Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”

Dove, Nicholas; Torn, Margaret; Hart, Stephen; Tas, Neslihan

doi:10.15485/1866269

Title: Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”

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Abstract

This dataset contains soil chemistry data of soils from the whole-soil warming experiment at Blodgett Forest in June 2018, and from laboratory incubation experiments conducted with a subset of those soils. Soil samples were collected at five different depths down to 80 cm from soil plots continuously heated by 4°C above ambient temperature for 4.5 years, and from the respective unheated control plots. Incubation experiments were conducted for 28 days with soils collected between 10-30 cm (“surface soils”) and 60-80 cm (“subsoils”) from heated and unheated field plots, amended in the laboratory with cellobiose (C, carbon amendment), or cellobiose plus ammonium and phosphate (CNP, combined carbon, nitrogen and phosphorus amendment). The dataset includes separate files for: (i) total carbon and nitrogen concentrations of initial field soils; (ii) carbon dioxide efflux rates at multiple times throughout the incubation experiments, and respective cumulative carbon dioxide efflux rates, as well as inorganic nitrogen concentrations at the beginning and end of the incubations, and net nitrogen mineralization rates and carbon use efficiency calculated at the end of the incubation. Analysis of these data has been published in Dove et al., (2021), “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughoutmore »« less

Authors:

;

ESS-DIVE
Lawrence Berkeley National Laboratory
University of California Merced

Publication Date:: Sat Jan 01 04:00:00 UTC 2022

Research Org.:: Environmental System Science Data Infrastructure for a Virtual Ecosystem; Belowground Biogeochemistry Scientific Focus Area

Sponsoring Org.:: US.DOE. > Office of Science > Biological and Environmental Research (BER)

Subject:: 54 ENVIRONMENTAL SCIENCES; ESS-DIVE CSV File Formatting Guidelines Reporting Format; ESS-DIVE File Level Metadata Reporting Format; Earth Science > Land Science > Soils > Carbon > Soil organic Carbon (SOC); Earth Science > Land Science > Soils > Microbial Carbon Use Efficiency; Earth Science > Land Science > Soils > Nitrification Rate; Earth Science > Land Science > Soils > Nitrogen; Earth Science > Land Science > Soils > Phosphorus; Earth Science > Land Science > Soils > Soil Depth; Earth Science > Land Science > Soils > Soil Respiration > Heterotrophic respiration; Earth Science > Land Science > Soils > Soil Temperature; microbial_carbon_use_efficiency; soil_mass_content_of_carbon; soil_mass_content_of_inorganic_ammonium_expressed_as_nitrogen; soil_mass_content_of_inorganic_nitrate_expressed_as_nitrogen; soil_mass_content_of_nitrogen

OSTI Identifier:: 1866269

DOI:: https://doi.org/10.15485/1866269

Citation Formats


                    Dove, Nicholas, Torn, Margaret, Hart, Stephen, and Tas, Neslihan. Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”.  United States: N. p., 2022. 
        Web.  doi:10.15485/1866269.

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                    Dove, Nicholas, Torn, Margaret, Hart, Stephen, & Tas, Neslihan. Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”.  United States.  doi:https://doi.org/10.15485/1866269

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                    Dove, Nicholas, Torn, Margaret, Hart, Stephen, and Tas, Neslihan. 2022.  
"Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”".  United States.  doi:https://doi.org/10.15485/1866269.  https://www.osti.gov/servlets/purl/1866269. Pub date:Sat Jan 01 04:00:00 UTC 2022

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@article{osti_1866269,

  title        = {Chemistry data from soils and soil incubation experiments from the whole-soil warming experiment at Blodgett Forest, CA, 2018, from: “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile”},

  author       = {Dove, Nicholas and Torn, Margaret and Hart, Stephen and Tas, Neslihan},

  abstractNote = {This dataset contains soil chemistry data of soils from the whole-soil warming experiment at Blodgett Forest in June 2018, and from laboratory incubation experiments conducted with a subset of those soils. Soil samples were collected at five different depths down to 80 cm from soil plots continuously heated by 4°C above ambient temperature for 4.5 years, and from the respective unheated control plots. Incubation experiments were conducted for 28 days with soils collected between 10-30 cm (“surface soils”) and 60-80 cm (“subsoils”) from heated and unheated field plots, amended in the laboratory with cellobiose (C, carbon amendment), or cellobiose plus ammonium and phosphate (CNP, combined carbon, nitrogen and phosphorus amendment). The dataset includes separate files for: (i) total carbon and nitrogen concentrations of initial field soils; (ii) carbon dioxide efflux rates at multiple times throughout the incubation experiments, and respective cumulative carbon dioxide efflux rates, as well as inorganic nitrogen concentrations at the beginning and end of the incubations, and net nitrogen mineralization rates and carbon use efficiency calculated at the end of the incubation. Analysis of these data has been published in Dove et al., (2021), “Metabolic capabilities mute positive response to direct and indirect impacts of warming throughout the soil profile. Nat. Commun. 12:2089”, https://doi.org/10.1038/s41467-021-22408-5. This research was performed as part of the TES Belowground Biogeochemistry SFA project at Lawrence Berkeley National Laboratory.},

  doi          = {10.15485/1866269},

  journal      = {},

  number       = ,

  volume       = ,

  place        = {United States},

  year         = {Sat Jan 01 04:00:00 UTC 2022},

  month        = {Sat Jan 01 04:00:00 UTC 2022}

}

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DOI: https://doi.org/10.15485/1866269

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