Abstract
Under a warming climate, permafrost degradation has resulted in profound hydrogeological consequences. Here, we mainly review 240 recent relevant papers. Permafrost degradation has boosted groundwater storage and discharge to surface runoffs through improving hydraulic connectivity and reactivation of groundwater flow systems, resulting in reduced summer peaks, delayed autumn flow peaks, flattened annual hydrographs, and deepening and elongating flow paths. As a result of permafrost degradation, lowlands underlain by more continuous, colder, and thicker permafrost are getting wetter and uplands and mountain slopes, drier. However, additional contribution of melting ground ice to groundwater and stream-flows seems limited in most permafrost basins. As a result of permafrost degradation, the permafrost table and supra-permafrost water table are lowering; subaerial supra-permafrost taliks are forming; taliks are connecting and expanding; thermokarst activities are intensifying. These processes may profoundly impact on ecosystem structures and functions, terrestrial processes, surface and subsurface coupled flow systems, engineered infrastructures, and socioeconomic development. During the last 20 years, substantial and rapid progress has been made in many aspects in cryo-hydrogeology. However, these studies are still inadequate in desired spatiotemporal resolutions, multi-source data assimilation and integration, as well as cryo-hydrogeological modeling, particularly over rugged terrains in ice-rich, warm (>−1 °C) permafrost zones. Future research should be prioritized to the following aspects. First, we should better understand the concordant changes in processes, mechanisms, and trends for terrestrial processes, hydrometeorology, geocryology, hydrogeology, and ecohydrology in warm and thin permafrost regions. Second, we should aim towards revealing the physical and chemical mechanisms for the coupled processes of heat transfer and moisture migration in the vadose zone and expanding supra-permafrost taliks, towards the coupling of the hydrothermal dynamics of supra-, intra- and sub-permafrost waters, as well as that of water-resource changes and of hydrochemical and biogeochemical mechanisms for the coupled movements of solutes and pollutants in surface and subsurface waters as induced by warming and thawing permafrost. Third, we urgently need to establish and improve coupled predictive distributed cryo-hydrogeology models with optimized parameterization. In addition, we should also emphasize automatically, intelligently, and systematically monitoring, predicting, evaluating, and adapting to hydrogeological impacts from degrading permafrost at desired spatiotemporal scales. Systematic, in-depth, and predictive studies on and abilities for the hydrogeological impacts from degrading permafrost can greatly advance geocryology, cryo-hydrogeology, and cryo-ecohydrology and help better manage water, ecosystems, and land resources in permafrost regions in an adaptive and sustainable manner.
Highlights
Permafrost has occurred extensively on the Earth’s surfaces in the past and at present, and will occur in the future, with an areal extent of about 20–23 million km2 for the existing permafrost [1,2,3]
It is evident that: (1) permafrost is warming at 0.002–0.05 ◦ C a−1 ; (2) there are some places without a noticeable increase, but, and only occasionally, few known sites for cooling; (3) ALT is increasing at some locations, and there are some locations in West Siberia, Alaska, and Central Asia where the active layer no longer freezes up every year; (4) longterm permafrost thawing has already started at some locations in undisturbed conditions; and (5) the nature and rate of permafrost degradation differ substantially
Locked in permafrost, the water/ice of geological ages can present in sub-permafrost aquifers; the incursion of shallow recharge waters can be detected by dating the sub-permafrost water
Summary
Permafrost has occurred extensively on the Earth’s surfaces in the past and at present, and will occur in the future, with an areal extent of about 20–23 million km for the existing permafrost [1,2,3]. Groundwater flows exert strong influences on the formation, distribution, and evolution of permafrost and taliks/aquifers mainly by heat advection and convection along preferential flow paths (e.g., [9,10,11,12,13]) This interplay, in addition to feedback from physical, chemical, and biogeochemical processes, creates complex permafrost–groundwater interactive dynamics in permafrost regions, such as those in the Circum-Arctic regions and on the Qinghai–Tibet. On the basis of pooling and analyzing about 240 recent (2000–2021) publications and with a global perspective, this paper reviews the progress in permafrost degradation and its hydrogeological impacts It aims at identifying inadequacies and priorities for near-future studies. N fluxes (to the atmosphere or to water systems) of groundwater systems nor much on surface hydrological, terrestrial, and ecological processes, unless it is directly connected with permafrost–groundwater systems
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