Electrical conductivity monitoring of soil condition and available N with animal manure and a cover crop

Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and to synchronize the levels of soil available N with crop plant needs during the growing season. This study was conducted at the US Meat Animal...

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Published inAgriculture, ecosystems & environment Vol. 88; no. 2; pp. 183 - 193
Main Authors Eigenberg, R.A, Doran, J.W, Nienaber, J.A, Ferguson, R.B, Woodbury, B.L
Format Journal Article Conference Proceeding
LanguageEnglish
Published Amsterdam Elsevier B.V 01.02.2002
Elsevier Science
Subjects
agriculture
Agronomy. Soil science and plant productions
animal manures
Biological and medical sciences
cover crops
electrical conductivity
Electromagnetic induction
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Manure
monitoring
Nebraska
Nutrient availability
nutrient requirements
Other nutrients. Amendments. Solid and liquid wastes. Sludges and slurries
Secale cereale
Silage corn
Soil electrical conductivity
soil fertility
Soil-plant relationships. Soil fertility. Fertilization. Amendments
Zea mays
United States
North America
America
Nebraska
EC, electrical conductivity
ECa, profile weighted electrical conductivity
Manure
GPS, global positioning system
EM, electromagnetic
Electromagnetic induction
Nutrient availability
USMARC, US Meat Animal Research Center
Silage corn
Soil electrical conductivity
Compost
Nitrogen fertilization
Monocotyledones
Electrical conductivity
Secale cereale
Zea mays
Cover crop
Available nutrient
Cropping system
Soil quality
Organic fertilization
Organic fertilizer
Mollisols
Nitrogen
Farmyard manure
Inorganic element
Cereal crop
Agroecosystem
Silt loam soil
Gramineae
Angiospermae
Nutrient
Spermatophyta
Monitoring
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Abstract Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and to synchronize the levels of soil available N with crop plant needs during the growing season. This study was conducted at the US Meat Animal Research Center in the central USA to determine whether differences in electromagnetic (EM) soil conductivity and available N levels over a growing season can be linked to feedlot manure/compost application and use of a green winter cover crop. A series of soil conductivity maps of a research cornfield were generated using global positioning system (GPS) and EM induction methods. The study site was treated over a 7-year period with manure and compost at rates matching either the phosphorus or the nitrogen requirements of silage corn (Zea mays L.). The plot was split for sub-treatments of a rye (Secale cereale L.) winter cover crop and no cover crop. Image processing techniques were used to establish electrical conductivity (EC) treatment means for each of the growing season surveys. Sequential measurement of profile weighted soil electrical conductivity (ECa) was effective in identifying the dynamic changes in available soil N, as affected by animal manure and N fertilizer treatments, during the corn-growing season. This method also clearly identified the effectiveness of cover crops in minimizing levels of available soil N before and after the corn-growing season, when soluble N is most subject to loss. The EM method for assessing soil condition provides insights into the dynamics of available N transformations that are supported by soil chemical analyses. This real-time monitoring approach could also be useful to farmers in enhancing N use efficiencies of cropping management systems and in minimizing N losses to the environment.
AbstractList Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and to synchronize the levels of soil available N with crop plant needs during the growing season. This study was conducted at the US Meat Animal Research Center in the central USA to determine whether differences in electromagnetic (EM) soil conductivity and available N levels over a growing season can be linked to feedlot manure/compost application and use of a green winter cover crop. A series of soil conductivity maps of a research cornfield were generated using global positioning system (GPS) and EM induction methods. The study site was treated over a 7-year period with manure and compost at rates matching either the phosphorus or the nitrogen requirements of silage corn (Zea mays L.). The plot was split for sub-treatments of a rye (Secale cereale L.) winter cover crop and no cover crop. Image processing techniques were used to establish electrical conductivity (EC) treatment means for each of the growing season surveys. Sequential measurement of profile weighted soil electrical conductivity (EC sub(a)) was effective in identifying the dynamic changes in available soil N, as affected by animal manure and N fertilizer treatments, during the corn-growing season. This method also clearly identified the effectiveness of cover crops in minimizing levels of available soil N before and after the corn-growing season, when soluble N is most subject to loss. The EM method for assessing soil condition provides insights into the dynamics of available N transformations that are supported by soil chemical analyses. This real-time monitoring approach could also be useful to farmers in enhancing N use efficiencies of cropping management systems and in minimizing N losses to the environment.
Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and to synchronize the levels of soil available N with crop plant needs during the growing season. This study was conducted at the US Meat Animal Research Center in the central USA to determine whether differences in electromagnetic (EM) soil conductivity and available N levels over a growing season can be linked to feedlot manure/compost application and use of a green winter cover crop. A series of soil conductivity maps of a research cornfield were generated using global positioning system (GPS) and EM induction methods. The study site was treated over a 7-year period with manure and compost at rates matching either the phosphorus or the nitrogen requirements of silage corn (Zea mays L.). The plot was split for sub-treatments of a rye (Secale cereale L.) winter cover crop and no cover crop. Image processing techniques were used to establish electrical conductivity (EC) treatment means for each of the growing season surveys. Sequential measurement of profile weighted soil electrical conductivity (EC(a)) was effective in identifying the dynamic changes in available soil N, as affected by animal manure and N fertilizer treatments, during the corn-growing season. This method also clearly identified the effectiveness of cover crops in minimizing levels of available soil N before and after the corn-growing season, when soluble N is most subject to loss. The EM method for assessing soil condition provides insights into the dynamics of available N transformations that are supported by soil chemical analyses. This real-time monitoring approach could also be useful to farmers in enhancing N use efficiencies of cropping management systems and in minimizing N losses to the environment.
Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and to synchronize the levels of soil available N with crop plant needs during the growing season. This study was conducted at the US Meat Animal Research Center in the central USA to determine whether differences in electromagnetic (EM) soil conductivity and available N levels over a growing season can be linked to feedlot manure/compost application and use of a green winter cover crop. A series of soil conductivity maps of a research cornfield were generated using global positioning system (GPS) and EM induction methods. The study site was treated over a 7-year period with manure and compost at rates matching either the phosphorus or the nitrogen requirements of silage corn (Zea mays L.). The plot was split for sub-treatments of a rye (Secale cereale L.) winter cover crop and no cover crop. Image processing techniques were used to establish electrical conductivity (EC) treatment means for each of the growing season surveys. Sequential measurement of profile weighted soil electrical conductivity (ECa) was effective in identifying the dynamic changes in available soil N, as affected by animal manure and N fertilizer treatments, during the corn-growing season. This method also clearly identified the effectiveness of cover crops in minimizing levels of available soil N before and after the corn-growing season, when soluble N is most subject to loss. The EM method for assessing soil condition provides insights into the dynamics of available N transformations that are supported by soil chemical analyses. This real-time monitoring approach could also be useful to farmers in enhancing N use efficiencies of cropping management systems and in minimizing N losses to the environment.
Development of sustainable agricultural systems will require better use of such renewable resources as animal manure and synchronizing soil available nitrogen (N) with crop plant needs. Linkages between electromagnetic (EM) soil conductivity, available N over a growing season, manure application, and use of a green winter cover crop were studied. Soil conductivity maps of a research cornfield were generated using a global positioning system and EM measurements. Manure/compost was applied over 7 yr to match either the N or the phosphorus requirements of corn. A rye winter cover crop was planted on some sub-plots. Soil profile weighted electrical conductivity was an effective measure of dynamic changes in soil available N, as affected by manure and fertilizer treatments, and also effectively identified cover crop effects of minimizing available soil N before and after the corn growing season. Real time EM monitoring could prove useful to farmers seeking to enhance N use efficiencies of crops and to minimize N losses to the environment.
Author Ferguson, R.B
Doran, J.W
Woodbury, B.L
Eigenberg, R.A
Nienaber, J.A
Author_xml – sequence: 1
  givenname: R.A
  surname: Eigenberg
  fullname: Eigenberg, R.A
  email: eigenberg@mail.marc.usda.gov
  organization: Biological Engineering Research Unit, USDA-ARS US Meat Animal Research Center, P.O. Box 166, Clay Center, NE 68933, USA
– sequence: 2
  givenname: J.W
  surname: Doran
  fullname: Doran, J.W
  organization: USDA-ARS Soil and Water Conservation Research, University of Nebraska, Lincoln, NE 68583, USA
– sequence: 3
  givenname: J.A
  surname: Nienaber
  fullname: Nienaber, J.A
  organization: Biological Engineering Research Unit, USDA-ARS US Meat Animal Research Center, P.O. Box 166, Clay Center, NE 68933, USA
– sequence: 4
  givenname: R.B
  surname: Ferguson
  fullname: Ferguson, R.B
  organization: South Central Research and Extension Center, P.O. Box 66, University of Nebraska, Clay Center, NE 68933, USA
– sequence: 5
  givenname: B.L
  surname: Woodbury
  fullname: Woodbury, B.L
  organization: Biological Engineering Research Unit, USDA-ARS US Meat Animal Research Center, P.O. Box 166, Clay Center, NE 68933, USA
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Issue 2
Keywords EC, electrical conductivity
ECa, profile weighted electrical conductivity
Manure
GPS, global positioning system
EM, electromagnetic
Electromagnetic induction
Nutrient availability
USMARC, US Meat Animal Research Center
Silage corn
Soil electrical conductivity
Compost
Nitrogen fertilization
Monocotyledones
Electrical conductivity
Secale cereale
Zea mays
Cover crop
Available nutrient
Cropping system
Soil quality
Organic fertilization
Organic fertilizer
Mollisols
Nitrogen
Farmyard manure
Inorganic element
Cereal crop
Agroecosystem
Silt loam soil
Gramineae
Angiospermae
Nutrient
Spermatophyta
Monitoring
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Snippet Development of sustainable agricultural management systems will depend, in part, on the ability to better use renewable resources, such as animal manure, and...
Development of sustainable agricultural systems will require better use of such renewable resources as animal manure and synchronizing soil available nitrogen...
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SubjectTerms agriculture
Agronomy. Soil science and plant productions
animal manures
Biological and medical sciences
cover crops
electrical conductivity
Electromagnetic induction
Fundamental and applied biological sciences. Psychology
General agronomy. Plant production
Manure
monitoring
Nebraska
Nutrient availability
nutrient requirements
Other nutrients. Amendments. Solid and liquid wastes. Sludges and slurries
Secale cereale
Silage corn
Soil electrical conductivity
soil fertility
Soil-plant relationships. Soil fertility. Fertilization. Amendments
Zea mays
Title Electrical conductivity monitoring of soil condition and available N with animal manure and a cover crop
URI https://dx.doi.org/10.1016/S0167-8809(01)00256-0
https://www.proquest.com/docview/14602838
https://www.proquest.com/docview/16131489
https://www.proquest.com/docview/47710152
Volume 88
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