Soil organic carbon stabilization mechanisms and temperature sensitivity in old terraced soils

Zhao, Pengzhi; Fallu, Daniel J.; Cucchiaro, Sara; Tarolli, Paolo; Waddington, Clive; Cockcroft, David; Snape, Lisa; Lang, Andreas; Doetterl, Sebastian; Brown, Antony G.; Oost, Kristof Van

doi:10.5194/bg-18-6301-2021

Cited by 8 publications

(1 citation statement)

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“…The ancient retaining walls directly increased the land stability in both floodwater irrigation systems, which was expressed by a higher fine particles content, and organic matter that formed bio‐cementation compounds and stabilized aggregates (Rao et al, 2021; Zhao et al, 2021). The biocrust, except for its positive influence on soil fertility, by enriching the soil with fixed carbon and nitrogen production (Barger et al, 2016; Sancho et al, 2016), enhanced soil surface stability by gluing the soil particles (Zaady et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

Reclamation of ancient agricultural terraces in the Negev Highlands; soil, archeological, hydrological, and topographical perspectives

et al. 2022

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Ancient terraced lands are considered badlands without profitable utilization except for urbanization. Nevertheless, this attitude prevents further agricultural utilization in addition to the loss of archaeological data. The study hypothesizes that the main influencing part in these systems is the retaining walls (RW). An analysis of their current influence on soil fertility, stability, and hydrology will indicate their adequate reclamation strategy. The objectives are to gather the influences and correlate them to the RW constructional state. In the Yeroham Hills, three parallel located terraced systems (one on the Wadi Shualim channel and the other, which is located on its banks) were studied. Their ancient agricultural utilization was dated, after in‐site excavations, to the Roman until early Islamic eras. Ten representative RWs were chosen, five from each terraced system. Their influences on the soil fertility, hydrology, and physical properties of the adjacent soil and 2 m ahead (the terrace) were studied. The finding indicates that the RW serves as a physical ecosystem engineer with positive influences on soil organic matter (0.5% higher content compared to the terrace) and land stability properties (maturated soil biocrust and higher aggregate stability). Comparison of the finding from both terraced irrigation systems, which differ in their conservation state, enables to determine the agricultural utilization and land stabilization after an adequate reclamation strategy, which is based on the RWs constructional parameters analyzed in‐site, and adaption to the current floodwater paths. The study's principles and analysis scheme enable the study and conservation of similar areas worldwide for increased utilization and profitability.

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