4.7 Article

Soil pore network response to freeze-thaw cycles in permafrost aggregates

期刊

GEODERMA
卷 411, 期 -, 页码 -

出版社

ELSEVIER
DOI: 10.1016/j.geoderma.2021.115674

关键词

Pore morphology; Pore connectivity; Freeze thaw; Microscale; Permafrost thaw; Arctic; Aggregates

资金

  1. U.S. Department of Energy, Office of Science, Biological and Environmental Research as part of the Environmental System Science Program
  2. DOE [DE-AC05-76RL01830]
  3. Environmental Molecular Sciences Laboratory, a DOE Office of Science user facility [50267, grid.436923.9]
  4. Department of Energy's Office of Biological and Environmental Research program [DE-AC05-76RL01830]
  5. National Science Foundation (NSF)
  6. NSF through the NEON program

向作者/读者索取更多资源

Climate change in Arctic landscapes can increase the frequency of freeze-thaw cycles in the active layer and newly thawed permafrost. These cycles can disrupt the soil pore network, affecting water transport, redox conditions, and microbial activity. This study investigates the impact of freeze-thaw cycles on the pore network of thawed permafrost aggregates, revealing changes in pore morphology, connectivity, and throat diameter distribution. The results suggest that freeze-thaw alters the microenvironment of permafrost aggregates and affects soil properties and function in Arctic landscapes undergoing transition.
Climate change in Arctic landscapes may increase freeze-thaw frequency within the active layer as well as newly thawed permafrost. Freeze-thaw is a highly disruptive process that can deform soil pores and alter the architecture of the soil pore network with varied impacts to water transport and retention, redox conditions, and microbial activity. Our objective was to investigate how freeze-thaw cycles impacted the pore network of newly thawed permafrost aggregates to improve understanding of what type of transformations can be expected from warming Arctic landscapes. We measured the impact of freeze-thaw on pore morphology, pore throat diameter distribution, and pore connectivity with X-ray computed tomography (XCT) using six permafrost aggregates with sizes of 2.5 cm3 from a mineral soil horizon (Bw; 28-50 cm depths) in Toolik, Alaska. Freeze-thaw cycles were performed using a laboratory incubation consisting of five freeze-thaw cycles (-10 C to 20 C) over five weeks. Our findings indicated decreasing spatial connectivity of the pore network across all aggregates with higher frequencies of singly connected pores following freeze-thaw. Water-filled pores that were connected to the pore network decreased in volume while the overall connected pore volumetric fraction was not affected. Shifts in the pore throat diameter distribution were mostly observed in pore throats ranges of 100 mu m or less with no corresponding changes to the pore shape factor of pore throats. Responses of the pore network to freeze-thaw varied by aggregate, suggesting that initial pore morphology may play a role in driving freeze-thaw response. Our research suggests that freeze-thaw alters the microenvironment of permafrost aggregates during the incipient stage of deformation following permafrost thaw, impacting soil properties and function in Arctic landscapes undergoing transition.

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