Editorial special issue: Advancing foundational sun-induced chlorophyll fluorescence science

[1]  Tomomichi Kato,et al.  Red solar-induced chlorophyll fluorescence as a robust proxy for ecosystem-level photosynthesis in a rice field , 2023, Agricultural and Forest Meteorology.

[2]  P. Zarco-Tejada,et al.  From remotely‐sensed solar‐induced chlorophyll fluorescence to ecosystem structure, function, and service: Part II—Harnessing data , 2023, Global change biology.

[3]  P. Zarco-Tejada,et al.  From remotely sensed solar‐induced chlorophyll fluorescence to ecosystem structure, function, and service: Part I—Harnessing theory , 2023, Global change biology.

[4]  C. Zhang,et al.  The Photosynthetic Response of Spectral Chlorophyll Fluorescence Differs Across Species and Light Environments in a Boreal Forest Ecosystem , 2023, SSRN Electronic Journal.

[5]  C. Frankenberg,et al.  Impact of radiation variations on temporal upscaling of instantaneous Solar-Induced Chlorophyll Fluorescence , 2022, Agricultural and Forest Meteorology.

[6]  Jingfeng Xiao,et al.  Estimation of global GPP from GOME-2 and OCO-2 SIF by considering the dynamic variations of GPP-SIF relationship , 2022, Agricultural and Forest Meteorology.

[7]  L. Guanter,et al.  A precise method unaffected by atmospheric reabsorption for ground-based retrieval of red and far-red sun-induced chlorophyll fluorescence , 2022, Agricultural and Forest Meteorology.

[8]  J. Clevers,et al.  Comparison of a UAV- and an airborne-based system to acquire far-red sun-induced chlorophyll fluorescence measurements over structurally different crops , 2022, Agricultural and Forest Meteorology.

[9]  M. Rossini,et al.  Physiological dynamics dominate the response of canopy far-red solar-induced fluorescence to herbicide treatment , 2022, Agricultural and Forest Meteorology.

[10]  Jingfeng Xiao,et al.  Monitoring drought impacts on crop productivity of the U.S. Midwest with solar-induced fluorescence: GOSIF outperforms GOME-2 SIF and MODIS NDVI, EVI, and NIRv , 2022, Agricultural and Forest Meteorology.

[11]  J. Peñuelas,et al.  Fluorescence ratio and photochemical reflectance index as a proxy for photosynthetic quantum efficiency of photosystem II along a phosphorus gradient , 2022, Agricultural and Forest Meteorology.

[12]  P. Blanken,et al.  Gross primary production (GPP) and red solar induced fluorescence (SIF) respond differently to light and seasonal environmental conditions in a subalpine conifer forest , 2022, Agricultural and Forest Meteorology.

[13]  T. Magney,et al.  The Physiological Basis for Estimating Photosynthesis from Chlorophyll a Fluorescence. , 2022, The New phytologist.

[14]  M. Rossini,et al.  Heatwave breaks down the linearity between sun-induced fluorescence and gross primary production. , 2021, The New phytologist.

[15]  L. Gu,et al.  The roles of photochemical and non-photochemical quenching in regulating photosynthesis depend on the phases of fluctuating light conditions. , 2021, Tree physiology.

[16]  Liangyun Liu,et al.  Modelling the influence of incident radiation on the SIF-based GPP estimation for maize , 2021 .

[17]  F. Maignan,et al.  Chlorophyll a fluorescence illuminates a path connecting plant molecular biology to Earth-system science , 2021, Nature Plants.

[18]  A. Damm,et al.  On the seasonal relation of sun-induced chlorophyll fluorescence and transpiration in a temperate mixed forest , 2021, Agricultural and Forest Meteorology.

[19]  L. Guanter,et al.  Assessing bi-directional effects on the diurnal cycle of measured solar-induced chlorophyll fluorescence in crop canopies , 2020 .

[20]  Zhiqiang Xiao,et al.  Simulating spatially distributed solar-induced chlorophyll fluorescence using a BEPS-SCOPE coupling framework , 2020 .

[21]  Javier Pacheco-Labrador,et al.  Multiple-constraint inversion of SCOPE. Evaluating the potential of GPP and SIF for the retrieval of plant functional traits , 2019 .

[22]  Javier Pacheco-Labrador,et al.  Nitrogen and Phosphorus effect on Sun-Induced Fluorescence and Gross Primary Productivity in Mediterranean Grassland , 2019, Remote. Sens..

[23]  J. Berry,et al.  Canopy structure explains the relationship between photosynthesis and sun-induced chlorophyll fluorescence in crops , 2019, Remote Sensing of Environment.

[24]  W. Verhoef,et al.  Remote sensing of solar-induced chlorophyll fluorescence (SIF) in vegetation: 50 years of progress. , 2019, Remote sensing of environment.

[25]  L. Gu,et al.  Sun-induced Chl fluorescence and its importance for biophysical modeling of photosynthesis based on light reactions. , 2019, The New phytologist.

[26]  P. Blanken,et al.  Mechanistic evidence for tracking the seasonality of photosynthesis with solar-induced fluorescence , 2019, Proceedings of the National Academy of Sciences.

[27]  J. Riggs,et al.  Advancing Terrestrial Ecosystem Science With a Novel Automated Measurement System for Sun‐Induced Chlorophyll Fluorescence for Integration With Eddy Covariance Flux Networks , 2019, Journal of Geophysical Research: Biogeosciences.

[28]  M. Rossini,et al.  Linking photosynthesis and sun-induced fluorescence at sub-daily to seasonal scales , 2018, Remote Sensing of Environment.

[29]  C. Frankenberg,et al.  PhotoSpec: A new instrument to measure spatially distributed red and far-red Solar-Induced Chlorophyll Fluorescence , 2018, Remote Sensing of Environment.

[30]  M. Migliavacca,et al.  Sun-induced fluorescence and gross primary productivity during a heat wave , 2018, Scientific Reports.

[31]  C. Frankenberg,et al.  Overview of Solar-Induced chlorophyll Fluorescence (SIF) from the Orbiting Carbon Observatory-2: Retrieval, cross-mission comparison, and global monitoring for GPP , 2018 .

[32]  Liangyun Liu,et al.  Influence of the canopy BRDF characteristics and illumination conditions on the retrieval of solar-induced chlorophyll fluorescence , 2018 .

[33]  Tiana W. Hammer,et al.  Plant functional traits and canopy structure control the relationship between photosynthetic CO2 uptake and far-red sun-induced fluorescence in a Mediterranean grassland under different nutrient availability. , 2017, The New phytologist.

[34]  J. Moreno,et al.  Evaluating the predictive power of sun-induced chlorophyll fluorescence to estimate net photosynthesis of vegetation canopies: A SCOPE modeling study , 2016 .

[35]  U. Rascher,et al.  Plant chlorophyll fluorescence: active and passive measurements at canopy and leaf scales with different nitrogen treatments , 2015, Journal of experimental botany.

[36]  R. Colombo,et al.  Sun‐induced fluorescence – a new probe of photosynthesis: First maps from the imaging spectrometer HyPlant , 2015, Global change biology.

[37]  J. Moreno,et al.  Global sensitivity analysis of the SCOPE model: What drives simulated canopy-leaving sun-induced fluorescence? , 2015 .

[38]  J. Berry,et al.  Models of fluorescence and photosynthesis for interpreting measurements of solar-induced chlorophyll fluorescence , 2014, Journal of geophysical research. Biogeosciences.

[39]  A. Huete,et al.  Estimation of vegetation photosynthetic capacity from space‐based measurements of chlorophyll fluorescence for terrestrial biosphere models , 2014, Global change biology.

[40]  C. Frankenberg,et al.  Linking chlorophyll a fluorescence to photosynthesis for remote sensing applications: mechanisms and challenges. , 2014, Journal of experimental botany.

[41]  R. Samson,et al.  Upward and downward solar-induced chlorophyll fluorescence yield indices of four tree species as indicators of traffic pollution in Valencia. , 2013, Environmental pollution.

[42]  Philip Lewis,et al.  Retrieval and global assessment of terrestrial chlorophyll fluorescence from GOSAT space measurements , 2012 .

[43]  M. Rossini,et al.  High resolution field spectroscopy measurements for estimating gross ecosystem production in a rice field , 2010 .

[44]  J. Moreno,et al.  Remote sensing of sun‐induced fluorescence to improve modeling of diurnal courses of gross primary production (GPP) , 2010 .

[45]  W. Verhoef,et al.  An integrated model of soil-canopy spectral radiances, photosynthesis, fluorescence, temperature and energy balance , 2009 .

[46]  Luis Alonso,et al.  Remote sensing of solar-induced chlorophyll fluorescence: Review of methods and applications , 2009 .

[47]  R. Colombo,et al.  Leaf level detection of solar induced chlorophyll fluorescence by means of a subnanometer resolution spectroradiometer , 2006 .

[48]  Óscar Pérez-Priego,et al.  Detection of water stress in orchard trees with a high-resolution spectrometer through chlorophyll fluorescence in-filling of the O/sub 2/-A band , 2005, IEEE Transactions on Geoscience and Remote Sensing.

[49]  H. Kautsky,et al.  Neue Versuche zur Kohlensäureassimilation , 1931, Naturwissenschaften.

[50]  Ulrich Schreiber,et al.  Pulse-Amplitude-Modulation (PAM) Fluorometry and Saturation Pulse Method: An Overview , 2004 .

[51]  Pablo J. Zarco-Tejada,et al.  Chlorophyll fluorescence effects on vegetation apparent reflectance: II. laboratory and airborne canopy-level measurements with hyperspectral data. , 2000 .

[52]  J. Briantais,et al.  The relationship between the quantum yield of photosynthetic electron transport and quenching of chlorophyll fluorescence , 1989 .