Interpreting canopy development and physiology using a European phenology camera network at flux sites

Research output: Contribution to journalResearch articleContributedpeer-review

Contributors

  • L. Wingate - , INRAE - National Institute of Agricultural Research (Author)
  • J. Ogeé - , INRAE - National Institute of Agricultural Research (Author)
  • E. Cremonese - , Environmental Protection Agency of Aosta Valley (Author)
  • G. Filippa - , Environmental Protection Agency of Aosta Valley (Author)
  • T. Mizunuma - , University of Edinburgh (Author)
  • M. Migliavacca - , Max Planck Institute for Biogeochemistry (Author)
  • C. Moisy - , INRAE - National Institute of Agricultural Research (Author)
  • M. Wilkinson - , Forestry Commission England (Author)
  • C. Moureaux - , University of Liege (Author)
  • G. Wohlfahrt - , University of Innsbruck, EURAC Research (Author)
  • A. Hammerle - , University of Innsbruck (Author)
  • L. Hörtnagl - , University of Innsbruck, ETH Zurich (Author)
  • C. Gimeno - , Mediterranean Center for Environmental Studies (CEAM) (Author)
  • A. Porcar-Castell - , University of Helsinki (Author)
  • M. Galvagno - , Environmental Protection Agency of Aosta Valley (Author)
  • T. Nakaji - , Hokkaido University (Author)
  • J. Morison - , Forestry Commission England (Author)
  • O. Kolle - , Max Planck Institute for Biogeochemistry (Author)
  • A. Knohl - , University of Göttingen (Author)
  • W. Kutsch - , Johann Heinrich von Thunen Institute (Author)
  • P. Kolari - , University of Helsinki (Author)
  • E. Nikinmaa - , University of Helsinki (Author)
  • A. Ibrom - , Technical University of Denmark (Author)
  • B. Gielen - , University of Antwerp (Author)
  • W. Eugster - , ETH Zurich (Author)
  • M. Balzarolo - , University of Antwerp, Tuscia University (Author)
  • D. Papale - , Tuscia University (Author)
  • K. Klumpp - , UREP (Author)
  • B. Köstner - , Chair of Meteorology (Author)
  • T. Grünwald - , Chair of Meteorology (Author)
  • R. Joffre - , French National Centre for Scientific Research (CNRS) (Author)
  • J. M. Ourcival - , French National Centre for Scientific Research (CNRS) (Author)
  • M. Hellstrom - , Lund University (Author)
  • A. Lindroth - , Lund University (Author)
  • C. George - , Centre for Ecology and Hydrology (Author)
  • B. Longdoz - , INRAE - National Institute of Agricultural Research (Author)
  • B. Genty - , French Alternative Energies and Atomic Energy Commission (CEA), French National Centre for Scientific Research (CNRS) (Author)
  • J. Levula - , University of Helsinki (Author)
  • B. Heinesch - , University of Liege (Author)
  • M. Sprintsin - , Keren Kayemeth LeIsrael – Jewish National Fund (KKL-JNF) (Author)
  • D. Yakir - , Weizmann Institute of Science (Author)
  • T. Manise - , University of Liege (Author)
  • D. Guyon - , INRAE - National Institute of Agricultural Research (Author)
  • H. Ahrends - , ETH Zurich, University of Cologne (Author)
  • A. Plaza-Aguilar - , University of Cambridge (Author)
  • J. H. Guan - , Max Planck Institute for Biogeochemistry (Author)
  • J. Grace - , University of Edinburgh (Author)

Abstract

Plant phenological development is orchestrated through subtle changes in photoperiod, temperature, soil moisture and nutrient availability. Presently, the exact timing of plant development stages and their response to climate and management practices are crudely represented in land surface models. As visual observations of phenology are laborious, there is a need to supplement long-term observations with automated techniques such as those provided by digital repeat photography at high temporal and spatial resolution. We present the first synthesis from a growing observational network of digital cameras installed on towers across Europe above deciduous and evergreen forests, grasslands and croplands, where vegetation and atmosphere CO2 fluxes are measured continuously. Using colour indices from digital images and using piecewise regression analysis of time series, we explored whether key changes in canopy phenology could be detected automatically across different land use types in the network. The piecewise regression approach could capture the start and end of the growing season, in addition to identifying striking changes in colour signals caused by flowering and management practices such as mowing. Exploring the dates of green-up and senescence of deciduous forests extracted by the piecewise regression approach against dates estimated from visual observations, we found that these phenological events could be detected adequately (RMSE < 8 and 11 days for leaf out and leaf fall, respectively). We also investigated whether the seasonal patterns of red, green and blue colour fractions derived from digital images could be modelled mechanistically using the PROSAIL model parameterised with information of seasonal changes in canopy leaf area and leaf chlorophyll and carotenoid concentrations. From a model sensitivity analysis we found that variations in colour fractions, and in particular the late spring 'green hump' observed repeatedly in deciduous broadleaf canopies across the network, are essentially dominated by changes in the respective pigment concentrations. Using the model we were able to explain why this spring maximum in green signal is often observed out of phase with the maximum period of canopy photosynthesis in ecosystems across Europe. Coupling such quasi-continuous digital records of canopy colours with co-located CO2 flux measurements will improve our understanding of how changes in growing season length are likely to shape the capacity of European ecosystems to sequester CO2 in the future.

Details

Original languageEnglish
Pages (from-to)5995-6015
Number of pages21
JournalBiogeosciences
Volume12
Issue number20
Publication statusPublished - 21 Oct 2015
Peer-reviewedYes

External IDs

Scopus 84945348954
ORCID /0000-0003-2263-0073/work/163766014
ORCID /0000-0002-0839-8020/work/166289378

Keywords

Keywords

  • Fluxnet, plant physiology, camera observation