Increase in elemental carbon values between 1970 and 2004 observed in a 300-year ice core from Holtedahlfonna (Svalbard)

Ruppel, Meri; Isaksson, I.; Ström, Johan; Beaudon, Émilie; Svensson, Jonas; Pedersen, C. A.; Korhola, Atte

doi:10.5194/acp-14-11447-2014

Cited by 41 publications

(96 citation statements)

References 83 publications

(165 reference statements)

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“…The high-elevation Greenland records indicate a BC deposition peak around 1910 followed by rapidly decreasing deposition until 1950 and more or less stable, almost preindustrial values until the present (McConnell, 2010). The Svalbard ice core clearly concurs with the Greenland records for the early 20th century but unexpectedly shows a pronounced increase in BC concentrations and deposition from 1970 to the top of the core in 2004 (Ruppel et al, 2014). The reasons for the observed post-1970 BC deposition increase in Svalbard -while at the same time Greenland ice cores, atmospheric measurements (e.g.…”

Section: Introductionsupporting

confidence: 60%

“…The increasing BC deposition on the Svalbard glacier has significant effects on the radiative budget of this site and concurs with substantially increased summer melting of the glacier since the 1980s (Ruppel et al, 2014). The increased melt of the glacier is better explained by the combination of observed increasing summer temperatures and the increasing BC concentrations than by increasing temperatures alone.…”

Section: Introductionmentioning

confidence: 73%

“…Four continuous BC ice core records covering ca. 1750 to 2013 have been published from Greenland (McConnell et al, 2007;McConnell and Edwards, 2008;McConnell, 2010;Keegan et al, 2014) and one 300-year record (1700 to 2004) from Svalbard (Ruppel et al, 2014). The high-elevation Greenland records indicate a BC deposition peak around 1910 followed by rapidly decreasing deposition until 1950 and more or less stable, almost preindustrial values until the present (McConnell, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…Sharma et al, 2013) and model results (e.g. Koch et al, 2011) suggest decreasing BC values -was left partly unresolved (Ruppel et al, 2014). Increasing flaring emissions from northern Russia in the Barents Sea area that do not reach the Greenland ice coring sites due to restricted isentropic uplift in the Arctic, and potentially increasing wetscavenging efficiency due to increasing temperatures particularly around Svalbard, were the leading hypotheses (Ruppel et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…The increased melt of the glacier is better explained by the combination of observed increasing summer temperatures and the increasing BC concentrations than by increasing temperatures alone. To estimate the extent of the climatic implications suggested in Ruppel et al (2014) it is essential to solve whether the observed increasing BC deposition trend in Svalbard since 1970 can be corroborated with other data. Furthermore, it is necessary to thoroughly assess the BC sources responsible and the deposition processes associated to the observed increase because these may affect also other parts of the Arctic.…”

Section: Introductionmentioning

confidence: 99%

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Do contemporary (1980–2015) emissions determine the elemental carbon deposition trend at Holtedahlfonna glacier, Svalbard?

et al. 2017

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Abstract. The climate impact of black carbon (BC) is notably amplified in the Arctic by its deposition, which causes albedo decrease and subsequent earlier snow and ice spring melt. To comprehensively assess the climate impact of BC in the Arctic, information on both atmospheric BC concentrations and deposition is essential. Currently, Arctic BC deposition data are very scarce, while atmospheric BC concentrations have been shown to generally decrease since the 1990s. However, a 300-year Svalbard ice core showed a distinct increase in EC (elemental carbon, proxy for BC) deposition from 1970 to 2004 contradicting atmospheric measurements and modelling studies. Here, our objective was to decipher whether this increase has continued in the 21st century and to investigate the drivers of the observed EC deposition trends. For this, a shallow firn core was collected from the same Svalbard glacier, and a regional-to-meso-scale chemical transport model (SILAM) was run from 1980 to 2015. The ice and firn core data indicate peaking EC deposition values at the end of the 1990s and lower values thereafter. The modelled BC deposition results generally support the observed glacier EC variations. However, the ice and firn core results clearly deviate from both measured and modelled atmospheric BC concentration trends, and the modelled BC deposition trend shows variations seemingly independent from BC emission or atmospheric BC concentration trends. Furthermore, according to the model ca. 99 % BC mass is wet-deposited at this Svalbard glacier, indicating that meteorological processes such as precipitation and scavenging efficiency have most likely a stronger influence on the BC deposition trend than BC emission or atmospheric concentration trends. BC emission source sectors contribute differently to the modelled atmospheric BC concentrations and BC deposition, which further supports our conclusion that different processes affect atmospheric BC concentration and deposition trends. Consequently, Arctic BC deposition trends should not directly be inferred based on atmospheric BC measurements, and more observational BC deposition data are required to assess the climate impact of BC in Arctic snow.

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Section: Introductionsupporting

confidence: 60%

Section: Introductionmentioning

confidence: 73%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Do contemporary (1980–2015) emissions determine the elemental carbon deposition trend at Holtedahlfonna glacier, Svalbard?

et al. 2017

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Light‐absorbing impurities enhance glacier albedo reduction in the southeastern Tibetan plateau

et al. 2017

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Light‐absorbing impurities (LAIs) in snow of the southeastern Tibetan Plateau (TP) and their climatic impacts are of interest not only because this region borders areas affected by the South Asian atmospheric brown clouds but also because the seasonal snow and glacier melt from this region form important headwaters of large rivers. In this study, we collected surface snow and snowpit samples from four glaciers in the southeastern TP in June 2015 to investigate the comprehensive observational data set of LAIs. Results showed that the LAI concentrations were much higher in the aged snow and granular ice than in the fresh snow and snowpits due to postdepositional processes. Impurity concentrations fluctuated across snowpits, with maximum LAI concentrations frequently occurring toward the bottom of snowpits. Based on the SNow ICe Aerosol Radiative model, the albedo simulation indicated that black carbon and dust account for approximately 20% of the albedo reduction relative to clean snow. The radiative forcing caused by black carbon and dust deposition on the glaciers were between 1.0–141 W m−2 and 1.5–120 W m−2, respectively. Black carbon (BC) played a larger role in albedo reduction and radiative forcing than dust in the study area, enhancing approximately 15% of glacier melt. Analysis based on the Fire INventory from NCAR indicated that nonbiomass‐burning sources of BC played an important role in the total BC deposition, especially during the monsoon season. This study suggests that eliminating anthropogenic BC could mitigate glacier melt in the future of the southeastern TP.

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Assessment of Black Carbon in Arctic: Current Status and Potential Improvements

Soares

Geels

Langner

et al. 2017

Air Pollution Modeling and Its Application XXV

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Increase in elemental carbon values between 1970 and 2004 observed in a 300-year ice core from Holtedahlfonna (Svalbard)

Cited by 41 publications

References 83 publications

Do contemporary (1980–2015) emissions determine the elemental carbon deposition trend at Holtedahlfonna glacier, Svalbard?

Do contemporary (1980–2015) emissions determine the elemental carbon deposition trend at Holtedahlfonna glacier, Svalbard?

Light‐absorbing impurities enhance glacier albedo reduction in the southeastern Tibetan plateau

Assessment of Black Carbon in Arctic: Current Status and Potential Improvements

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