Cosmic-ray neutron transport at a forest field site - Ansatte der arbejder med Geologi

Institut for Geovidenskab og Naturforvaltning

Cosmic-ray neutron transport at a forest field site: The sensitivity to various environmental conditions with focus on biomass and canopy interception

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Standard

Cosmic-ray neutron transport at a forest field site : The sensitivity to various environmental conditions with focus on biomass and canopy interception. / Andreasen, Mie; Jensen, Karsten Høgh; Desilets, Darin; Zreda, Marek; Bogena, Heye R.; Zibar, Majken C. L.

I: Hydrology and Earth System Sciences, Bind 21, Nr. 4, 2017, s. 1875-1894.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Andreasen, M, Jensen, KH, Desilets, D, Zreda, M, Bogena, HR & Zibar, MCL 2017, 'Cosmic-ray neutron transport at a forest field site: The sensitivity to various environmental conditions with focus on biomass and canopy interception', Hydrology and Earth System Sciences, bind 21, nr. 4, s. 1875-1894. https://doi.org/10.5194/hess-21-1875-2017

APA

Andreasen, M., Jensen, K. H., Desilets, D., Zreda, M., Bogena, H. R., & Zibar, M. C. L. (2017). Cosmic-ray neutron transport at a forest field site: The sensitivity to various environmental conditions with focus on biomass and canopy interception. Hydrology and Earth System Sciences, 21(4), 1875-1894. https://doi.org/10.5194/hess-21-1875-2017

Vancouver

Andreasen M, Jensen KH, Desilets D, Zreda M, Bogena HR, Zibar MCL. Cosmic-ray neutron transport at a forest field site: The sensitivity to various environmental conditions with focus on biomass and canopy interception. Hydrology and Earth System Sciences. 2017;21(4):1875-1894. https://doi.org/10.5194/hess-21-1875-2017

Author

Andreasen, Mie ; Jensen, Karsten Høgh ; Desilets, Darin ; Zreda, Marek ; Bogena, Heye R. ; Zibar, Majken C. L. / Cosmic-ray neutron transport at a forest field site : The sensitivity to various environmental conditions with focus on biomass and canopy interception. I: Hydrology and Earth System Sciences. 2017 ; Bind 21, Nr. 4. s. 1875-1894.

Bibtex

@article{26b947c42f1240d89fbc621939c23869,

title = "Cosmic-ray neutron transport at a forest field site: The sensitivity to various environmental conditions with focus on biomass and canopy interception",

abstract = "Cosmic-ray neutron intensity is inversely correlated to all hydrogen present in the upper decimeters of the subsurface and the first few hectometers of the atmosphere above the ground surface. This correlation forms the base of the cosmic-ray neutron soil moisture estimation method. The method is, however, complicated by the fact that several hydrogen pools other than soil moisture affect the neutron intensity. In order to improve the cosmic-ray neutron soil moisture estimation method and explore the potential for additional applications, knowledge about the environmental effect on cosmic-ray neutron intensity is essential (e.g., the effect of vegetation, litter layer and soil type). In this study the environmental effect is examined by performing a sensitivity analysis using neutron transport modeling. We use a neutron transport model with various representations of the forest and different parameters describing the subsurface to match measured height profiles and time series of thermal and epithermal neutron intensities at a field site in Denmark. Overall, modeled thermal and epithermal neutron intensities are in satisfactory agreement with measurements; however, the choice of forest canopy conceptualization is found to be significant. Modeling results show that the effect of canopy interception, soil chemistry and dry bulk density of litter and mineral soil on neutron intensity is small. On the other hand, the neutron intensity decreases significantly with added litter-layer thickness, especially for epithermal neutron energies. Forest biomass also has a significant influence on the neutron intensity height profiles at the examined field site, altering both the shape of the profiles and the ground-level thermal-to-epithermal neutron ratio. This ratio increases with increasing amounts of biomass, and was confirmed by measurements from three sites representing agricultural, heathland and forest land cover. A much smaller effect of canopy interception on the ground-level thermal-to-epithermal neutron ratio was modeled. Overall, the results suggest a potential to use ground-level thermal-to-epithermal neutron ratios to discriminate the effect of different hydrogen contributions on the neutron signal.",

author = "Mie Andreasen and Jensen, {Karsten H{\o}gh} and Darin Desilets and Marek Zreda and Bogena, {Heye R.} and Zibar, {Majken C. L.}",

year = "2017",

doi = "10.5194/hess-21-1875-2017",

language = "English",

volume = "21",

pages = "1875--1894",

journal = "Hydrology and Earth System Sciences",

issn = "1027-5606",

publisher = "Copernicus GmbH",

number = "4",

}

RIS

TY - JOUR

T1 - Cosmic-ray neutron transport at a forest field site

T2 - The sensitivity to various environmental conditions with focus on biomass and canopy interception

AU - Andreasen, Mie

AU - Jensen, Karsten Høgh

AU - Desilets, Darin

AU - Zreda, Marek

AU - Bogena, Heye R.

AU - Zibar, Majken C. L.

PY - 2017

Y1 - 2017

N2 - Cosmic-ray neutron intensity is inversely correlated to all hydrogen present in the upper decimeters of the subsurface and the first few hectometers of the atmosphere above the ground surface. This correlation forms the base of the cosmic-ray neutron soil moisture estimation method. The method is, however, complicated by the fact that several hydrogen pools other than soil moisture affect the neutron intensity. In order to improve the cosmic-ray neutron soil moisture estimation method and explore the potential for additional applications, knowledge about the environmental effect on cosmic-ray neutron intensity is essential (e.g., the effect of vegetation, litter layer and soil type). In this study the environmental effect is examined by performing a sensitivity analysis using neutron transport modeling. We use a neutron transport model with various representations of the forest and different parameters describing the subsurface to match measured height profiles and time series of thermal and epithermal neutron intensities at a field site in Denmark. Overall, modeled thermal and epithermal neutron intensities are in satisfactory agreement with measurements; however, the choice of forest canopy conceptualization is found to be significant. Modeling results show that the effect of canopy interception, soil chemistry and dry bulk density of litter and mineral soil on neutron intensity is small. On the other hand, the neutron intensity decreases significantly with added litter-layer thickness, especially for epithermal neutron energies. Forest biomass also has a significant influence on the neutron intensity height profiles at the examined field site, altering both the shape of the profiles and the ground-level thermal-to-epithermal neutron ratio. This ratio increases with increasing amounts of biomass, and was confirmed by measurements from three sites representing agricultural, heathland and forest land cover. A much smaller effect of canopy interception on the ground-level thermal-to-epithermal neutron ratio was modeled. Overall, the results suggest a potential to use ground-level thermal-to-epithermal neutron ratios to discriminate the effect of different hydrogen contributions on the neutron signal.

AB - Cosmic-ray neutron intensity is inversely correlated to all hydrogen present in the upper decimeters of the subsurface and the first few hectometers of the atmosphere above the ground surface. This correlation forms the base of the cosmic-ray neutron soil moisture estimation method. The method is, however, complicated by the fact that several hydrogen pools other than soil moisture affect the neutron intensity. In order to improve the cosmic-ray neutron soil moisture estimation method and explore the potential for additional applications, knowledge about the environmental effect on cosmic-ray neutron intensity is essential (e.g., the effect of vegetation, litter layer and soil type). In this study the environmental effect is examined by performing a sensitivity analysis using neutron transport modeling. We use a neutron transport model with various representations of the forest and different parameters describing the subsurface to match measured height profiles and time series of thermal and epithermal neutron intensities at a field site in Denmark. Overall, modeled thermal and epithermal neutron intensities are in satisfactory agreement with measurements; however, the choice of forest canopy conceptualization is found to be significant. Modeling results show that the effect of canopy interception, soil chemistry and dry bulk density of litter and mineral soil on neutron intensity is small. On the other hand, the neutron intensity decreases significantly with added litter-layer thickness, especially for epithermal neutron energies. Forest biomass also has a significant influence on the neutron intensity height profiles at the examined field site, altering both the shape of the profiles and the ground-level thermal-to-epithermal neutron ratio. This ratio increases with increasing amounts of biomass, and was confirmed by measurements from three sites representing agricultural, heathland and forest land cover. A much smaller effect of canopy interception on the ground-level thermal-to-epithermal neutron ratio was modeled. Overall, the results suggest a potential to use ground-level thermal-to-epithermal neutron ratios to discriminate the effect of different hydrogen contributions on the neutron signal.

U2 - 10.5194/hess-21-1875-2017

DO - 10.5194/hess-21-1875-2017

M3 - Journal article

AN - SCOPUS:85016816123

VL - 21

SP - 1875

EP - 1894

JO - Hydrology and Earth System Sciences

JF - Hydrology and Earth System Sciences

SN - 1027-5606

IS - 4

ER -

ID: 179164844