Refractory black carbon (rBC) variability in a 47-year West Antarctic snow and firn core

Marquetto, Luciano; Kaspari, Susan; Simões, Jefferson Cárdia

doi:10.5194/tc-14-1537-2020

Cited by 12 publications

(32 citation statements)

References 67 publications

(142 reference statements)

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“…The impact of snow impurities is assumed negligible for Antarctica and thus we set d α c = 0 (Bisiaux et al., 2012; Grenfell et al., 1994; Marquetto et al., 2020; Warren & Clarke, 1990). Jakobs et al.…”

Section: Methodsmentioning

confidence: 99%

Spatial Variability of the Snowmelt‐Albedo Feedback in Antarctica

et al. 2021

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Surface melt is an important process for the stability of ice shelves, and therewith the Antarctic ice sheet. In Antarctica, absorption of solar radiation is mostly the largest energy source for surface melt, which is further enhanced by the snowmelt‐albedo feedback (SMAF): Refrozen snow has a lower albedo than new snow, which causes it to absorb more solar radiation, further increasing the energy available for surface melt. This feedback has previously been shown to increase surface melt by approximately a factor of 2.5 at Neumayer Station in East Antarctica. In this study, we use a regional climate model to quantify SMAF for the entire Antarctic ice sheet. We find that it is most effective on ice shelves in East Antarctica, and is less important in the Antarctic Peninsula and on the Ross and Filchner‐Ronne ice shelves. We identify a relationship between SMAF and average summer 2 m air temperatures, and find that SMAF is most important around 265 ± 2 K. On a subseasonal scale, we identify several parameters that contribute to SMAF: the length of dry periods, the time between significant snowfall events and snowmelt events, and prevailing temperatures. We then apply the same temperature dependency of SMAF to the Greenland ice sheet and find that it is potentially active in a narrow band around the ice sheet, and finally discuss how the importance of SMAF could change in a warming climate.

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Section: Methodsmentioning

confidence: 99%

Spatial Variability of the Snowmelt‐Albedo Feedback in Antarctica

et al. 2021

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“…Considering the low BC concentration in the samples, especially in the wet season (as low as 200 detected particles/sample), we present our results as a grouping of individual samples in 94 seasonally resolved clusters (wet season subset = summer/fall, 474 samples and 47 clusters; dry season subset = winter/spring, 530 samples and 47 clusters). The number of clusters is due to the estimated dating of the core (47 years, Marquetto, Kaspari, & Simões, 2020). Although the dry season subset presented considerably more particles ( n = 8.28 × 10 5 ) than the wet season subset ( n = 2.03 × 10 5 ), both have a robust number of collected particles.…”

Section: Methodsmentioning

confidence: 99%

“…Seasonal sample discrimination was based on the core dating presented in Marquetto, Kaspari, and Simões (2020). Antarctic ice core BC records show a well‐defined seasonality, with peak concentrations in the dry season due to increased biomass burning activity in the Southern Hemisphere (SH) during this time of the year (Bisiaux, Edwards, McConnell, Curran, et al, 2012; Sand et al, 2017; Winstrup et al, 2019); more efficient transport to the ice core site (Marquetto, Kaspari, & Simões, 2020; Neff & Bertler, 2015; Schwanck et al, 2017; Stohl & Sodemann, 2010); and weaker precipitation (Legrand & Mayewski, 1997; Sinclair et al, 2010). The wet season is identified by much lower BC concentrations.…”

Section: Methodsmentioning

confidence: 99%

“…rBC size distribution data have been published online on PANGAEA repository as Marquetto, Kaspari, & Simões (2020): Refractory black carbon mass and number size distributions in West Antarctica snow and firn samples, PANGAEA (https://doi.org/10.1594/PANGAEA.920981).…”

Section: Data Availability Statementmentioning

confidence: 99%

“…In this work we present the rBC number and mass size distributions of 1,004 snow samples from a 20 m snow/firn core (TT07) drilled in West Antarctica during the 2014/2015 austral summer that spans 1968–2015 (Marquetto, Kaspari, & Simões, 2020). The rBC present in the core likely reflects long‐range transport from sources in South America and Australia/New Zealand and is associated mostly with biomass burning emissions (Arienzo et al, 2017; Bisiaux, Edwards, McConnell, Albert, et al, 2012; Koch et al, 2007; Stohl & Sodemann, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Mass and Number Size Distributions of rBC in Snow and Firn Samples From Pine Island Glacier, West Antarctica

Marquetto

Kaspari

Simões

2020

Earth and Space Science

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An extended-range Single Particle Soot Photometer (SP2) coupled to a Marin-5 nebulizer was used to measure the refractory black carbon (rBC) mass and number size distributions in 1,004 samples from a West Antarctica snow/firn core. The SP2 was calibrated using Aquadag and a Centrifugal Particle Mass Analyzer for BC particles ranging from 0.5 to 800 fg. Our results indicate a significant contribution of rare, large particles of mass-equivalent diameter (D BC) > 500 nm to the total rBC mass (36%), while small particles (D BC < 100 nm) are abundant but contribute <8% to total rBC mass. We observed a primary mass median diameter of 162 ± 40 nm, smaller than reported for snow in other regions of the globe but similar to East Antarctica rBC size distributions. In addition, we observed other modes at 673, 1,040, and >1,810 nm (uncontained mode). We compared two sets of samples from different seasons (wet vs. dry) and observed that dry season concentrations are 3.4 and 2 times that of the wet season in the ranges of 80 nm < D BC < 500 nm (small particles) and 500 nm < D BC < 2,000 nm (large particles), respectively, while number of particles in the dry season is 3.5 and 2 times that of the wet season for the same size ranges. Millimeter thick melt layers have been observed in some samples, although they did not change the observed median diameter. This study provides the first detailed rBC mass and number size distribution from West Antarctica. Plain Language Summary Black carbon (BC) is a particle produced by the incomplete combustion of biomass burning and fossil fuels and plays an important role in the climate system due to its strong light absorption properties. The size of BC particles in snow is important for determining the effects that BC has on the cryosphere and provides insight into the processes controlling BC emission history, transport, and deposition. Past studies indicate spatial differences of BC size distributions in snow, but these studies are limited in number, and more are needed to address this spatial variability. Here the size distribution is presented of BC particles from 1,004 samples from a Pine Island Glacier ice core, West Antarctica, in a region where there is no information of BC particle size in snow. BC in West Antarctica is smaller than other regions of the globe but large, rare particles are also present. These large BC particles are larger than what other studies have reported and could be a result of long-range transport from other continents and/or agglomeration from small particles during transport or deposition.

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Spatial and temporal variations of refractory black carbon along the transect from Zhongshan Station to Dome A, eastern Antarctica

et al. 2020

Atmospheric Environment

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Refractory black carbon (rBC) variability in a 47-year West Antarctic snow and firn core

Cited by 12 publications

References 67 publications

Spatial Variability of the Snowmelt‐Albedo Feedback in Antarctica

Spatial Variability of the Snowmelt‐Albedo Feedback in Antarctica

Mass and Number Size Distributions of rBC in Snow and Firn Samples From Pine Island Glacier, West Antarctica

Spatial and temporal variations of refractory black carbon along the transect from Zhongshan Station to Dome A, eastern Antarctica

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