Measuring the dielectric permittivity of a plant canopy and its response to changes in plant water status: An application of Impulse Time Domain Transmission

Burke, Eleanor J.; Harlow, R. Chawn; Ferré, Ty P. A.

doi:10.1007/s11104-004-0303-7

Cited by 13 publications

(9 citation statements)

References 31 publications

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“…5, the oven-dry experiments showed that the intrinsic water of organics, for example, the leaves or watermelon peel, accounts for 95 percent of the total mass of organics. The K a of a plant is a mixture of free water, bound water, and plant dry matter (Burke et al, 2005). Therefore, before being mixed with any water, the K a of leaves or watermelon peel is much higher than paper and plastic.…”

Section: Resultsmentioning

confidence: 99%

Time Domain Reflectometry for Water Content Measurement of Municipal Solid Waste

Chen

et al. 2012

Environmental Engineering Science

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Water content measurement of municipal solid waste (MSW) is critical to water balance analysis of landfill, leachate collection and recirculation, and acceleration of MSW degradation. Time domain reflectometry (TDR) is commonly applied to soils for the measurement of water content. Application of TDR methods for moisture measurement in MSW is difficult, because MSW is a heterogeneous and highly conductive material. This study investigated the application of TDR surface reflection method for the determination of apparent dielectric constant and water content of MSW. A series of experiments were conducted to study the dielectric properties of MSW and its main components such as paper, plastic, and organics. Results indicate that the effect of waste material type seems to be negligible on the measurement of water content. TDR technique can effectively measure the intrinsic water of organics in the absence of significant bound water effects. Results of dielectric constant by surface reflection method gave similar accuracy as the conventional travel time analysis for waste materials with low electrical conductivities. In addition, surface reflection method provides higher accuracy for waste materials with high electrical conductivities than travel time analysis. This research provides experimental basis for the use of TDR surface reflection method in landfills.

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Section: Resultsmentioning

confidence: 99%

Time Domain Reflectometry for Water Content Measurement of Municipal Solid Waste

Chen

et al. 2012

Environmental Engineering Science

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“…Since the only variation in the plant system throughout time is loss of water due to evaporation and that our measurement technique is especially sensitive to water (due to its high dielectric constant), we can assume that the variations in light/dark electrical parameters are due to losing water. The effects of water loss on electrical properties are a well-known effect [34] As discussed in the introduction, admittance signals can also be represented in the form of a vector on a complex plane in order to facilitate its analysis. It is formed by two components, Y G jB = + : susceptance ( B C ω = ) and conductance ( 1 G R =…”

Section: Resultsmentioning

confidence: 99%

“…• He et al developed a portable bioelectrical impedance spectroscopy system able to detect tomato plant water status [30]. • Burke et al showed that Impulse Time Domain Transmission (an extension of Time Domain Reflectometry, an electromagnetic technique used for measuring the dielectric constant of soils, which is related to soil water content) is very sensitive to small changes in plant canopy water status [34].…”

Section: Introductionmentioning

confidence: 99%

Using an Off-the-Shelf Lock-In Detector for Admittance Spectroscopy in the Study of Plants

Monteiro¹,

Stallinga²

2020

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We report on the development of an electrical characterization admittance spectroscopy equipment and method based on an off-the-shelf lock-in detector that is cheap and yet highly sensitive. It is concluded that a contacted constant-pressure electrode configuration is preferable. It was further determined that the temperature does not have great impact in the measured values, but relative humidity of air can be important, especially in the constant-gap electrode configuration. In-situ measurements are difficult since the coupling of the plant with the environment is of high importance. Another aspect is the cables; they are important in that they have to be terminated by their characteristic impedance (50 Ω in our case) to avoid reflections that introduce artificial attenuation and phase shifts in the signal. We introduce a fingerprint plot type to be able to distinguish between various plants and other specimens, and can actually detect the aqueous state of a plant.

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“…After application of water to the trees, both water potential and dielectric constant in the xylem increased. Burke et al (2005) used lab measurements of leaf dielectric constants to show the relation between relative water content and the dielectric constant. Dobson et al (1991) found that dielectric constant of loblolly pine trunks were partially correlated to canopy layer physiological observations, such as transpiration, stomatal conductance and xylem water potential.…”

Section: Relation Between Plant Dynamics and Dielectric Prop-ertiesmentioning

confidence: 99%

Water stress detection using radar

Emmerik¹

2017

Preprint

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Measuring the dielectric permittivity of a plant canopy and its response to changes in plant water status: An application of Impulse Time Domain Transmission

Cited by 13 publications

References 31 publications

Time Domain Reflectometry for Water Content Measurement of Municipal Solid Waste

Time Domain Reflectometry for Water Content Measurement of Municipal Solid Waste

Using an Off-the-Shelf Lock-In Detector for Admittance Spectroscopy in the Study of Plants

Water stress detection using radar

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