Your search keyword '"Water band index"' showing total 2 results

1. Response times of remote sensing measured sun-induced chlorophyll fluorescence, surface temperature and vegetation indices to evolving soil water limitation in a crop canopy

Author

Damm, Alexander, Cogliati, S, Colombo, R, Fritsche, L, Genangeli, A, Genesio, L, Hanus, J, Peressotti, A, Rademske, P, Rascher, Uwe, Schuettemeyer, D, Siegmann, B, Sturm, J, Miglietta, F, Damm, A, Cogliati, S, Colombo, R, Fritsche, L, Genangeli, A, Genesio, L, Hanus, J, Peressotti, A, Rademske, P, Rascher, U, Schuettemeyer, D, Siegmann, B, Sturm, J, Miglietta, F, University of Zurich, and Damm, Alexander

Subjects

Photochemical reflectance index, FIS/06 - FISICA PER IL SISTEMA TERRA E PER IL MEZZO CIRCUMTERRESTRE, MERIS terrestrial chlorophyll index, 1903 Computers in Earth Sciences, GEO/12 - OCEANOGRAFIA E FISICA DELL'ATMOSFERA, Soil Science, Geology, Multi-sensor remote sensing, 10122 Institute of Geography, Agricultural ecosystems, Agricultural ecosystem, ddc:550, Soil water limitation, Water band index, 910 Geography & travel, Computers in Earth Sciences, 1111 Soil Science, 1907 Geology

Abstract

Vegetation responds at varying temporal scales to changing soil water availability. These process dynamics complicate assessments of plant-water relations but also offer various access points to advance understanding of vegetation responses to environmental change. Remote sensing (RS) provides large capacity to quantify sensitive and robust information of vegetation responses and underlying abiotic change driver across observational scales. Retrieved RS based vegetation parameters are often sensitive to various environmental and plant specific factors in addition to the targeted plant response. Further, individual plant responses to water limitation act at different temporal and spatial scales, while RS sampling schemes are often not optimized to assess these dynamics. The combination of these aspects complicates the interpretation of RS parameter when assessing plant-water relations. We consequently aim to advance insight on the sensitivity of physiological, biochemical and structural RS parameter for plant adaptation in response to emerging soil water limitation. We made a field experiment in maize in Tuscany (Central Italy), while irrigation was stopped in some areas of the drip-irrigated field. Within a period of two weeks, we measured the hydraulic and physiological state of maize plants in situ and complemented these detailed measurements with extensive airborne observations (e.g. sun-induced chlorophyll fluorescence (SIF), vegetation indices sensitive for photosynthesis, pigment and water content, land surface temperature). We observe a double response of far-red SIF with a short-term increase after manifestation of soil water limitation and a decrease afterwards. We identify different response times of RS parameter representing different plant adaptation mechanisms ranging from short term responses (e.g. stomatal conductance, photosynthesis) to medium term changes (e.g. pigment decomposition, changing leaf water content). Our study demonstrates complementarity of common and new RS parameter to mechanistically assess the complex cascade of functional, biochemical and structural plant responses to evolving soil water limitation.

Published

2022

2. Monitoring drought effects on vegetation water content and fluxes in chaparral with the 970 nm water band index

Author

Claudio, Helen C., Cheng, Yufu, Fuentes, David A., Gamon, John A., Luo, Hongyan, Oechel, Walter, Qiu, Hong-Lie, Rahman, Abdullah F., and Sims, Daniel A.

Subjects

*DROUGHTS, *REFLECTANCE, *SPECTRAL reflectance, *SURFACE tension

Abstract

Abstract: The goal of this study was to explore the utility of the 970 nm water band index (WBI) in estimating evapotranspiration and vegetation water status for a semiarid shrubland ecosystem. Between 2001 and 2003, spectral reflectance coupled with CO2 and water flux data were collected at Sky Oaks Biological Field Station, a chaparral-dominated ecosystem in southern California, and one of the sites within the SpecNet network. The reflectance data were collected either by walking along a 100 m transect or by using a semi-automated tram system installed later at the site along the same 100 m transect. CO2 and water flux data were gathered with an eddy covariance flux tower adjacent to the tram system. The 970 nm WBI and normalized difference vegetation index (NDVI) were derived from the spectral reflectance. The two indices were expressed both as points approximately a meter apart along the transect and as whole-transect averages, where all of the reflectance values along the transect were averaged together, simulating a large pixel. This study encompassed a wet year with normal precipitation (2001), a 100-year record drought (2002), and a recovery year (2003), allowing for comparison over time and between precipitation regimes. Species-specific responses to wet and dry periods were evident in the reflectance spectra, providing a basis for separating species based on their optical properties. The WBI was significantly correlated with the NDVI revealing a strong link between canopy water content and green canopy structure; however this relationship varied with species and water status, providing evidence for the independence of these two optical indices. The WBI was also strongly linked to surface–atmosphere fluxes, explaining 49% of the variance in the water vapor flux, and 24% of the carbon dioxide fluxes. These results suggest that WBI or other similar water status indices may be useful variables in modeling CO2 and water fluxes when combined with other physiological, environmental, and atmospheric factors. [Copyright &y& Elsevier]

Published

2006