berntsen
Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
description <p>Historically, aerosols of anthropogenic origin have offset some of the warming from increased atmospheric greenhouse gas concentrations. The strength of this negative aerosol forcing, however, is highly uncertain – especially the part originating from cloud–aerosol interactions. An important part of this uncertainty originates from our lack of knowledge about pre-industrial aerosols and how many of these would have acted as cloud condensation nuclei (CCN). In order to simulate CCN concentrations in models, we must adequately model secondary aerosols, including new particle formation (NPF) and early growth, which contributes a large part of atmospheric CCN. In this study, we investigate the effective radiative forcing (ERF) from cloud–aerosol interactions (<span class="inline-formula">ERF<sub>aci</sub></span>) with an improved treatment of early particle growth, as presented in <span class="cit" id="xref_text.1"><a href="#bib1.bibx9">Blichner et al.</a> (<a href="#bib1.bibx9">2021</a>)</span>. We compare the improved scheme to the default scheme, OsloAero, which are both embedded in the atmospheric component of the Norwegian Earth System Model v2 (NorESM2). The improved scheme, OsloAeroSec, includes a sectional scheme that treats the growth of particles from 5–39.6 <span class="inline-formula">nm</span> in diameter, which thereafter inputs the particles to the smallest mode in the pre-existing modal aerosol scheme. The default scheme parameterizes the growth of particles from nucleation up to the smallest mode, a process that can take several hours. The explicit treatment of early growth in OsloAeroSec, on the other hand, captures the changes in atmospheric conditions during this growth time in terms of air mass mixing, transport, and condensation and coagulation.</p> <p>We find that the <span class="inline-formula">ERF<sub>aci</sub></span> with the sectional scheme is <span class="inline-formula">−</span>1.16 <span class="inline-formula">W m<sup>−2</sup></span>, which is 0.13 <span class="inline-formula">W m<sup>−2</sup></span> weaker compared to the default scheme. This reduction originates from OsloAeroSec producing more particles than the default scheme in pristine, low-aerosol-concentration areas and fewer NPF particles in high-aerosol areas. We find, perhaps surprisingly, that NPF inhibits cloud droplet activation in polluted and/or high-aerosol-concentration regions because the NPF particles increase the condensation sink and reduce the growth of the larger particles which may otherwise activate. This means that in these high-aerosol regions, the model with the lowest NPF – OsloAeroSec – will have the highest cloud droplet activation and thus more reflective clouds. In pristine and/or low-aerosol regions, however, NPF enhances cloud droplet activation because the NPF particles themselves tend to activate.</p> <p>Lastly, we find that sulfate emissions in the present-day simulations increase the hygroscopicity of secondary aerosols compared to pre-industrial simulations. This makes NPF particles more relevant for cloud droplet activation in the present day than the pre-industrial atmosphere because increased hygroscopicity means they can activate at smaller sizes.</p>
format article
author S. M. Blichner
M. K. Sporre
T. K. Berntsen
author_facet S. M. Blichner
M. K. Sporre
T. K. Berntsen
author_sort S. M. Blichner
title Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
title_short Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
title_full Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
title_fullStr Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
title_full_unstemmed Reduced effective radiative forcing from cloud–aerosol interactions (ERF<sub>aci</sub>) with improved treatment of early aerosol growth in an Earth system model
title_sort reduced effective radiative forcing from cloud–aerosol interactions (erf<sub>aci</sub>) with improved treatment of early aerosol growth in an earth system model
publisher Copernicus Publications
publishDate 2021
url https://doaj.org/article/67704069f4a248cfaa16b3ea4b43f121
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AT mksporre reducedeffectiveradiativeforcingfromcloudaerosolinteractionserfsubacisubwithimprovedtreatmentofearlyaerosolgrowthinanearthsystemmodel
AT tkberntsen reducedeffectiveradiativeforcingfromcloudaerosolinteractionserfsubacisubwithimprovedtreatmentofearlyaerosolgrowthinanearthsystemmodel
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