Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data

Naasko, Katherine I; Naylor, Dan T; Graham, Emily B; Couvillion, Sneha P; Danczak, Robert E; Tolic, Nikola; Nicora, Carrie D; Fransen, Steven C; Tao, Haiying; Hofmockel, Kirsten S; Jansson, Janet K

doi:10.25584/PNNLDH/1985149

Title: Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data

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Abstract

Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to one meter in depth from irrigated and planted field treatments and analyzed using a suite of omics and chemical analyses. Carbon cycling processes in the surface soil were dominated by plant-microbe interactions that drive organic carbon cycling, whereas inorganic carbon chemistry dominated in deeper soil layers. Both irrigation and plant cover impacted organic and inorganic carbon pools in the soil profiles. This study reveals the complex interactions between water, plants, minerals, and microorganisms that govern organic and inorganic pools of soil carbon at different depths.

Authors:

Naasko, Katherine I; Naylor, Dan T;

; Couvillion, Sneha P; Danczak, Robert E; Tolic, Nikola;

; Fransen, Steven C; Tao, Haiying;

; Jansson, Janet K

PNNL

Publication Date:: Fri Apr 14 00:00:00 EDT 2023

DOE Contract Number:: AC05-76RL01830

Research Org.:: Pacific Northwest National Laboratory 2

Sponsoring Org.:: DOE

OSTI Identifier:: 1985149

DOI:: https://doi.org/10.25584/PNNLDH/1985149

Citation Formats


                    Naasko, Katherine I, Naylor, Dan T, Graham, Emily B, Couvillion, Sneha P, Danczak, Robert E, Tolic, Nikola, Nicora, Carrie D, Fransen, Steven C, Tao, Haiying, Hofmockel, Kirsten S, and Jansson, Janet K. Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data.  United States: N. p., 2023. 
        Web.  doi:10.25584/PNNLDH/1985149.

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                    Naasko, Katherine I, Naylor, Dan T, Graham, Emily B, Couvillion, Sneha P, Danczak, Robert E, Tolic, Nikola, Nicora, Carrie D, Fransen, Steven C, Tao, Haiying, Hofmockel, Kirsten S, & Jansson, Janet K. Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data.  United States.  doi:https://doi.org/10.25584/PNNLDH/1985149

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                    Naasko, Katherine I, Naylor, Dan T, Graham, Emily B, Couvillion, Sneha P, Danczak, Robert E, Tolic, Nikola, Nicora, Carrie D, Fransen, Steven C, Tao, Haiying, Hofmockel, Kirsten S, and Jansson, Janet K. 2023.  
"Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data".  United States.  doi:https://doi.org/10.25584/PNNLDH/1985149.  https://www.osti.gov/servlets/purl/1985149. Pub date:Fri Apr 14 00:00:00 EDT 2023

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@article{osti_1985149,

  title        = {Data for Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry: Summary Data},

  author       = {Naasko, Katherine I and Naylor, Dan T and Graham, Emily B and Couvillion, Sneha P and Danczak, Robert E and Tolic, Nikola and Nicora, Carrie D and Fransen, Steven C and Tao, Haiying and Hofmockel, Kirsten S and Jansson, Janet K},

  abstractNote = {Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to one meter in depth from irrigated and planted field treatments and analyzed using a suite of omics and chemical analyses. Carbon cycling processes in the surface soil were dominated by plant-microbe interactions that drive organic carbon cycling, whereas inorganic carbon chemistry dominated in deeper soil layers. Both irrigation and plant cover impacted organic and inorganic carbon pools in the soil profiles. This study reveals the complex interactions between water, plants, minerals, and microorganisms that govern organic and inorganic pools of soil carbon at different depths.},

  doi          = {10.25584/PNNLDH/1985149},

  journal      = {},

  number       = ,

  volume       = ,

  place        = {United States},

  year         = {Fri Apr 14 00:00:00 EDT 2023},

  month        = {Fri Apr 14 00:00:00 EDT 2023}

}

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DOI: https://doi.org/10.25584/PNNLDH/1985149

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Summary Data for paper titled: Influence of soil depth, irrigation, and plant genotype on the soil microbiome, metaphenome, and carbon chemistry

Dataset Naasko, Katherine ; Naylor, Dan ; Graham, Emily B ; ...

Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to one meter in depth from irrigated and planted field treatments and analyzed using a suite of omics and chemical analyses. Carbon cycling processes in the surface soil were dominated by plant-microbe interactions that drive organicmore »« less
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ABSTRACT Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to 1 m in depth from irrigated and planted field treatments and was analyzed using a suite of omics and chemical analyses. The soil microbial community composition was impacted more by irrigation and plant covermore »« less
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Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to 1 m in depth from irrigated and planted field treatments and was analyzed using a suite of omics and chemical analyses. The soil microbial community composition was impacted more by irrigation and plant cover treatmentsmore »« less
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Climate change is causing an increase in drought in many soil ecosystems and a loss of soil organic carbon. Calcareous soils may partially mitigate these losses via carbon capture and storage. Here, we aimed to determine how irrigation-supplied soil moisture and perennial plants impact biotic and abiotic soil properties that underpin deep soil carbon chemistry in an unfertilized calcareous soil. Soil was sampled up to 1 m in depth from irrigated and planted field treatments and was analyzed using a suite of omics and chemical analyses. The soil microbial community composition was impacted more by irrigation and plant cover treatmentsmore »« less

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