Abrupt stream acidification and metal mobilization from permafrost degradation
Summary
Stream chemistry and ecosystem function are being transformed by abrupt acceleration of sulfide-mineral oxidation in permafrost-underlain headwater catchments of the Yukon and Mackenzie river basins-the two largest (sub)Arctic rivers in North America. Over the past decade, dozens of acidic (pH ~3) seepages have emerged in these headwaters, causing vegetation dieback and mobilizing metals at acutely toxic concentrations in receiving streams. Acid generated during sulfide-mineral oxidation a
Content
# Abrupt stream acidification and metal mobilization from permafrost degradation
*Published: 2026 May 21*
Stream chemistry and ecosystem function are being transformed by abrupt
acceleration of sulfide-mineral oxidation in permafrost-underlain headwater
catchments of the Yukon and Mackenzie river basins-the two largest (sub)Arctic
rivers in North America. Over the past decade, dozens of acidic (pH ~3) seepages
have emerged in these headwaters, causing vegetation dieback and mobilizing
metals at acutely toxic concentrations in receiving streams. Acid generated
during sulfide-mineral oxidation also accelerates carbon dioxide emissions by
driving carbonate-mineral dissolution. Downstream (sub)Arctic rivers show
statistically significant multidecadal increases in sulfate concentrations, yet
their metal concentrations remain stable because of attenuation and dilution
processes. Headwater stream acidification signals a major perturbation in metal,
carbon, and sulfur cycling linked to permafrost thaw with far-reaching
consequences for water resources, northern communities, ecosystem health, and
Earth's biogeochemical future.
DOI: 10.1126/science.aea2898