A revised pan-Arctic permafrost soil Hg pool based on Western Siberian peat Hg and carbon observations
oleh: A. G. Lim, M. Jiskra, J. E. Sonke, S. V. Loiko, N. Kosykh, O. S. Pokrovsky, O. S. Pokrovsky
| Format: | Article |
|---|---|
| Diterbitkan: | Copernicus Publications 2020-06-01 |
Deskripsi
<p>Natural and anthropogenic mercury (Hg) emissions are sequestered in terrestrial soils over short, annual to long, millennial timescales before Hg mobilization and run-off impact wetland and coastal ocean ecosystems. Recent studies have used Hg-to-carbon (C) ratios (<span class="inline-formula"><i>R</i><sub>HgC</sub></span>'s) measured in Alaskan permafrost mineral and peat soils together with a northern circumpolar permafrost soil carbon inventory to estimate that these soils contain large amounts of Hg (between 184 and 755 <span class="inline-formula">Gg</span>) in the upper 1 <span class="inline-formula">m</span>. However, measurements of <span class="inline-formula"><i>R</i><sub>HgC</sub></span> on Siberian permafrost peatlands are largely missing, leaving the size of the estimated northern soil Hg budget and its fate under Arctic warming scenarios uncertain. Here we present Hg and carbon data for six peat cores down to mineral horizons at 1.5–4 <span class="inline-formula">m</span> depth, across a 1700 <span class="inline-formula">km</span> latitudinal (56 to 67<span class="inline-formula"><sup>∘</sup></span> N) permafrost gradient in the Western Siberian Lowland (WSL). Mercury concentrations increase from south to north in all soil horizons, reflecting a higher stability of sequestered Hg with respect to re-emission. The <span class="inline-formula"><i>R</i><sub>HgC</sub></span> in the WSL peat horizons decreases with depth, from 0.38 <span class="inline-formula">Gg Pg<sup>−1</sup></span> in the active layer to 0.23 <span class="inline-formula">Gg Pg<sup>−1</sup></span> in continuously frozen peat of the WSL. We estimate the Hg pool (0–1 <span class="inline-formula">m</span>) in the permafrost-affected part of the WSL peatlands to be <span class="inline-formula">9.3±2.7</span> <span class="inline-formula">Gg</span>. We review and estimate pan-Arctic organic and mineral soil <span class="inline-formula"><i>R</i><sub>HgC</sub></span> to be 0.19 and 0.63 <span class="inline-formula">Gg Pg<sup>−1</sup></span>, respectively, and use a soil carbon budget to revise the pan-Arctic permafrost soil Hg pool to be 72 <span class="inline-formula">Gg</span> (39–91 <span class="inline-formula">Gg</span>; interquartile range, IQR) in the upper 30 <span class="inline-formula">cm</span>, 240 <span class="inline-formula">Gg</span> (110–336 <span class="inline-formula">Gg</span>) in the upper 1 <span class="inline-formula">m</span>, and 597 <span class="inline-formula">Gg</span> (384–750 <span class="inline-formula">Gg</span>) in the upper 3 <span class="inline-formula">m</span>. Using the same <span class="inline-formula"><i>R</i><sub>HgC</sub></span> approach, we revise the upper 30 <span class="inline-formula">cm</span> of the global soil Hg pool to contain 1086 <span class="inline-formula">Gg</span> of Hg (852–1265 <span class="inline-formula">Gg</span>, IQR), of which 7 % (72 <span class="inline-formula">Gg</span>) resides in northern permafrost soils. Additional soil and river studies in eastern and northern Siberia are needed to lower the uncertainty on these estimates and assess the timing of Hg release to the atmosphere and rivers.</p>