Abstract. Water-soluble organic carbon (WSOC) in the cryosphere can
significantly influence the global carbon cycle and radiation budget.
However, WSOC in the snowpack has received little scientific attention to
date. This study reports the fluorescence characteristics, absorption
properties, and radiative effects of WSOC based on 34 snow samples collected
from sites in northeastern China. A significant degree of regional WSOC
variability is found, with concentrations ranging from 0.5±0.2 to 5.7±3.7 µg g−1 (average concentration: 3.6±3.2 µg g−1). The three principal fluorescent components of
WSOC are identified as (1) the high-oxygenated humic-like substances
(HULIS-1) of terrestrial origin, (2) the low-oxygenated humic-like
substances (HULIS-2) of mixed origin, and (3) the protein-like substances
(PRLIS) derived from autochthonous microbial activity. In southeastern Inner
Mongolia (SEIM), a region dominated by desert and exposed soils, the WSOC
exhibits the highest humification index (HIX) but the lowest fluorescence
(FI) and biological (BIX) indices; the fluorescence signal is mainly
attributed to HULIS-1 and thus implicates soil as the primary source. By
contrast, the HIX (FI and BIX) value is the lowest (highest), and the percentage
of PRLIS is the highest in the remote area of northeastern Inner
Mongolia (NEIM), suggesting a primarily biological source. For south and
north of northeastern China (SNC and NNC), both of which are characterized
by intensive agriculture and industrial activity, the fluorescence signal is
dominated by HULIS-2, and the HIX, FI, and BIX values are all moderate,
indicating the mixed origins for WSOC (anthropogenic activity, microbial
activity, and soil). We also observe that, throughout northeastern China,
the light absorption of WSOC is dominated by HULIS-1, followed by HULIS-2
and PRLIS. The contribution of WSOC to albedo reduction (average
concentration: 3.6 µg g−1) in the ultraviolet–visible (UV–Vis)
band is approximately half that of black carbon (BC average concentration:
0.6 µg g−1). Radiative forcing is 3.8 (0.8) W m−2 in old
(fresh) snow, equating to 19 % (17 %) of the radiative forcing of BC.
These results indicate that WSOC has a profound impact on snow albedo and
the solar radiation balance.
Light-absorbing particles (LAPs) deposited on snow can significantly reduce surface albedo and contribute to positive radiative forcing. This study firstly estimated and attributed the spatio-temporal variability in the radiative forcing (RF) of LAPs in snow over the northern hemisphere during the snow-covered period 2003–2018 by employing Moderate Resolution Imaging Spectroradiometer (MODIS) data, coupled with snow and atmospheric radiative transfer modelling. In general, the RF for the northern hemisphere shows a large spatial variability over the whole snow-covered areas and periods, with the highest value (12.7 W m−2) in northeastern China (NEC) and the lowest (1.9 W m−2) in Greenland (GRL). The concentration of LAPs in snow is the dominant contributor to spatial variability in RF in spring (~73%) while the joint spatial contributions of snow water equivalent (SWE) and solar irradiance (SI) are the most important (>50%) in winter. The average northern hemisphere RF gradually increases from 2.1 W m−2 in December to 4.1 W m−2 in May and the high-value area shifts gradually northwards from mid-altitude to high-latitude over the same period, which is primarily due to the seasonal variability of SI (~58%). More interestingly, our data reveal a significant decrease in RF over high-latitude Eurasia (HEUA) of −0.04 W m−2 a−1 and northeastern China (NEC) of −0.14 W m−2 a−1 from 2003 to 2018. By employing a sensitivity test, we find the concurrent decline in the concentration of LAPs in snow accounted for the primary responsibility for the decrease in RF over these two areas, which is further confirmed by in situ observations.
Snowpack is a crucial component of the cryosphere, serving as a huge water reservoir for river catchments, and it is especially important for the regional sustainability of ecosystems and communities (Barnett et al., 2005;Hugonnet et al., 2021;Sturm et al., 2017). The surface energy budget of snow-covered regions, and the ablation rate of the snowpack in particular, are significantly affected by snow albedo (Flanner et al., 2011;Jakobs et al., 2021;Riihelä et al., 2021;Zhang et al., 2021). Numerous observations and model simulations have shown that light-absorbing particles (LAPs; e.g., black carbon (BC) and mineral dust (hereafter referred to as dust)) within the snowpack can reduce snow albedo and accelerate snow melting by enhancing the absorption of solar radiation (
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