Mercury Transport, Transformation and Accumulation Recorded by Stable Isotopes during Retreated Glacier Chronosequence of 250 Years
Nantao Liu, Xin Li, Peijia Chen, Wei Yuan, Che‐Jen Lin, Xinbin Feng, Xun Wang
Abstract
Vegetative development in regions where glaciers retreated due to global warming forces the mercury (Hg) cycle in the cryosphere. This study depicts the fate of Hg in a glacier-retreated chronosequence over the last 250 years recorded by signals of stable Hg isotopes. Results show that the Hg storage in surface soil increases by 3.2 times over 250 years after the glacier retreated. 53 ± 11% of Hg in grass shoots is from the uptake of atmospheric Hg 0 and 47 ± 11%, from the uptake of soil Hg. Atmospheric Hg 2+ is the primary source of surface soil Hg (54 ± 13%), followed by atmospheric Hg 0 (40 ± 10%) and geogenic Hg. The Hg accumulation in soils increased by a factor of 5 at an accelerating rate from the 1870s to 2010s. The Hg release flux from melting glaciers is 3.51 ± 0.01 μg m –2 yr –1 . The highly positive Δ 199 Hg (1.03 ± 0.49‰) in precipitation due to photoreduction of Hg 2+ in water droplets causes all samples in ecosystems to have positive Δ 199 Hg values. Isotopic evidence suggests that photolytic and abiotic dark reduction processes have driven Hg 0 re-emission from glacier and underlying soil after melting. The accelerated Hg release from melting glaciers and soil Hg accumulation caused by global warming alter Hg cycling in the cryosphere.