Jesse Bloom Bateman1,2, Oliver A Chadwick3, Peter M Vitousek4. 1. Department of Earth System Science, Stanford University, Stanford, CA 94305. 2. Institute of the Environment and Sustainability, University of California, Los Angeles, CA. 3. Department of Geography, University of California, Santa Barbara, CA. 4. Department of Biology, Stanford University, Stanford, CA 94305.
Abstract
Pedogenic thresholds describe where soil properties or processes change in an abrupt/nonlinear fashion in response to small changes in environmental forcing. Contrastingly, soil process domains refer to the space between thresholds where soil properties are either unchanged, or change gradually, across a broad range of environmental forcing. Here, we test quantitatively for the presence of thresholds in patterns of soil properties across a climatic gradient on soils developed from ~20 ky old basaltic substrate on the Island of Hawai'i. From multiple soil properties, we quantitatively identified a threshold at ~750 mm/y of water balance (precipitation minus potential evapotranspiration), delineating the upper water balance boundary of soil fertility in these soils. From the threshold in the ratio of exchangeable Ca to total Ca we identified the lower water balance boundary of soil fertility in these soils at -1000 mm/y, however this threshold was qualitatively described as it lies near the limit of the climate gradient data where the statistical approach can not be applied. These two results represent the first time that pedogenic thresholds have been identified using statistically rigorous methods and the limitations of said methods, respectively. Comparing the 20 ky soils to soils that developed on basaltic substrates of 1.2 ky, 7.5 ky, 150 ky, and 4100 ky in a time-climate matrix, we found that our quantitative analysis supports previous qualitatively identified thresholds in the soils developed from older substrates. We also identified the 20 ky as the transition from kinetic to supply limitation for plant nutrients in soil in this system.
pan class="Chemical">Pn>edogenic thresholds describe where soil propn>ern>an class="Chemical">ties or processes change in an abrupt/nonlinear fashion in response to small changes in environmentpan class="Chemical">al forcing. Contrastingly, soil process domains refer to the space between thresholds where soil properties are either unchanged, or change gradually, across a broad range of environmental forcing. Here, we test quantitatively for the presence of thresholds in patterns of soil properties across a climatic gradient on soils developed from ~20 ky old basaltic substrate on the Island of Hawai'i. From multiple soil properties, we quantitatively identified a threshold at ~750 mm/y of water balance (precipitation minus potential evapotranspiration), delineating the upper water balance boundary of soil fertility in these soils. From the threshold in the ratio of exchangeable Ca to total Ca we identified the lower water balance boundary of soil fertility in these soils at -1000 mm/y, however this threshold was qualitatively described as it lies near the limit of the climate gradient data where the statistical approach can not be applied. These two results represent the first time that pedogenic thresholds have been identified using statistically rigorous methods and the limitations of said methods, respectively. Comparing the 20 ky soils to soils that developed on basaltic substrates of 1.2 ky, 7.5 ky, 150 ky, and 4100 ky in a time-climate matrix, we found that our quantitative analysis supports previous qualitatively identified thresholds in the soils developed from older substrates. We also identified the 20 ky as the transition from kinetic to supply limitation for plant nutrients in soil in this system.
Entities:
Keywords:
Hawai’i; biological uplift; breakpoints; pedogenesis; pedogenic thresholds; process domains; volcanic soil; water balance
Authors: Michael W Burnett; Ariel E Bobbett; Corinna E Brendel; Kehaulani Marshall; Christian von Sperber; Elizabeth L Paulus; Peter M Vitousek Journal: Oecologia Date: 2022-01-05 Impact factor: 3.225
Authors: Creighton M Litton; Christian P Giardina; Kristen R Freeman; Paul C Selmants; Jed P Sparks Journal: Front Plant Sci Date: 2020-06-12 Impact factor: 5.753