W. Verhoef scite author profile

Remote sensing of solar-induced chlorophyll fluorescence (SIF) is a rapidly advancing front in terrestrial vegetation science, with emerging capability in space-based methodologies and diverse application prospects. Although remote sensing of SIF -especially from space -is seen as a contemporary new specialty for terrestrial plants, it is founded upon a multi-decadal history of research, applications, and sensor developments in active and passive sensing of chlorophyll fluorescence. Current technical capabilities allow SIF to be measured across a range of biological, spatial, and temporal scales. As an optical signal, SIF may be assessed remotely using high-resolution spectral sensors in tandem with state-of-the-art algorithms to distinguish the emission from reflected and/or scattered ambient light. Because the red to far-red SIF emission is detectable non-invasively, it may be sampled repeatedly to acquire spatio-temporally explicit information about photosynthetic light responses and steady-state behaviour in vegetation.Progress in this field is accelerating with innovative sensor developments, retrieval methods, and modelling advances. This review distills the historical and current developments spanning the last several decades. It highlights SIF heritage and complementarity within the broader field of fluorescence science, the maturation of physiological and radiative transfer modelling, SIF signal retrieval strategies, techniques for field and airborne sensing, advances in satellite-based systems, and applications of these capabilities in evaluation of photosynthesis and stress effects. Progress, challenges, and future directions are considered for this unique avenue of remote sensing.

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Unified Optical-Thermal Four-Stream Radiative Transfer Theory for Homogeneous Vegetation Canopies

Verhoef

Xiao

et al. 2007

IEEE Trans. Geosci. Remote Sensing

339

145

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Third Radiation Transfer Model Intercomparison (RAMI) exercise: Documenting progress in canopy reflectance models

et al. 2007

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[1] The Radiation Transfer Model Intercomparison (RAMI) initiative benchmarks canopy reflectance models under well-controlled experimental conditions. Launched for the first time in 1999, this triennial community exercise encourages the systematic evaluation of canopy reflectance models on a voluntary basis. The first phase of RAMI focused on documenting the spread among radiative transfer (RT) simulations over a small set of primarily 1-D canopies. The second phase expanded the scope to include structurally complex 3-D plant architectures with and without background topography. Here sometimes significant discrepancies were noted which effectively prevented the definition of a reliable ''surrogate truth,'' over heterogeneous vegetation canopies, against which other RT models could then be compared. The present paper documents the outcome of the third phase of RAMI, highlighting both the significant progress that has been made in terms of model agreement since RAMI-2 and the capability of/need for RT models to accurately reproduce local estimates of radiative quantities under conditions that are reminiscent of in situ measurements. Our assessment of the self-consistency and the relative and absolute performance of 3-D Monte Carlo models in RAMI-3 supports their usage in the generation of a ''surrogate truth'' for all RAMI test cases. This development then leads (1) to the presentation of the ''RAMI Online Model Checker'' (ROMC), an open-access web-based interface to evaluate RT models automatically, and (2) to a reassessment of the role, scope, and opportunities of the RAMI project in the future.

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Fluspect-B: A model for leaf fluorescence, reflectance and transmittance spectra

Vilfan

Tol

Muller

et al. 2016

Remote Sensing of Environment

180

116

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A model for chlorophyll fluorescence and photosynthesis at leaf scale

Tol¹,

Verhoef²,

Rosema

2009

Agricultural and Forest Meteorology

172

109

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W. Verhoef

Remote sensing of solar-induced chlorophyll fluorescence (SIF) in vegetation: 50 years of progress

Unified Optical-Thermal Four-Stream Radiative Transfer Theory for Homogeneous Vegetation Canopies

Third Radiation Transfer Model Intercomparison (RAMI) exercise: Documenting progress in canopy reflectance models

Fluspect-B: A model for leaf fluorescence, reflectance and transmittance spectra

A model for chlorophyll fluorescence and photosynthesis at leaf scale

Contact Info

Product

Resources

About

W. Verhoef

Remote sensing of solar-induced chlorophyll fluorescence (SIF) in vegetation: 50 years of progress

Unified Optical-Thermal Four-Stream Radiative Transfer Theory for Homogeneous Vegetation Canopies

Third Radiation Transfer Model Intercomparison (RAMI) exercise: Documenting progress in canopy reflectance models

Fluspect-B: A model for leaf fluorescence, reflectance and transmittance spectra

A model for chlorophyll fluorescence and photosynthesis at leaf scale

Contact Info

Product

Resources

About

Remote sensing of solar-induced chlorophyll fluorescence (SIF) in vegetation: 50 years of progress