Soil formation and weathering in a permafrost environment of the Swiss Alps: a multi‐parameter and non‐steady‐state approach

Zollinger, Barbara; Alewell, Christine; Kneisel, Christof; Brandová, Dagmar; Petrillo, Marta; Plötze, Michael; Christl, Marcus; Egli, Markus

doi:10.1002/esp.4040

Cited by 17 publications

(35 citation statements)

References 80 publications

(137 reference statements)

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“…Lal, 2001;Balco et al, 2008). The approaches of Lal (2001) and Zollinger et al (2017) achieve quite similar results. Due to pedogenic processes or human impact, the distribution pattern along the profile may be disturbed and, particularly in relatively young soils, far from a state of equilibrium.…”

Section: Soil Redistribution Rates (Erosion and Accumulation)mentioning

confidence: 76%

“…Soil erosion rates calculated using meteoric and in situ 10 Be were moderately comparable when employing the approach according to Hidy et al (2010) or that of Zollinger et al (2017). Considering only the buried soil, the erosion rates were slightly higher compared to the rates of the whole VAMOS profile using the approaches of Lal (2001), Zollinger et al (2017) and also MODERN. At the site LP12N, relatively high long-term erosion rates of 1.6 t ha -1 yr -1 (Hidy et al, 2010) to 2.1 t ha -1 yr -1 (Zollinger et al, 2017) were measured whereas the foot-slope site (or lower slope position) exhibited smaller erosion rates when considering the whole soil profile VAMOS; however, this profile however has a buried soil.…”

Section: Physical and Chemical Soil Propertiesmentioning

confidence: 79%

“…Due to the fact that LP4 is considered as the reference site, soil redistribution rates are assumed to be zero for the short-term rates. At the site LP12N, relatively high long-term erosion rates of 1.6 t ha -1 yr -1 (Hidy et al, 2010) to 2.1 t ha -1 yr -1 (Zollinger et al, 2017) were measured whereas the foot-slope site (or lower slope position) exhibited smaller erosion rates when considering the whole soil profile VAMOS; however, this profile however has a buried soil. Soil erosion rates calculated using meteoric and in situ 10 Be were moderately comparable when employing the approach according to Hidy et al (2010) or that of Zollinger et al (2017).…”

Section: Physical and Chemical Soil Propertiesmentioning

confidence: 93%

“…As reported in Egli et al (2010), the 10 Be deposition rates are mostly unknown for a specific area and have to be estimated. With soil erosion, Equation (1) is extended to the following non-steady-state approach (Zollinger et al, 2017): With soil erosion, Equation (1) is extended to the following non-steady-state approach (Zollinger et al, 2017):…”

Section: Calculation Of Mass Redistribution Ratesmentioning

confidence: 99%

“…Another problem is that often steady-state conditions are assumed to calculate denudation or soil production rates; an assumption that may lead to unrealistic representations of the dynamics of pedogenesis and weathering profile evolution (Phillips, 2010) if the requirements for a steadystate are not fulfilled. With known surface ages, denudation rates can also be calculated using meteoric 10 Be (Zollinger et al, 2017) even under a non-steady-state situation. Schaller et al, 2010;Hidy et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

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Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be

Calitri

Sommer

Norton

et al. 2019

Earth Surf Processes Landf

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Two principal groups of processes shape mass fluxes from and into a soil: vertical profile development and lateral soil redistribution. Periods having predominantly progressive soil forming processes (soil profile development) alternate with periods having predominantly regressive processes (erosion). As a result, short‐term soil redistribution – years to decades – can differ substantially from long‐term soil redistribution; i.e. centuries to millennia. However, the quantification of these processes is difficult and consequently their rates are poorly understood. To assess the competing roles of erosion and deposition we determined short‐ and long‐term soil redistribution rates in a formerly glaciated area of the Uckermark, northeast Germany. We compared short‐term erosion or accumulation rates using plutonium‐239 and ‐240 (239+240Pu) and long‐term rates using both in situ and meteoric cosmogenic beryllium‐10 (10Be). Three characteristic process domains have been analysed in detail: a flat landscape position having no erosion/deposition, an erosion‐dominated mid‐slope, and a deposition‐dominated lower‐slope site. We show that the short‐term mass erosion and accumulation rates are about one order of magnitude higher than long‐term redistribution rates. Both, in situ and meteoric 10Be provide comparable results. Depth functions, and therefore not only an average value of the topsoil, give the most meaningful rates. The long‐term soil redistribution rates were in the range of −2.1 t ha‐1 yr‐1 (erosion) and +0.26 t ha‐1 yr‐1 (accumulation) whereas the short‐term erosion rates indicated strong erosion of up to 25 t ha‐1 yr‐1 and accumulation of 7.6 t ha‐1 yr‐1. Our multi‐isotope method identifies periods of erosion and deposition, confirming the ‘time‐split approach’ of distinct different phases (progressive/regressive) in soil evolution. With such an approach, temporally‐changing processes can be disentangled, which allows the identification of both the dimensions of and the increase in soil erosion due to human influence. © 2019 John Wiley & Sons, Ltd.

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Section: Soil Redistribution Rates (Erosion and Accumulation)mentioning

confidence: 76%

Section: Physical and Chemical Soil Propertiesmentioning

confidence: 79%

Section: Physical and Chemical Soil Propertiesmentioning

confidence: 93%

Section: Calculation Of Mass Redistribution Ratesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be

Calitri

Sommer

Norton

et al. 2019

Earth Surf Processes Landf

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The Origin and Formation of Clay Minerals in Alpine Soils

Egli

Mirabella²

2021

Geophysical Monograph Series

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Clay minerals are among the most chemically active components and are a bridge between the inorganic and organic parts of a soil. The clay minerals influence pedogenetic processes by interacting with cations and inorganic and organic compounds, influencing the nutrition of the plants and the structure of the soils. Clay minerals are phyllosilicates and can in soils be either inherited from the parent material, neoformed, or transformed from precursor minerals. Relatively shortly after exposure of the parent material to atmospheric conditions, important mineral transformation reactions can occur, even in cold alpine climates. In alpine environments, the soil system reacts in a particularly sensitive way at the beginning of soil formation, i.e. during the first c. 3000 years. With time, the formation and transformation rates, and thus changes, decelerate. Smectitic components, and therefore 2:1 mineral structures, are the weathering steady-state products. Although weathering conditions are particularly intense close to the timberline and on pole-facing sites, 2:1 minerals strongly prevail over kaolinite or gibbsite, which are most often encountered as a weathering steady-state product in tropical regions. Smectitic components enrich under conditions of high percolation rates, cool climates (close to the treeline), high amounts of organic ligands, low erosion, stable conditions, and thus low soil production rates. Smectite formation therefore relates not only to the paradigms of the percolation theory, but the type and presence of vegetation and the production of organic ligands are additional driving factors.

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Identifying slope processes over time and their imprint in soils of medium‐high mountains of Central Europe (the Karkonosze Mountains, Poland)

Waroszewski

Egli

Brandová

et al. 2018

Earth Surf Processes Landf

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Soils in mountainous areas are often polygenetic, developed in slope covers that relate to glacial and periglacial activities of the Pleistocene and Holocene and reflect climatic variations. Landscape development during the Holocene may have been influenced by erosion/solifluction that often started after the Holocene climatic optimum. To trace back soil evolution and its timing, we applied a multi‐methodological approach. This approach helped us to outline scenario of soil transformation. According to our results, some aeolian input must have occurred in the late Pleistocene. During that time and the early Holocene, the soils most likely had features of Cryosols or Leptosols. Physico‐chemical and mineralogical analyses have indicated that the material was denudated (between late Boreal to the Atlantic) from the ridge and upper‐slope positions forming a colluvium at mid‐slope positions. Later, during the Sub‐Boreal, mass wasting of the remains of silt material deposited at the end of the Pleistocene age on the ridge top seems to have occurred. In addition, the cool and moist conditions caused the deposition of a colluvium at the lower‐slope positions. The next phase was characterized by the transformation of Leptosols/Cambisols into Podzols at upper‐slope or shoulder positions and to Albic Cambisols at mid‐slope positions. During the Sub‐Boreal period, Stagnosols started to form at the lower part of the slope catena. Overall, the highest erosion rates were calculated at the upper‐slope position and the lowest rates at mid‐slope sites. Berylium‐10 (10Be) data showed that the Bs, BC/C were covered during the Holocene by a colluvium with a different geological composition which complicated the calculation of erosion or accumulation rates. The interpretation of erosion and accumulation rates in such multi‐layered materials may, therefore, be hampered. However, the multi‐methodological reconstruction we applied shed light on the soil and landscape evolution of the eastern Karkonosze Mountains. Copyright © 2017 John Wiley & Sons, Ltd.

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Soil formation and weathering in a permafrost environment of the Swiss Alps: a multi‐parameter and non‐steady‐state approach

Cited by 17 publications

References 80 publications

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be

The Origin and Formation of Clay Minerals in Alpine Soils

Identifying slope processes over time and their imprint in soils of medium‐high mountains of Central Europe (the Karkonosze Mountains, Poland)

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Soil formation and weathering in a permafrost environment of the Swiss Alps: a multi‐parameter and non‐steady‐state approach

Cited by 17 publications

References 80 publications

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using 239+240Pu and 10Be

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using 239+240Pu and 10Be

The Origin and Formation of Clay Minerals in Alpine Soils

Identifying slope processes over time and their imprint in soils of medium‐high mountains of Central Europe (the Karkonosze Mountains, Poland)

Contact Info

Product

Resources

About

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be

Tracing the temporal evolution of soil redistribution rates in an agricultural landscape using ^239+240Pu and ¹⁰Be