Black carbon concentrations and modeled smoke deposition fluxes to the bare-ice dark zone of the Greenland Ice Sheet

IF 4.4 2区地球科学 Q1 GEOGRAPHY, PHYSICAL

Cryosphere Pub Date : 2023-07-18 DOI:10.5194/tc-17-2909-2023

Alia L. Khan, P. Xian, J. Schwarz

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Abstract

Abstract. Ice–albedo feedbacks in the ablation region of the Greenland Ice Sheet (GrIS) are difficult to constrain and model due, in part, to our limited understanding of the seasonal evolution of the bare-ice region. To help fill observational gaps, 13 surface samples were collected on the GrIS across the 2014 summer melt season from patches of snow and ice that were visibly light, medium, and dark colored. These samples were analyzed for their refractory black carbon (rBC) concentrations and size distributions with a single-particle soot photometer coupled to a characterized nebulizer. We present a size distribution of rBC in fresh snow on the GrIS and from the weathering crust in the bare-ice dark zone of the GrIS. The size distributions from the weathering crust samples appear unimodal and were overall smaller than the fresh snow sample, with a peak around 0.3 µm. The fresh snow sample contained very large rBC particles that had a pronounced bimodality in the peak size distributions, with peaks around 0.2 and 2 µm. rBC concentrations ranged from a minimum of 3 µg-rBC/L-H2O in light-colored patches at the beginning and end of the melt season to a maximum of 32 µg-rBC/L-H2O in a dark patch in early August. On average, the rBC concentrations were higher (20 ± 10 µg-rBC/L-H2O) in patches that were visibly dark, compared to medium patches (7 ± 2 µg-rBC/L-H2O) and light patches (4 ± 1 µg-rBC/L-H2O), suggesting that BC aggregation contributed to snow aging on the GrIS, and vice versa. Additionally, concentrations peaked in light and dark patches in early August, which is likely due to smoke transport from wildfires in northern Canada and Alaska, as supported by the Navy Aerosol Analysis and Prediction System (NAAPS) reanalysis model. According to the model output, 26 mg m−3 of biomass-burning-derived smoke was deposited between 1 April and 30 August, of which 85 % came from wet deposition, and 67 % was deposited during our sample collection time frame. The increase in the rBC concentration and size distributions immediately after the modeled smoke deposition fluxes suggest that biomass burning smoke is a source of BC to the dark zone of the GrIS. Thus, the role of BC in the seasonal evolution of the ice–albedo feedbacks should continue to be investigated in the weathering crust of the bare-ice zone of the GrIS.

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黑碳浓度和模拟烟雾沉降通量到格陵兰冰盖的裸冰暗区

摘要格陵兰冰盖消融区域的冰-反照率反馈很难约束和建模，部分原因是我们对裸冰区域的季节演变了解有限。为了填补观测空白，在2014年夏季融化季节，在GrIS上收集了13个表面样本，这些样本来自可见的浅色、中等和深色的雪和冰。使用与表征雾化器相连的单颗粒烟尘光度计分析这些样品的难熔炭黑（rBC）浓度和尺寸分布。我们给出了GrIS上新鲜雪和GrIS裸冰暗区风化壳中rBC的大小分布。风化壳样品的尺寸分布呈单峰型，总体上小于新鲜雪样品，峰值约为0.3 µm。新鲜雪样品含有非常大的rBC颗粒，其峰值大小分布具有明显的双峰性，峰值约为0.2和2 µm。rBC的浓度范围最小为3 在融化季节开始和结束时，浅色斑块中的µg-rBC/L-H2O最大为32 µg-rBC/L-H2O。平均而言，rBC浓度更高（20 ± 10 µg-rBC/L-H2O），与中等斑块（7 ± 2. µg-rBC/L-H2O）和光贴片（4 ± 1. µg-rBC/L-H2O），表明BC聚集有助于GrIS上的雪老化，反之亦然。此外，在海军气溶胶分析和预测系统（NAAPS）再分析模型的支持下，浓度在8月初的明暗区域达到峰值，这可能是由于加拿大北部和阿拉斯加野火产生的烟雾输送。根据模型输出，26 毫克 4月1日至8月30日期间沉积了m−3的生物质燃烧产生的烟雾，其中85 % 来自湿沉积，67 % 在我们的样品采集时间范围内存放。在模拟的烟雾沉积通量之后，rBC浓度和尺寸分布的增加表明，燃烧生物质的烟雾是GrIS暗区的BC来源。因此，应继续在GrIS裸冰区的风化壳中研究BC在冰反照率反馈的季节演变中的作用。

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来源期刊

Cryosphere GEOGRAPHY, PHYSICAL-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

8.70

自引率

17.30%

发文量

240

审稿时长

4-8 weeks

期刊介绍： The Cryosphere (TC) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on all aspects of frozen water and ground on Earth and on other planetary bodies. The main subject areas are the following: ice sheets and glaciers; planetary ice bodies; permafrost and seasonally frozen ground; seasonal snow cover; sea ice; river and lake ice; remote sensing, numerical modelling, in situ and laboratory studies of the above and including studies of the interaction of the cryosphere with the rest of the climate system.