Validation of a new gamma ray soil bulk density sensor
Soil compaction and soil bulk density are key soil properties affecting soil health and soil ecosystem services like crop production, water retention and purification and carbon sequestration. The standard method for soil bulk density measurements using Kopecky rings is very labour intensive, time consuming and leaves notable damage to the field. Accurate data on bulk density are therefore scarce. To enable large-scale data collection, we tested a new portable gamma ray sensor (RhoC) for in situ field and dry bulk density measurements up to 1 m depth. In this first validation study, measurements with the RhoC-sensor were compared with classic ring sampling. Measurements were made in two agricultural fields in the Netherlands (a sandy clay loam and a sandy soil), with large variation in subsoil compaction. At 10 locations within each field, three soil density profiles were made. Each profile comprised six depth measurements (every 10 cm from 10 to 60 cm depth) using the RhoC-sensor and Kopecky rings, resulting in 30 pairwise profiles and 180 measurements in total per field. At an average soil density of 1.5 g/cm3, the relative uncertainty was 9% for the Kopecky rings and 15% for the RhoC-sensor. Because the RhoC-sensor is easy and quick to use, the higher relative uncertainty can easily be compensated for by making additional measurements per location. In conclusion, the RhoC-sensor allows a reliable quantitative in situ assessment of both field and dry bulk density. This provides the much-needed possibility for rapid and accurate assessment of soil compaction. The acquisition of this data supports the calculation of soil organic carbon stocks and is indispensable for (national) soil monitoring, to assess soil health and to inform sustainable land management practices for sustained or improved soil health and provision of soil ecosystem services, such as requested in the proposed EU Directive on Soil Monitoring and Resilience.
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| Format: | Article/Letter to editor biblioteca |
| Language: | English |
| Subjects: | RhoC-sensor, gamma-ray attenuation, in situ measurement, mineral soil, novel sensor technique, soil compaction, soil monitoring, soil organic carbon stocks, soil threat analysis, |
| Online Access: | https://research.wur.nl/en/publications/validation-of-a-new-gamma-ray-soil-bulk-density-sensor |
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dig-wur-nl-wurpubs-6325182024-10-02 Pepers, Karin H.J. van Egmond, Fenny Koomans, Ronald Teuling, Kees Staats, Gijs van Os, Gera Article/Letter to editor European Journal of Soil Science 75 (2024) 4 ISSN: 1351-0754 Validation of a new gamma ray soil bulk density sensor 2024 Soil compaction and soil bulk density are key soil properties affecting soil health and soil ecosystem services like crop production, water retention and purification and carbon sequestration. The standard method for soil bulk density measurements using Kopecky rings is very labour intensive, time consuming and leaves notable damage to the field. Accurate data on bulk density are therefore scarce. To enable large-scale data collection, we tested a new portable gamma ray sensor (RhoC) for in situ field and dry bulk density measurements up to 1 m depth. In this first validation study, measurements with the RhoC-sensor were compared with classic ring sampling. Measurements were made in two agricultural fields in the Netherlands (a sandy clay loam and a sandy soil), with large variation in subsoil compaction. At 10 locations within each field, three soil density profiles were made. Each profile comprised six depth measurements (every 10 cm from 10 to 60 cm depth) using the RhoC-sensor and Kopecky rings, resulting in 30 pairwise profiles and 180 measurements in total per field. At an average soil density of 1.5 g/cm3, the relative uncertainty was 9% for the Kopecky rings and 15% for the RhoC-sensor. Because the RhoC-sensor is easy and quick to use, the higher relative uncertainty can easily be compensated for by making additional measurements per location. In conclusion, the RhoC-sensor allows a reliable quantitative in situ assessment of both field and dry bulk density. This provides the much-needed possibility for rapid and accurate assessment of soil compaction. The acquisition of this data supports the calculation of soil organic carbon stocks and is indispensable for (national) soil monitoring, to assess soil health and to inform sustainable land management practices for sustained or improved soil health and provision of soil ecosystem services, such as requested in the proposed EU Directive on Soil Monitoring and Resilience. en application/pdf https://research.wur.nl/en/publications/validation-of-a-new-gamma-ray-soil-bulk-density-sensor 10.1111/ejss.13542 https://edepot.wur.nl/670332 RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis https://creativecommons.org/licenses/by/4.0/ https://creativecommons.org/licenses/by/4.0/ Wageningen University & Research |
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RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis |
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RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis Pepers, Karin H.J. van Egmond, Fenny Koomans, Ronald Teuling, Kees Staats, Gijs van Os, Gera Validation of a new gamma ray soil bulk density sensor |
| description |
Soil compaction and soil bulk density are key soil properties affecting soil health and soil ecosystem services like crop production, water retention and purification and carbon sequestration. The standard method for soil bulk density measurements using Kopecky rings is very labour intensive, time consuming and leaves notable damage to the field. Accurate data on bulk density are therefore scarce. To enable large-scale data collection, we tested a new portable gamma ray sensor (RhoC) for in situ field and dry bulk density measurements up to 1 m depth. In this first validation study, measurements with the RhoC-sensor were compared with classic ring sampling. Measurements were made in two agricultural fields in the Netherlands (a sandy clay loam and a sandy soil), with large variation in subsoil compaction. At 10 locations within each field, three soil density profiles were made. Each profile comprised six depth measurements (every 10 cm from 10 to 60 cm depth) using the RhoC-sensor and Kopecky rings, resulting in 30 pairwise profiles and 180 measurements in total per field. At an average soil density of 1.5 g/cm3, the relative uncertainty was 9% for the Kopecky rings and 15% for the RhoC-sensor. Because the RhoC-sensor is easy and quick to use, the higher relative uncertainty can easily be compensated for by making additional measurements per location. In conclusion, the RhoC-sensor allows a reliable quantitative in situ assessment of both field and dry bulk density. This provides the much-needed possibility for rapid and accurate assessment of soil compaction. The acquisition of this data supports the calculation of soil organic carbon stocks and is indispensable for (national) soil monitoring, to assess soil health and to inform sustainable land management practices for sustained or improved soil health and provision of soil ecosystem services, such as requested in the proposed EU Directive on Soil Monitoring and Resilience. |
| format |
Article/Letter to editor |
| topic_facet |
RhoC-sensor gamma-ray attenuation in situ measurement mineral soil novel sensor technique soil compaction soil monitoring soil organic carbon stocks soil threat analysis |
| author |
Pepers, Karin H.J. van Egmond, Fenny Koomans, Ronald Teuling, Kees Staats, Gijs van Os, Gera |
| author_facet |
Pepers, Karin H.J. van Egmond, Fenny Koomans, Ronald Teuling, Kees Staats, Gijs van Os, Gera |
| author_sort |
Pepers, Karin H.J. |
| title |
Validation of a new gamma ray soil bulk density sensor |
| title_short |
Validation of a new gamma ray soil bulk density sensor |
| title_full |
Validation of a new gamma ray soil bulk density sensor |
| title_fullStr |
Validation of a new gamma ray soil bulk density sensor |
| title_full_unstemmed |
Validation of a new gamma ray soil bulk density sensor |
| title_sort |
validation of a new gamma ray soil bulk density sensor |
| url |
https://research.wur.nl/en/publications/validation-of-a-new-gamma-ray-soil-bulk-density-sensor |
| work_keys_str_mv |
AT peperskarinhj validationofanewgammaraysoilbulkdensitysensor AT vanegmondfenny validationofanewgammaraysoilbulkdensitysensor AT koomansronald validationofanewgammaraysoilbulkdensitysensor AT teulingkees validationofanewgammaraysoilbulkdensitysensor AT staatsgijs validationofanewgammaraysoilbulkdensitysensor AT vanosgera validationofanewgammaraysoilbulkdensitysensor |
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