Bound and mobile soil water isotope ratios are affected by soil texture and mineralogy, whereas extraction method influences their measurement

Rachel E. Adams, Ayumi Hyodo, Toby SantaMaria, Cynthia L. Wright, Thomas W. Boutton, Jason B. West

Research output: Contribution to journalArticlepeer-review

29 Scopus citations

Abstract

Questions persist about interpreting isotope ratios of bound and mobile soil water pools, particularly relative to clay content and extraction conditions. Interactions between pools and resulting extracted water isotope composition are presumably related to soil texture, yet few studies have manipulated the bound pool to understand its influence on soil water processes. Using a series of drying and spiking experiments, we effectively labelled bound and mobile water pools in soils with varying clay content. Soils were first vacuum dried to remove residual water, which was then replaced with heavy isotope-enriched water prior to oven drying and spiking with heavy isotope-depleted water. Water was extracted via centrifugation or cryogenic vacuum distillation (at four temperatures) and analysed for oxygen and hydrogen isotope ratios via isotope ratio mass spectrometry. Water from centrifuged samples fell along a mixing line between the two added waters but was more enriched in heavy isotopes than the depleted label, demonstrating that despite oven drying, a residual pool remains and mixes with the mobile water. Soils with higher clay + silt content appeared to have a larger bound pool. Water from vacuum distillation samples have a significant temperature effect, with high temperature extractions yielding progressively more heavy isotope-enriched values, suggesting that Rayleigh fractionation occurred at low temperatures in the vacuum line. By distinctly labelling bound and mobile soil water pools, we detected interactions between the two that were dependent on soil texture. Although neither extraction method appeared to completely extract the combined bound and mobile (total water) pool, centrifugation and high temperature cryogenic vacuum distillations were comparable for both δ2H and δ18O of soil water isotope ratios.

Original languageEnglish
Pages (from-to)991-1003
Number of pages13
JournalHydrological Processes
Volume34
Issue number4
DOIs
StatePublished - Feb 15 2020
Externally publishedYes

Funding

Research was supported by USDA/NIFA Hatch Projects 1003961 and 1002535, the Sid Kyle Endowment and the Sid Kyle Graduate Merit Assistantship from the Department of Ecosystem Science and Management (ESSM) at Texas A&M University (TAMU), National Geographic Society Early Career Grant (CP‐090ER‐17), the National Science Foundation Graduate Research Fellowship Program, the TAMU ESSM Franklin F. Wasko Graduate Merit Fellowship, the TAMU Office of Graduate and Professional Studies Graduate Diversity Fellowship, and the TAMU AgriLife Strategic Initiative Assistantship. Xiangmin Sun provided the soils from Oklahoma as well as performed initial experiments, which provided a foundation for this study. We would like to thank Dr Youjun Deng and Bidemi T. Fashina from the Soil Mineralogy laboratory in the Department of Soil and Crop Sciences at Texas A&M University for performing the XRD analysis and offering assistance to interpret the results. Research was supported by USDA/NIFA Hatch Projects 1003961 and 1002535, the Sid Kyle Endowment and the Sid Kyle Graduate Merit Assistantship from the Department of Ecosystem Science and Management (ESSM) at Texas A&M University (TAMU), National Geographic Society Early Career Grant (CP-090ER-17), the National Science Foundation Graduate Research Fellowship Program, the TAMU ESSM Franklin F. Wasko Graduate Merit Fellowship, the TAMU Office of Graduate and Professional Studies Graduate Diversity Fellowship, and the TAMU AgriLife Strategic Initiative Assistantship. Xiangmin Sun provided the soils from Oklahoma as well as performed initial experiments, which provided a foundation for this study. We would like to thank Dr Youjun Deng and Bidemi T. Fashina from the Soil Mineralogy laboratory in the Department of Soil and Crop Sciences at Texas A&M University for performing the XRD analysis and offering assistance to interpret the results.

FundersFunder number
Sid Kyle EndowmentGraduate Merit Assistantship
Soil Mineralogy laboratory in the Department of Soil and Crop Sciences at Texas A&M University
TAMU AgriLife
TAMU ESSM Franklin F. Wasko Graduate Merit Fellowship
TAMU Office of Graduate
USDA/NIFA
National Science Foundation
U.S. Department of Agriculture
National Institute of Food and Agriculture1002535, 1003961
National Geographic SocietyCP‐090ER‐17
Texas A and M University
Department of Ecosystem Science and Management, Texas A and M University
Department Ecosystem Science and Management, Texas A and M University
European Society for Sexual Medicine

    Keywords

    • clay mineralogy
    • extraction
    • methods
    • soil texture
    • soil water
    • stable isotopes
    • two water world hypothesis

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