4.7 Article

Chronological changes in soil biogeochemical properties of the glacier foreland of Midtre Lov acute accent enbreen, Svalbard, attributed to soil-forming factors

Journal

GEODERMA
Volume 415, Issue -, Pages -

Publisher

ELSEVIER
DOI: 10.1016/j.geoderma.2022.115777

Keywords

Glacier foreland; Soil-forming factors; Soil biogeochemical property; Chronosequence; Glacio-fluvial runoff; Svalbard

Categories

Funding

  1. Korea Polar Research Institute [KOPRI] [PE16030]
  2. National Research Foundation of Korea - Korean Government [NRF-2021M1A5A1075508, KOPRI-PN22012]
  3. U.S. Department of Energy
  4. U.S. Department of Energy's National Nuclear Security Administration [DE-NA-0003525]
  5. National Research Foundation of Korea [2021M1A5A1075508] Funding Source: Korea Institute of Science & Technology Information (KISTI), National Science & Technology Information Service (NTIS)

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This study investigates soil development and biogeochemical changes in the glacier foreland of Svalbard by considering various factors including time. The study finds that plant-derived material is the main driver of soil organic matter accumulation, and other environmental parameters also affect soil biogeochemical properties. Glacier runoff hampers ecosystem development.
Glacier forelands provide an excellent opportunity to investigate vegetation succession and soil development along the chronosequence; however, there are few studies on soil biogeochemical changes from environmental factors, aside from time. This study aimed to investigate soil development and biogeochemical changes in the glacier foreland of Midtre Love ' nbreen, Svalbard, by considering various factors, including time. Eighteen vegetation and soil variables were measured at 38 different sampling sites of varying soil age, depth, and glaciofluvial activity. Soil organic matter (SOM) was quantitatively measured, and the compositional changes in SOM were determined following size-density fractionation. In the topsoil, the soil organic carbon (SOC) and total nitrogen (N) content was found to increase along the soil chronosequence and were highly correlated with vegetation-associated variables. These findings suggest that plant-derived material was the main driver of the light fraction of SOM accumulation in the topsoil. The heavy fractions of SOM were composed of microbially transformed organic compounds, eventually contributing to SOM stabilization within short 90-yr deglaciation under harsh climatic conditions. In addition to time, the soil vertical profiles showed that other environmental parameters, also affected the soil biogeochemical properties. The high total phosphorous (P) content and electrical conductivity in the topsoil were attributed to unweathered subglacial materials and a considerable amount of inorganic ions from subglacial meltwater. The high P and magnesium content in the subsoil were attributed to parent materials, while the high sodium and potassium content in the surface soil were a result of sea-salt deposition. Glacio-fluvial runoff hampered ecosystem development by inhibiting vegetation development and SOM accumulation. This study emphasizes the importance of considering various soil-forming factors, including parent/subglacial materials, aeolian deposition, and glacio-fluvial runoff, as well as soil age, to obtain a comprehensive understanding of the ecosystem development in glacier forelands.

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