Your search keyword '"van Emmerik, T.H.M. (author)"' showing total 4 results

1. A comparison between leaf dielectric properties of stressed and unstressed tomato plants

Author

Van Emmerik, T.H.M. (author), Steele-Dunne, S.C. (author), Judge, J. (author), Van de Giesen, N.C. (author), Van Emmerik, T.H.M. (author), Steele-Dunne, S.C. (author), Judge, J. (author), and Van de Giesen, N.C. (author)

Abstract

Leaf dielectric properties influence microwave scattering from a vegetation canopy. The dielectric properties of leaves are primarily a function of leaf water content. Understanding the effect of water stress on leaf dielectric properties will give insight in how plant dynamics change as a result of water stress, and how radar can be used for early water stress detection over agricultural canopies. This paper presents in-vivo measurements of leaf dielectric properties. Different relationships between leaf water content and leaf dielectric properties were found tomato leaves at various heights. The dielectric properties of live stressed and unstressed tomato plants were measured during a controlled, two-week experiment. A clear difference was found between the leaf dielectric properties of stressed and unstressed leaves, which can be attributed to increase in water stress. This results of this study show changes in plant dynamics due to water stress lead to a difference in leaf dielectric properties between stressed and unstressed plants., Water Management, Civil Engineering and Geosciences

Published

2015

2. A comparison between leaf dielectric properties of stressed and unstressed tomato plants

Author

Van Emmerik, T.H.M. (author), Steele-Dunne, S.C. (author), Judge, J. (author), Van de Giesen, N.C. (author), Van Emmerik, T.H.M. (author), Steele-Dunne, S.C. (author), Judge, J. (author), and Van de Giesen, N.C. (author)

Abstract

Leaf dielectric properties influence microwave scattering from a vegetation canopy. The dielectric properties of leaves are primarily a function of leaf water content. Understanding the effect of water stress on leaf dielectric properties will give insight in how plant dynamics change as a result of water stress, and how radar can be used for early water stress detection over agricultural canopies. This paper presents in-vivo measurements of leaf dielectric properties. Different relationships between leaf water content and leaf dielectric properties were found tomato leaves at various heights. The dielectric properties of live stressed and unstressed tomato plants were measured during a controlled, two-week experiment. A clear difference was found between the leaf dielectric properties of stressed and unstressed leaves, which can be attributed to increase in water stress. This results of this study show changes in plant dynamics due to water stress lead to a difference in leaf dielectric properties between stressed and unstressed plants., Water Management, Civil Engineering and Geosciences

Published

2015

3. Impact of diurnal variation in vegetation water content on radar backscatter from maize during water stress

Author

Van Emmerik, T.H.M. (author), Dunne, S.C. (author), Judge, J. (author), van de Giesen, N.C. (author), Van Emmerik, T.H.M. (author), Dunne, S.C. (author), Judge, J. (author), and van de Giesen, N.C. (author)

Abstract

Microwave backscatter from vegetated surfaces is influenced by vegetation structure and vegetation water content (VWC), which varies with meteorological conditions and moisture in the root zone. Radar backscatter observations are used for many vegetation and soil moisture monitoring applications under the assumption that VWC is constant on short timescales. This research aims to understand how backscatter over agricultural canopies changes in response to diurnal differences in VWC due to water stress. A standard water-cloud model and a two-layer water-cloud model for maize were used to simulate the influence of the observed variations in bulk/leaf/stalk VWC and soil moisture on the various contributions to total backscatter at a range of frequencies, polarizations, and incidence angles. The bulk VWC and leaf VWC were found to change up to 30% and 40%, respectively, on a diurnal basis during water stress and may have a significant effect on radar backscatter. Total backscatter time series are presented to illustrate the simulated diurnal difference in backscatter for different radar frequencies, polarizations, and incidence angles. Results show that backscatter is very sensitive to variations in VWC during water stress, particularly at large incidence angles and higher frequencies. The diurnal variation in total backscatter was dominated by variations in leaf water content, with simulated diurnal differences of up to 4 dB in X- through Ku-bands (8.6–35 GHz). This study highlights a potential source of error in current vegetation and soil monitoring applications and provides insights into the potential use for radar to detect variations in VWC due to water stress., Water Management, Civil Engineering and Geosciences

Published

2014

4. Impact of diurnal variation in vegetation water content on radar backscatter from maize during water stress

Author

Van Emmerik, T.H.M. (author), Dunne, S.C. (author), Judge, J. (author), van de Giesen, N.C. (author), Van Emmerik, T.H.M. (author), Dunne, S.C. (author), Judge, J. (author), and van de Giesen, N.C. (author)

Abstract

Microwave backscatter from vegetated surfaces is influenced by vegetation structure and vegetation water content (VWC), which varies with meteorological conditions and moisture in the root zone. Radar backscatter observations are used for many vegetation and soil moisture monitoring applications under the assumption that VWC is constant on short timescales. This research aims to understand how backscatter over agricultural canopies changes in response to diurnal differences in VWC due to water stress. A standard water-cloud model and a two-layer water-cloud model for maize were used to simulate the influence of the observed variations in bulk/leaf/stalk VWC and soil moisture on the various contributions to total backscatter at a range of frequencies, polarizations, and incidence angles. The bulk VWC and leaf VWC were found to change up to 30% and 40%, respectively, on a diurnal basis during water stress and may have a significant effect on radar backscatter. Total backscatter time series are presented to illustrate the simulated diurnal difference in backscatter for different radar frequencies, polarizations, and incidence angles. Results show that backscatter is very sensitive to variations in VWC during water stress, particularly at large incidence angles and higher frequencies. The diurnal variation in total backscatter was dominated by variations in leaf water content, with simulated diurnal differences of up to 4 dB in X- through Ku-bands (8.6–35 GHz). This study highlights a potential source of error in current vegetation and soil monitoring applications and provides insights into the potential use for radar to detect variations in VWC due to water stress., Water Management, Civil Engineering and Geosciences

Published

2014