Annual distributions and sources of Arctic aerosol components, aerosol optical depth, and aerosol absorption

Breider, T. J.; Mickley, Loretta J.; Jacob, Daniel J.; Wang, Qiaoqiao; Fisher, Jenny A.; Chang, Rachel Y.-­W.; Alexander, Becky

doi:10.1002/2013jd020996

Cited by 97 publications

(122 citation statements)

References 141 publications

(190 reference statements)

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“…The major transport pathway of North American emissions to the Arctic follows constant potential temperatures, which cause cloud formation and precipitation, hence higher wet scavenging of aerosols. Brock et al, 2011, McConnell, 2007, Stohl, 2006, Breider et al, 2014and Liu et al, 2015 show similar low contributions of North American Anthropogenic emission to the Arctic surface concentration. Less than 5% percent of emissions are transported from each of South Asia and the Middle East to the Arctic.…”

Section: Geographical Source Contribution To Pm Concentrationmentioning

confidence: 80%

“…However, 10 during the past two decades emissions from East Asia have increased rapidly due to the vast economic growth, while the emissions from Europe have declined during the same time period (Streets et al, 2009). Recent studies have shown the significant contribution of Asian emissions to the Arctic, especially during winter-spring (Breider et al, 2014;Fisher et al, 2010;Koch and Hansen, 2005;Shindell et al, 2008;Stohl, 2006;Wang et al, 2011).…”

mentioning

confidence: 99%

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Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic

Sobhani¹,

Kulkarni²,

Carmichael³

2018

Preprint

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The impacts of BC and PM 2.5 emissions from different source sectors (e.g. transportation, power, 10 industry, residential, and biomass burning) and source regions (e.g. Europe, North America, China, Russia, Central Asia, South Asia, and the Middle East) to Arctic BC and PM 2.5 concentrations are investigated using a series of sensitivity runs with WRF-STEM modeling framework. The simulations are validated using aircraft observations over the Arctic during spring and summer 2008. Emissions from power, industrial, and biomass burning sectors are found to be the main contributors to the Arctic PM 2.5 with contributions of ~30%, ~25%, and 15 ~20% respectively. In contrast, the residential and transportation sectors are identified as the major contributors to Arctic BC with contributions of ~38% and ~30%. Anthropogenic emissions are the most dominant contributors (~88%) to the BC surface concentration over the Arctic; however, the contribution from biomass burning is significant over the summer (up to ~50%). Among all geographical regions, Europe and China have the highest contributions to the BC surface concentrations with contributions of ~46% and ~25% respectively. 20Further sensitivity runs show that among various economic sectors of all geographic regions, European and Chinese residential sector contribute up to ~25% and ~14% to the Arctic average surface BC concentration. For Arctic PM2.5, the anthropogenic emissions contribute > ~75% at the surface annually, with contributions of ~25% from Europe and ~20% from China; however, the contributions of biomass burning emissions are Atmos. Chem. Phys. Discuss., https://doi.org/10.5194/acp-2018-65 Manuscript under review for journal Atmos. Chem. Phys.

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Section: Geographical Source Contribution To Pm Concentrationmentioning

confidence: 80%

mentioning

confidence: 99%

Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic

Sobhani¹,

Kulkarni²,

Carmichael³

2018

Preprint

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“…Stohl, 2006;Shindel et al, 2008;Hirdman et al, 2010;Wang et al, 2014) while others found eastern and southern Asia had the largest contribution (Koch and Hansen, 2005;Ikeda et al, 2017). Some studies suggested that Europe was the dominant source of BC aloft (Stohl, 2006;Huang et al, 2010b) while others found eastern and southern Asia was the most important source (Sharma et al, 2013;Breider et al, 2014;Wang et al, 2014;Ikeda et al, 2017) in the middle troposphere. Recent work by Stohl et al (2013) and Sand et al (2016) raised questions about prior studies by identifying the importance of seasonally varying residential heating and by suggesting a significant overlooked source from gas flaring in high-latitude regions.…”

Section: Introductionmentioning

confidence: 97%

“…We subsequently use the adjoint of the GEOS-Chem model to investigate the spatially resolved sensitivity of Arctic BC column concentrations to global emissions. Our work builds on knowledge gained from previous GEOS-Chem studies of Arctic BC (Wang et al, 2011;Breider et al, 2014Breider et al, , 2017Qi et al, 2017a, b) with major improvements, including (1) new airborne measurements during 2009, 2011 and 2015 when more typical fires than in previous studies foster better understanding of anthropogenic source contributions to the Arctic; (2) new refractory BC (rBC) measurements in the Arctic more accurately constrain emissions in simulations; (3) more recent and improved emissions better represent the global redistribution of BC emissions and include flaring and seasonal emissions of residential heating; and (4) seasonal source attribution using the adjoint of GEOS-Chem reveals the importance of specific sources. Bond et al (1999) and is further reduced by 30 % at all stations following Sinha et al (2017).…”

Section: Introductionmentioning

confidence: 99%

Source attribution of Arctic black carbon constrained by aircraft and surface measurements

Martin

Morrow

et al. 2017

Atmos. Chem. Phys.

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Abstract. Black carbon (BC) contributes to Arctic warming, yet sources of Arctic BC and their geographic contributions remain uncertain. We interpret a series of recent airborne (NETCARE 2015; PAMARCMiP 2009 and 2011 campaigns) and ground-based measurements (at Alert, Barrow and Ny-Ålesund) from multiple methods (thermal, laser incandescence and light absorption) with the GEOS-Chem global chemical transport model and its adjoint to attribute the sources of Arctic BC. This is the first comparison with a chemical transport model of refractory BC (rBC) measurements at Alert. The springtime airborne measurements performed by the NETCARE campaign in 2015 and the PAMARCMiP campaigns in 2009 and 2011 offer BC vertical profiles extending to above 6 km across the Arctic and include profiles above Arctic ground monitoring stations. Our simulations with the addition of seasonally varying domestic heating and of gas flaring emissions are consistent with ground-based measurements of BC concentrations at Alert and Barrow in winter and spring (rRMSE < 13 %) and with airborne measurements of the BC vertical profile across the Arctic (rRMSE = 17 %) except for an underestimation in the middle troposphere (500-700 hPa).Sensitivity simulations suggest that anthropogenic emissions in eastern and southern Asia have the largest effect on the Arctic BC column burden both in spring (56 %) and annually (37 %), with the largest contribution in the middle troposphere (400-700 hPa). Anthropogenic emissions from northern Asia contribute considerable BC (27 % in spring and 43 % annually) to the lower troposphere (below 900 hPa). Biomass burning contributes 20 % to the Arctic BC column annually.At the Arctic surface, anthropogenic emissions from northern Asia (40-45 %) and eastern and southern Asia (20-40 %) are the largest BC contributors in winter and spring, followed by Europe (16-36 %). Biomass burning from North America is the most important contributor to all stations in summer, especially at Barrow.Our adjoint simulations indicate pronounced spatial heterogeneity in the contribution of emissions to the Arctic BC column concentrations, with noteworthy contributions from emissions in eastern China (15 %) and western Siberia (6.5 %). Although uncertain, gas flaring emissions from oilfields in western Siberia could have a striking impact (13 %) on Arctic BC loadings in January, comparable to the total influence of continental Europe and North America (6.5 % each in January). Emissions from as far as the Indo-Gangetic Plain could have a substantial influence (6.3 % annually) on Arctic BC as well.

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“…Long range transport could also have brought Saharan dust to the region (e.g. Breider et al, 2014), and this was seen during the Spring campaign of the ACCACIA project 15 (Young et al 2016b), though the temperature of the clouds reported here did not go below -12 °C and so any dust particle present would likely not act as INP.…”

Section: Potential Sources Of Aerosol/in For This Projectmentioning

confidence: 76%

Summertime Arctic Aircraft Measurements during ACCACIA

Jones

Young

Choularton

et al. 2018

Preprint

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Abstract. Arctic Climate is not represented with a high degree of certainty in current climate; part of this is due to Arctic clouds not being well modelled. There have been very few in-situ measurements in the region until recent years, where coverage still remains sparse. Whilst a lot is known regarding lower latitude cloud microphysics, the same cannot be said for 15Arctic cloud microphysics where cloud interactions and feedback mechanisms are known to vary from those at lower latitudes. This paper reports data from the 2013 ACCACIA project where aerosol and cloud data were collected over eight flights sampling in the region around Svalbard during July.Clouds from six out of the eight flights were found to be mixed phase to some extent, with in-cloud flight-mean droplet number concentrations ranging from 21.7 -132 cm -3 across all flights where clouds were sampled between 262 and 283 K. 20Cloud droplet diameter was found to increase from cloud base to cloud top within sampled stratocumulus layers which were noted to lift and deepen when moving out from over the sea-ice to over the open ocean. Cloud ice particles concentrations, when present, ranged from 0.42 -0.88 L -1 , with irregular, stellar and columnar habits noted. Results suggest a small number of ice nucleating particles were active in the region, with conditions intermittently present such that secondary ice processes were able to glaciate small portions of the cloud. 25The purpose of this paper is to provide a more extensive range of data for the development of improved parameterisations for use in models applied to Polar regions.

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Annual distributions and sources of Arctic aerosol components, aerosol optical depth, and aerosol absorption

Cited by 97 publications

References 141 publications

Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic

Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic

Source attribution of Arctic black carbon constrained by aircraft and surface measurements

Summertime Arctic Aircraft Measurements during ACCACIA

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Annual distributions and sources of Arctic aerosol components, aerosol optical depth, and aerosol absorption

Cited by 97 publications

References 141 publications

Source Sector and Region Contributions to Black Carbon and PM&lt;sub&gt;2.5&lt;/sub&gt; in the Arctic

Source Sector and Region Contributions to Black Carbon and PM&lt;sub&gt;2.5&lt;/sub&gt; in the Arctic

Source attribution of Arctic black carbon constrained by aircraft and surface measurements

Summertime Arctic Aircraft Measurements during ACCACIA

Contact Info

Product

Resources

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Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic

Source Sector and Region Contributions to Black Carbon and PM<sub>2.5</sub> in the Arctic