SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2897383996> ?p ?o ?g. }

Showing items 1 to 100 of ±133 with 100 items per page.

W2897383996 endingPage "4782" @default.
W2897383996 startingPage "4763" @default.
W2897383996 abstract "Abstract. Both higher temperatures and increased CO2 concentrations are (separately) expected to increase the emissions of biogenic volatile organic compounds (BVOCs). This has been proposed to initiate negative climate feedback mechanisms through increased formation of secondary organic aerosol (SOA). More SOA can make the clouds more reflective, which can provide a cooling. Furthermore, the increase in SOA formation has also been proposed to lead to increased aerosol scattering, resulting in an increase in diffuse radiation. This could boost gross primary production (GPP) and further increase BVOC emissions. In this study, we have used the Norwegian Earth System Model (NorESM) to investigate both these feedback mechanisms. Three sets of experiments were set up to quantify the feedback with respect to (1) doubling the CO2, (2) increasing temperatures corresponding to a doubling of CO2 and (3) the combined effect of both doubling CO2 and a warmer climate. For each of these experiments, we ran two simulations, with identical setups, except for the BVOC emissions. One simulation was run with interactive BVOC emissions, allowing the BVOC emissions to respond to changes in CO2 and/or climate. In the other simulation, the BVOC emissions were fixed at present-day conditions, essentially turning the feedback off. The comparison of these two simulations enables us to investigate each step along the feedback as well as estimate their overall relevance for the future climate. We find that the BVOC feedback can have a significant impact on the climate. The annual global BVOC emissions are up to 63 % higher when the feedback is turned on compared to when the feedback is turned off, with the largest response when both CO2 and climate are changed. The higher BVOC levels lead to the formation of more SOA mass (max 53 %) and result in more particles through increased new particle formation as well as larger particles through increased condensation. The corresponding changes in the cloud properties lead to a −0.43 W m−2 stronger net cloud forcing. This effect becomes about 50 % stronger when the model is run with reduced anthropogenic aerosol emissions, indicating that the feedback will become even more important as we decrease aerosol and precursor emissions. We do not find a boost in GPP due to increased aerosol scattering on a global scale. Instead, the fate of the GPP seems to be controlled by the BVOC effects on the clouds. However, the higher aerosol scattering associated with the higher BVOC emissions is found to also contribute with a potentially important enhanced negative direct forcing (−0.06 W m−2). The global total aerosol forcing associated with the feedback is −0.49 W m−2, indicating that it has the potential to offset about 13 % of the forcing associated with a doubling of CO2." @default.
W2897383996 created "2018-10-26" @default.
W2897383996 creator A5033256691 @default.
W2897383996 creator A5041537001 @default.
W2897383996 creator A5044622388 @default.
W2897383996 creator A5071572483 @default.
W2897383996 creator A5086592897 @default.
W2897383996 date "2019-04-09" @default.
W2897383996 modified "2023-10-16" @default.
W2897383996 title "BVOC–aerosol–climate feedbacks investigated using NorESM" @default.
W2897383996 cites W1497333048 @default.
W2897383996 cites W1504241111 @default.
W2897383996 cites W1781459411 @default.
W2897383996 cites W1894456890 @default.
W2897383996 cites W1975196041 @default.
W2897383996 cites W1979541009 @default.
W2897383996 cites W1984153926 @default.
W2897383996 cites W1990701514 @default.
W2897383996 cites W2004811960 @default.
W2897383996 cites W2013350969 @default.
W2897383996 cites W2018735695 @default.
W2897383996 cites W2022224360 @default.
W2897383996 cites W2024612183 @default.
W2897383996 cites W2025051238 @default.
W2897383996 cites W2030454113 @default.
W2897383996 cites W2040716772 @default.
W2897383996 cites W2051257671 @default.
W2897383996 cites W2052697879 @default.
W2897383996 cites W2064943738 @default.
W2897383996 cites W2066373811 @default.
W2897383996 cites W2067209936 @default.
W2897383996 cites W2068755216 @default.
W2897383996 cites W2078844631 @default.
W2897383996 cites W2096884373 @default.
W2897383996 cites W2098921391 @default.
W2897383996 cites W2103672978 @default.
W2897383996 cites W2106179545 @default.
W2897383996 cites W2108110404 @default.
W2897383996 cites W2110879771 @default.
W2897383996 cites W2112042999 @default.
W2897383996 cites W2118800194 @default.
W2897383996 cites W2120532631 @default.
W2897383996 cites W2141208140 @default.
W2897383996 cites W2148999460 @default.
W2897383996 cites W2149129262 @default.
W2897383996 cites W2151162783 @default.
W2897383996 cites W2151494953 @default.
W2897383996 cites W2153226382 @default.
W2897383996 cites W2158669608 @default.
W2897383996 cites W2161205508 @default.
W2897383996 cites W2262384140 @default.
W2897383996 cites W2496912199 @default.
W2897383996 cites W2498438570 @default.
W2897383996 cites W2531463405 @default.
W2897383996 cites W2587033537 @default.
W2897383996 cites W2590594233 @default.
W2897383996 cites W2614250595 @default.
W2897383996 cites W2727678863 @default.
W2897383996 cites W2766769544 @default.
W2897383996 cites W2772454161 @default.
W2897383996 cites W2781956999 @default.
W2897383996 cites W2784338218 @default.
W2897383996 cites W2795034097 @default.
W2897383996 cites W2807209884 @default.
W2897383996 cites W2887490719 @default.
W2897383996 cites W2955601895 @default.
W2897383996 doi "https://doi.org/10.5194/acp-19-4763-2019" @default.
W2897383996 hasPublicationYear "2019" @default.
W2897383996 type Work @default.
W2897383996 sameAs 2897383996 @default.
W2897383996 citedByCount "42" @default.
W2897383996 countsByYear W28973839962019 @default.
W2897383996 countsByYear W28973839962020 @default.
W2897383996 countsByYear W28973839962021 @default.
W2897383996 countsByYear W28973839962022 @default.
W2897383996 countsByYear W28973839962023 @default.
W2897383996 crossrefType "journal-article" @default.
W2897383996 hasAuthorship W2897383996A5033256691 @default.
W2897383996 hasAuthorship W2897383996A5041537001 @default.
W2897383996 hasAuthorship W2897383996A5044622388 @default.
W2897383996 hasAuthorship W2897383996A5071572483 @default.
W2897383996 hasAuthorship W2897383996A5086592897 @default.
W2897383996 hasBestOaLocation W28973839961 @default.
W2897383996 hasConcept C121332964 @default.
W2897383996 hasConcept C127313418 @default.
W2897383996 hasConcept C132651083 @default.
W2897383996 hasConcept C153294291 @default.
W2897383996 hasConcept C168754636 @default.
W2897383996 hasConcept C18903297 @default.
W2897383996 hasConcept C2779345167 @default.
W2897383996 hasConcept C2988944679 @default.
W2897383996 hasConcept C39432304 @default.
W2897383996 hasConcept C49204034 @default.
W2897383996 hasConcept C86803240 @default.
W2897383996 hasConcept C91586092 @default.
W2897383996 hasConceptScore W2897383996C121332964 @default.
W2897383996 hasConceptScore W2897383996C127313418 @default.
W2897383996 hasConceptScore W2897383996C132651083 @default.