Dataset
- Version 1 of 1
Dataset
Title:
Related Party - Organisation (Author): Rothamsted Research - North Wyke
Related Party - Organisation (Funder): Defra
Abstract:
Subject Keywords: Slurry; Nitrous oxide; Ammonia; Cattle slurry; Trailing shoe; Bandspreading; Application timing; Hydrologically isolated plots; Grassland soils; Clay soils
Geographic Keywords: Devon; South West England; England; United Kingdom
Phenomenon Time - Start Date/Time: 2010-03-16 End Date/Time: 2011-05-05
Data Quality Statement:
Rothamsted Research is committed to complying with the standards of the RCUK Policy and Guidelines on Governance of Good Research Conduct, Joint Code of Practice for Research (JCoPR), BBSRC Statement on Safeguarding Good Science Practice, BBSRC data sharing policy and the environmental standard, ISO 14001. Rothamsted Research provides a quality-oriented environment: - Senior management approval of science projects before submission to sponsors. - Scrutiny to ratify the statistical design, management and output for all field, glasshouse and CE experiments. - Institute wide information tools, such as databases of standard operating procedures, risk assessments, COSHH forms, scientific samples, chemical stocks, staff CVs, training and laboratory notebooks. - Laboratory notebook procedures to ensure all operations are recorded, signed and dated, primary data are linked to secondary data, sample location is easily identified and in-house training is recorded. - Electronic data are maintained and backed up on networked servers. Every week a full copy is cycled to a separate physical location. - Environmental targets and objectives are set and environmental performance is monitored in accordance with ISO 14001. - A well-defined training programme for postgraduate students. - Experienced, professional staff provide scientists with support services including experimentation under field, glass and controlled environmental conditions. - High quality academic support services (Computing, Library, Statistics, BioImaging, Analytical Labs, Contracts, Finance and Quality Assurance) - Regular calibration and maintenance of equipment. - Senior management approval of all publications prior to submission and a policy that emphasises submission to peer-reviewed journals. - Facilities are available for Rothamsted to conduct work to support pesticide and semiochemical product approval or authorisation under its ORETO licence number 338, expiry 26 March 2018. Work is conducted to the requirements of this licence if specifically requested by sponsors. Note, Rothamsted Research does not follow GLP and is not accredited as a test facility under the Good Laboratory Practice Regulations, 1999. Project Leaders are responsible for science project work, including that of sub-contractors. Project planning involves risk management of the project. Staff and students on appointment are selected on the basis of how their skills meet the requirements of the project. Training is provided at induction and thereafter identified through annual staff appraisal. Responsibilities of staff involved in the project are formally set out in their written job description and forward job plan. Monitoring and improvement of scientific and environmental standards is achieved through the operation of internal and external procedures: - Monitoring of science output by senior management. - Reviewing progress of projects. - Evaluating reports from internal audits of science projects against the JCoPR, from all Rothamsted activities against the requirements of ISO 14001 and from all external audits. Detailed nitrous oxide emission measurement methodology: Direct N2O emissions were measured with five static flux chambers (40 cm wide x 40 cm long x 25 cm high) per plot, covering a total surface area of 0.8 m2. The chambers were of white (i.e. reflective) PVC and un-vented with a weighted lid and neoprene seal allowing an air-tight seal to form following chamber enclosure. Chambers were pushed into the soil up to a depth of 5 cm and remained in place throughout the experiment, except during slurry application when chambers were removed, locations were marked, and chambers were re-instated to the same position as prior to removal. Chambers remained open except for a short time on each sampling day. On that day, ten samples of ambient air were taken to represent time zero (T0) N2O samples. From each chamber, after a 40-minute enclosure period (T40) one headspace sample was taken using a 50-ml syringe and flushed though a pre-evacuated 20-22 ml glass vial fitted with a chloro-butyl rubber septum and held at atmospheric pressure. The N2O flux was calculated using an assumed linear increase in N2O concentration from the ambient N2O concentration (T0) to the N2O concentration inside the chamber after 40-minutes enclosure (T40) (Chadwick et al., 2014). Throughout each experiment, the linearity of emissions through time was checked from three chambers located on the slurry plots; three times per week during intensive sampling periods and monthly at all other times. A minimum of four samples were taken from each chamber at 20 min intervals commencing at closure i.e. T0 and spanning the T40 sampling time. In order to minimise the effect of diurnal variation, gas sampling was carried out between 10:00 am and 14:00 pm and where possible between 10:00 am and 12:00 pm as suggested by IAEA (1992) and referred to in the IPCC good practice guidance (IPCC, 2000). Gas samples were analysed as soon as possible after collection (to minimise potential leakage) using gas chromatographs fitted with an electron-capture detector and an automated sample injection system. Following receipt in the laboratory, two replicates of one standard N2O gas were kept with the samples and were used to verify sample integrity during storage. The gas chromatographs were calibrated on a daily basis using certified N2O standard gas mixtures. Following slurry application, N2O flux measurements were carried out for 5 days immediately following slurry application, daily for a further 5 days during the next week, twice weekly for the next two weeks, weekly for the next week and every other week for four months, decreasing in frequency to monthly until the end of the 12 month sampling period. Prior to the first slurry application N2O measurements were taken to provide baseline information. This sampling schedule resulted in an annual total of c.40 sampling days starting from the day of slurry application. Measurements were taken over 12 months to follow IPCC good practice guidance and so that the results were directly comparable to the IPCC 2006 methodology default emission factor. Nitrous oxide fluxes from the five replicate chambers per plot were averaged. Cumulative fluxes were calculated using the trapezoidal rule to interpolate fluxes between sampling points. References: Chadwick, D.R., Cardenas, L., Misselbrook, T.H., Smith, K.A., Rees, R.M., Watson, C.J., Mcgeough, K.L., Williams, J.R., Cloy, J.M., Thorman, R.E. and Dhanoa, M.S. (2014). Optimizing chamber methods for measuring nitrous oxide emissions from plot-based agricultural experiments. European Journal of Soil Science 65, 295-307. IAEA (1992). Manual on Measurement of Methane & Nitrous Oxide Emissions from Agriculture. International Atomic Energy Agency (IAEA), Vienna, IAEA-TECDOC-674, ISSN 10111-4289. IPCC (2000). Good Practice Guidance & Uncertainty Management in National Greenhouse Gas Inventories. Penman, J., Kruger, D., Galbally, I., Hiraishi, T., Nyenzi, B., Emmanul, S., Buendia, L., Hoppaus, R., Martinsen, T., Meijer, J., Miwa, K. and Tanabe, K. (Eds). IGES, Japan.
Publication Date:
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Rights Statement
Total file downloads: 1014
Title:
Nitrous Oxide and Ammonia Emissions from Multiple Pollutant Cracking Clay Experimental Sites. Devon, 2010
Related Party - Organisation (Author): Rothamsted Research - North Wyke
Related Party - Organisation (Funder): Defra
Abstract:
An experiment was conducted at North Wyke, Devon, UK, using 1 ha hydrologically isolated grassland plots on a clay loam soil (38% clay) overlaying an impermeable clay subsoil (the Rowden facility). Half of the plots are drained, with tile drains at 40 m spacing and 85 cm depth, with permeable backfill to within 30 cm of the surface, and with secondary mole drainage at 40 cm depth and 2 m spacing. Cattle slurry was applied at a target rate of 50 m3 ha-1 using a trailing shoe slurry spreader to each of three replicate drained and undrained plots at two application timings: spring (mid-March 2010) and summer (mid-June 2010). At each timing three replicate control plots, receiving no slurry, were also established on both the drained and undrained treatments. Nitrous oxide emissions were measured from each plot following slurry application, using the static chamber method, with 5 replicate chambers located in a sub-plot (18 x 6 m) at the centre of each 1 ha plot. Emission measurements were made on up to 40 occasions over a 12 month period following each slurry application. An annual emission factor was derived for each slurry application timing and drainage treatment as the net (of control value) annual cumulative N2O-N flux expressed as a percentage of the slurry N applied. Ammonia emissions from slurry-treated plots were measured for 7 days following slurry application, using the micrometeorological mass balance technique, employing passive flux samplers deployed on masts located at the centre and upwind edge of each plot.
The Devon, 2010 experiment contains data sets of; annual nitrous oxide emissions, annual nitrous oxide emission factors, total ammonia loss, temperature, rainfall and associated soil and manure measurements.
Subject Keywords: Slurry; Nitrous oxide; Ammonia; Cattle slurry; Trailing shoe; Bandspreading; Application timing; Hydrologically isolated plots; Grassland soils; Clay soils
Geographic Keywords: Devon; South West England; England; United Kingdom
Phenomenon Time - Start Date/Time: 2010-03-16 End Date/Time: 2011-05-05
Geographic Extent - Longitude (West): -4.04 Longitude (East): -3.75 Latitude (South): 50.68 Latitude (North): 50.85 |
Data Quality Statement:
Rothamsted Research is committed to complying with the standards of the RCUK Policy and Guidelines on Governance of Good Research Conduct, Joint Code of Practice for Research (JCoPR), BBSRC Statement on Safeguarding Good Science Practice, BBSRC data sharing policy and the environmental standard, ISO 14001. Rothamsted Research provides a quality-oriented environment: - Senior management approval of science projects before submission to sponsors. - Scrutiny to ratify the statistical design, management and output for all field, glasshouse and CE experiments. - Institute wide information tools, such as databases of standard operating procedures, risk assessments, COSHH forms, scientific samples, chemical stocks, staff CVs, training and laboratory notebooks. - Laboratory notebook procedures to ensure all operations are recorded, signed and dated, primary data are linked to secondary data, sample location is easily identified and in-house training is recorded. - Electronic data are maintained and backed up on networked servers. Every week a full copy is cycled to a separate physical location. - Environmental targets and objectives are set and environmental performance is monitored in accordance with ISO 14001. - A well-defined training programme for postgraduate students. - Experienced, professional staff provide scientists with support services including experimentation under field, glass and controlled environmental conditions. - High quality academic support services (Computing, Library, Statistics, BioImaging, Analytical Labs, Contracts, Finance and Quality Assurance) - Regular calibration and maintenance of equipment. - Senior management approval of all publications prior to submission and a policy that emphasises submission to peer-reviewed journals. - Facilities are available for Rothamsted to conduct work to support pesticide and semiochemical product approval or authorisation under its ORETO licence number 338, expiry 26 March 2018. Work is conducted to the requirements of this licence if specifically requested by sponsors. Note, Rothamsted Research does not follow GLP and is not accredited as a test facility under the Good Laboratory Practice Regulations, 1999. Project Leaders are responsible for science project work, including that of sub-contractors. Project planning involves risk management of the project. Staff and students on appointment are selected on the basis of how their skills meet the requirements of the project. Training is provided at induction and thereafter identified through annual staff appraisal. Responsibilities of staff involved in the project are formally set out in their written job description and forward job plan. Monitoring and improvement of scientific and environmental standards is achieved through the operation of internal and external procedures: - Monitoring of science output by senior management. - Reviewing progress of projects. - Evaluating reports from internal audits of science projects against the JCoPR, from all Rothamsted activities against the requirements of ISO 14001 and from all external audits. Detailed nitrous oxide emission measurement methodology: Direct N2O emissions were measured with five static flux chambers (40 cm wide x 40 cm long x 25 cm high) per plot, covering a total surface area of 0.8 m2. The chambers were of white (i.e. reflective) PVC and un-vented with a weighted lid and neoprene seal allowing an air-tight seal to form following chamber enclosure. Chambers were pushed into the soil up to a depth of 5 cm and remained in place throughout the experiment, except during slurry application when chambers were removed, locations were marked, and chambers were re-instated to the same position as prior to removal. Chambers remained open except for a short time on each sampling day. On that day, ten samples of ambient air were taken to represent time zero (T0) N2O samples. From each chamber, after a 40-minute enclosure period (T40) one headspace sample was taken using a 50-ml syringe and flushed though a pre-evacuated 20-22 ml glass vial fitted with a chloro-butyl rubber septum and held at atmospheric pressure. The N2O flux was calculated using an assumed linear increase in N2O concentration from the ambient N2O concentration (T0) to the N2O concentration inside the chamber after 40-minutes enclosure (T40) (Chadwick et al., 2014). Throughout each experiment, the linearity of emissions through time was checked from three chambers located on the slurry plots; three times per week during intensive sampling periods and monthly at all other times. A minimum of four samples were taken from each chamber at 20 min intervals commencing at closure i.e. T0 and spanning the T40 sampling time. In order to minimise the effect of diurnal variation, gas sampling was carried out between 10:00 am and 14:00 pm and where possible between 10:00 am and 12:00 pm as suggested by IAEA (1992) and referred to in the IPCC good practice guidance (IPCC, 2000). Gas samples were analysed as soon as possible after collection (to minimise potential leakage) using gas chromatographs fitted with an electron-capture detector and an automated sample injection system. Following receipt in the laboratory, two replicates of one standard N2O gas were kept with the samples and were used to verify sample integrity during storage. The gas chromatographs were calibrated on a daily basis using certified N2O standard gas mixtures. Following slurry application, N2O flux measurements were carried out for 5 days immediately following slurry application, daily for a further 5 days during the next week, twice weekly for the next two weeks, weekly for the next week and every other week for four months, decreasing in frequency to monthly until the end of the 12 month sampling period. Prior to the first slurry application N2O measurements were taken to provide baseline information. This sampling schedule resulted in an annual total of c.40 sampling days starting from the day of slurry application. Measurements were taken over 12 months to follow IPCC good practice guidance and so that the results were directly comparable to the IPCC 2006 methodology default emission factor. Nitrous oxide fluxes from the five replicate chambers per plot were averaged. Cumulative fluxes were calculated using the trapezoidal rule to interpolate fluxes between sampling points. References: Chadwick, D.R., Cardenas, L., Misselbrook, T.H., Smith, K.A., Rees, R.M., Watson, C.J., Mcgeough, K.L., Williams, J.R., Cloy, J.M., Thorman, R.E. and Dhanoa, M.S. (2014). Optimizing chamber methods for measuring nitrous oxide emissions from plot-based agricultural experiments. European Journal of Soil Science 65, 295-307. IAEA (1992). Manual on Measurement of Methane & Nitrous Oxide Emissions from Agriculture. International Atomic Energy Agency (IAEA), Vienna, IAEA-TECDOC-674, ISSN 10111-4289. IPCC (2000). Good Practice Guidance & Uncertainty Management in National Greenhouse Gas Inventories. Penman, J., Kruger, D., Galbally, I., Hiraishi, T., Nyenzi, B., Emmanul, S., Buendia, L., Hoppaus, R., Martinsen, T., Meijer, J., Miwa, K. and Tanabe, K. (Eds). IGES, Japan.
Publication Date:
2017-04-11
To discuss any issues relating to this dataset please either send an email to dis@fba.org.uk or post to our forum
Download All 0.07MB
All Version Downloads
Rights Statement
This data is published under the licence FBA Licence
Attribution: T.H. Misselbrook, N. Donovan, V. Camp, C. Hodgson and D.R. Chadwick
Citation of this data should be as follows:
T.H. Misselbrook, N. Donovan, V. Camp, C. Hodgson and D.R. Chadwick (2017): Nitrous Oxide and Ammonia Emissions from Multiple Pollutant Cracking Clay Experimental Sites. Devon, 2010. Version:1. [dataset] Freshwater Biological Association [publisher]. doi:10.17865/ghgno773
Total file downloads: 1014
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