Effects of black carbon mitigation on Arctic climate
<p>We use the ECHAM-HAMMOZ aerosol-climate model to assess the effects of black carbon (BC) mitigation measures on Arctic climate. To this end we constructed several mitigation scenarios that implement all currently existing legislation and then implement further reductions of BC in a successi...
| Main Authors: | , , , , , , , , , , |
|---|---|
| Format: | Article |
| Language: | English |
| Published: |
Copernicus Publications
2020-05-01
|
| Series: | Atmospheric Chemistry and Physics |
| Online Access: | https://www.atmos-chem-phys.net/20/5527/2020/acp-20-5527-2020.pdf |
| id |
doaj-cf2c989d1e25438ba7d5414d049f0f8c |
|---|---|
| record_format |
Article |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
T. Kühn T. Kühn K. Kupiainen K. Kupiainen T. Miinalainen H. Kokkola V.-V. Paunu A. Laakso J. Tonttila R. Van Dingenen K. Kulovesi N. Karvosenoja K. E. J. Lehtinen K. E. J. Lehtinen |
| spellingShingle |
T. Kühn T. Kühn K. Kupiainen K. Kupiainen T. Miinalainen H. Kokkola V.-V. Paunu A. Laakso J. Tonttila R. Van Dingenen K. Kulovesi N. Karvosenoja K. E. J. Lehtinen K. E. J. Lehtinen Effects of black carbon mitigation on Arctic climate Atmospheric Chemistry and Physics |
| author_facet |
T. Kühn T. Kühn K. Kupiainen K. Kupiainen T. Miinalainen H. Kokkola V.-V. Paunu A. Laakso J. Tonttila R. Van Dingenen K. Kulovesi N. Karvosenoja K. E. J. Lehtinen K. E. J. Lehtinen |
| author_sort |
T. Kühn |
| title |
Effects of black carbon mitigation on Arctic climate |
| title_short |
Effects of black carbon mitigation on Arctic climate |
| title_full |
Effects of black carbon mitigation on Arctic climate |
| title_fullStr |
Effects of black carbon mitigation on Arctic climate |
| title_full_unstemmed |
Effects of black carbon mitigation on Arctic climate |
| title_sort |
effects of black carbon mitigation on arctic climate |
| publisher |
Copernicus Publications |
| series |
Atmospheric Chemistry and Physics |
| issn |
1680-7316 1680-7324 |
| publishDate |
2020-05-01 |
| description |
<p>We use the ECHAM-HAMMOZ aerosol-climate model to assess the effects of black carbon (BC) mitigation
measures on Arctic climate. To this end we constructed several mitigation scenarios that implement all currently existing
legislation and then implement further reductions of BC in a
successively increasing global area, starting from the eight member states of the Arctic Council,
expanding to its active observer states, then to all observer states, and finally to the entire globe. These scenarios also account for the reduction of the co-emitted organic carbon (OC) and
sulfate (SU). We find that, even though the additional BC emission reductions in the member states of the Arctic
Council are small, the resulting reductions in Arctic BC mass burdens can be substantial, especially
in the lower troposphere close to the surface. This in turn means that reducing BC emissions only in the Arctic Council member states can reduce
BC deposition in the Arctic by about 30 % compared to the current legislation,
which is about 60 % of what could be achieved if emissions were reduced
globally. Emission reductions further south affect Arctic BC concentrations at higher altitudes and thus
only have small additional effects on BC deposition in the Arctic. The direct radiative forcing scales fairly well with the total amount of BC emission reduction,
independent of the location of the emission source, with a maximum direct radiative forcing
in the Arctic of about <span class="inline-formula">−0.4</span> W m<span class="inline-formula"><sup>−2</sup></span> for a global BC emission reduction.
On the other hand, the Arctic effective radiative forcing due to the BC emission reductions,
which accounts for aerosol–cloud interactions, is small compared to the direct aerosol
radiative forcing. This happens because BC- and OC-containing particles can act as cloud condensation
nuclei, which affects cloud reflectivity and lifetime and counteracts the direct radiative
forcing of BC. Additionally, the effective radiative forcing is accompanied by very large uncertainties that
originate from the strong natural variability of meteorology, cloud cover, and surface albedo in the
Arctic. We further used the TM5-FASST model to assess the benefits of the aerosol emission reductions
for human health. We found that a full implementation in all Arctic Council member and observer states could
reduce the annual global number of premature deaths by
329 000 by the year 2030, which amounts to
9 % of the total global premature deaths due to particulate matter.</p> |
| url |
https://www.atmos-chem-phys.net/20/5527/2020/acp-20-5527-2020.pdf |
| work_keys_str_mv |
AT tkuhn effectsofblackcarbonmitigationonarcticclimate AT tkuhn effectsofblackcarbonmitigationonarcticclimate AT kkupiainen effectsofblackcarbonmitigationonarcticclimate AT kkupiainen effectsofblackcarbonmitigationonarcticclimate AT tmiinalainen effectsofblackcarbonmitigationonarcticclimate AT hkokkola effectsofblackcarbonmitigationonarcticclimate AT vvpaunu effectsofblackcarbonmitigationonarcticclimate AT alaakso effectsofblackcarbonmitigationonarcticclimate AT jtonttila effectsofblackcarbonmitigationonarcticclimate AT rvandingenen effectsofblackcarbonmitigationonarcticclimate AT kkulovesi effectsofblackcarbonmitigationonarcticclimate AT nkarvosenoja effectsofblackcarbonmitigationonarcticclimate AT kejlehtinen effectsofblackcarbonmitigationonarcticclimate AT kejlehtinen effectsofblackcarbonmitigationonarcticclimate |
| _version_ |
1724716944439902208 |
| spelling |
doaj-cf2c989d1e25438ba7d5414d049f0f8c2020-11-25T02:55:17ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242020-05-01205527554610.5194/acp-20-5527-2020Effects of black carbon mitigation on Arctic climateT. Kühn0T. Kühn1K. Kupiainen2K. Kupiainen3T. Miinalainen4H. Kokkola5V.-V. Paunu6A. Laakso7J. Tonttila8R. Van Dingenen9K. Kulovesi10N. Karvosenoja11K. E. J. Lehtinen12K. E. J. Lehtinen13Department of Applied Physics, University of Eastern Finland (UEF), Kuopio, FinlandAtmospheric Research Centre of Eastern Finland, Finnish Meteorological Institute (FMI), Kuopio, FinlandFinnish Environment Institute (SYKE), Helsinki, Finlandcurrently at: the Finnish Ministry of the Environment, Helsinki, FinlandDepartment of Applied Physics, University of Eastern Finland (UEF), Kuopio, FinlandAtmospheric Research Centre of Eastern Finland, Finnish Meteorological Institute (FMI), Kuopio, FinlandFinnish Environment Institute (SYKE), Helsinki, FinlandAtmospheric Research Centre of Eastern Finland, Finnish Meteorological Institute (FMI), Kuopio, FinlandAtmospheric Research Centre of Eastern Finland, Finnish Meteorological Institute (FMI), Kuopio, FinlandEuropean Commission, Joint Research Centre (JRC), Ispra (VA), ItalySchool of Law, University of Eastern Finland (UEF), Joensuu, FinlandFinnish Environment Institute (SYKE), Helsinki, FinlandDepartment of Applied Physics, University of Eastern Finland (UEF), Kuopio, FinlandAtmospheric Research Centre of Eastern Finland, Finnish Meteorological Institute (FMI), Kuopio, Finland<p>We use the ECHAM-HAMMOZ aerosol-climate model to assess the effects of black carbon (BC) mitigation measures on Arctic climate. To this end we constructed several mitigation scenarios that implement all currently existing legislation and then implement further reductions of BC in a successively increasing global area, starting from the eight member states of the Arctic Council, expanding to its active observer states, then to all observer states, and finally to the entire globe. These scenarios also account for the reduction of the co-emitted organic carbon (OC) and sulfate (SU). We find that, even though the additional BC emission reductions in the member states of the Arctic Council are small, the resulting reductions in Arctic BC mass burdens can be substantial, especially in the lower troposphere close to the surface. This in turn means that reducing BC emissions only in the Arctic Council member states can reduce BC deposition in the Arctic by about 30 % compared to the current legislation, which is about 60 % of what could be achieved if emissions were reduced globally. Emission reductions further south affect Arctic BC concentrations at higher altitudes and thus only have small additional effects on BC deposition in the Arctic. The direct radiative forcing scales fairly well with the total amount of BC emission reduction, independent of the location of the emission source, with a maximum direct radiative forcing in the Arctic of about <span class="inline-formula">−0.4</span> W m<span class="inline-formula"><sup>−2</sup></span> for a global BC emission reduction. On the other hand, the Arctic effective radiative forcing due to the BC emission reductions, which accounts for aerosol–cloud interactions, is small compared to the direct aerosol radiative forcing. This happens because BC- and OC-containing particles can act as cloud condensation nuclei, which affects cloud reflectivity and lifetime and counteracts the direct radiative forcing of BC. Additionally, the effective radiative forcing is accompanied by very large uncertainties that originate from the strong natural variability of meteorology, cloud cover, and surface albedo in the Arctic. We further used the TM5-FASST model to assess the benefits of the aerosol emission reductions for human health. We found that a full implementation in all Arctic Council member and observer states could reduce the annual global number of premature deaths by 329 000 by the year 2030, which amounts to 9 % of the total global premature deaths due to particulate matter.</p>https://www.atmos-chem-phys.net/20/5527/2020/acp-20-5527-2020.pdf |