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Implications of improved representations of plant respiration in a changing climate

Author

Listed:
  • Chris Huntingford

    (Centre for Ecology and Hydrology)

  • Owen K. Atkin

    (The Australian National University
    The Australian National University)

  • Alberto Martinez-de la Torre

    (Centre for Ecology and Hydrology)

  • Lina M. Mercado

    (Centre for Ecology and Hydrology
    University of Exeter)

  • Mary A. Heskel

    (Marine Biological Laboratory)

  • Anna B. Harper

    (University of Exeter)

  • Keith J. Bloomfield

    (The Australian National University)

  • Odhran S. O’Sullivan

    (The Australian National University)

  • Peter B. Reich

    (University of Minnesota
    Western Sydney University)

  • Kirk R. Wythers

    (University of Minnesota)

  • Ethan E. Butler

    (University of Minnesota)

  • Ming Chen

    (University of Minnesota)

  • Kevin L. Griffin

    (Lamont-Doherty Earth Observatory, Columbia University)

  • Patrick Meir

    (The Australian National University
    University of Edinburgh)

  • Mark G. Tjoelker

    (Western Sydney University)

  • Matthew H. Turnbull

    (University of Canterbury)

  • Stephen Sitch

    (University of Exeter)

  • Andy Wiltshire

    (Met Office)

  • Yadvinder Malhi

    (Oxford University Centre for the Environment, University of Oxford)

Abstract

Land-atmosphere exchanges influence atmospheric CO2. Emphasis has been on describing photosynthetic CO2 uptake, but less on respiration losses. New global datasets describe upper canopy dark respiration (R d) and temperature dependencies. This allows characterisation of baseline R d, instantaneous temperature responses and longer-term thermal acclimation effects. Here we show the global implications of these parameterisations with a global gridded land model. This model aggregates R d to whole-plant respiration R p, driven with meteorological forcings spanning uncertainty across climate change models. For pre-industrial estimates, new baseline R d increases R p and especially in the tropics. Compared to new baseline, revised instantaneous response decreases R p for mid-latitudes, while acclimation lowers this for the tropics with increases elsewhere. Under global warming, new R d estimates amplify modelled respiration increases, although partially lowered by acclimation. Future measurements will refine how R d aggregates to whole-plant respiration. Our analysis suggests R p could be around 30% higher than existing estimates.

Suggested Citation

  • Chris Huntingford & Owen K. Atkin & Alberto Martinez-de la Torre & Lina M. Mercado & Mary A. Heskel & Anna B. Harper & Keith J. Bloomfield & Odhran S. O’Sullivan & Peter B. Reich & Kirk R. Wythers & E, 2017. "Implications of improved representations of plant respiration in a changing climate," Nature Communications, Nature, vol. 8(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:8:y:2017:i:1:d:10.1038_s41467-017-01774-z
    DOI: 10.1038/s41467-017-01774-z
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    Cited by:

    1. Jong Kyu Lee & Myeong Ja Kwak & Sang Hee Park & Han Dong Kim & Yea Ji Lim & Su Gyeong Jeong & Yun Soo Choi & Su Young Woo, 2021. "Ozone Response of Leaf Physiological and Stomatal Characteristics in Brassica juncea L. at Supraoptimal Temperatures," Land, MDPI, vol. 10(4), pages 1-22, April.
    2. Bhatia, Shashi Kant & Bhatia, Ravi Kant & Jeon, Jong-Min & Kumar, Gopalakrishnan & Yang, Yung-Hun, 2019. "Carbon dioxide capture and bioenergy production using biological system – A review," Renewable and Sustainable Energy Reviews, Elsevier, vol. 110(C), pages 143-158.
    3. Dan Bruhn & Freya Newman & Mathilda Hancock & Peter Povlsen & Martijn Slot & Stephen Sitch & John Drake & Graham P. Weedon & Douglas B. Clark & Majken Pagter & Richard J. Ellis & Mark G. Tjoelker & Ke, 2022. "Nocturnal plant respiration is under strong non-temperature control," Nature Communications, Nature, vol. 13(1), pages 1-10, December.

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