Vertical profile of photosynthetic light response within rice canopy

Measured leaf photosynthetic light response (PLR) curves at different positions were fitted by non-rectangular hyperbola (NRH) equation to characterize vertical profile of parameters in NRH equation, namely maximum net photosynthetic rate P nmax , initial quantum yield of assimilation φ , dark respi...

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Bibliographic Details
Published in:International journal of biometeorology 2020-10, Vol.64 (10), p.1699-1708
Main Authors: Lv, Yuping, Xu, Junzeng, Liu, Xiaoyin, Wang, Haiyu
Format: Article
Language:English
Subjects:
Animal Physiology
Biological and Medical Physics
Biophysics
Canopies
Convexity
Earth and Environmental Science
Environment
Environmental Health
Estimation
Herbivores
Hyperbolas
Jointing
Leaves
Light effects
Meteorology
Original Paper
Parameter estimation
Photosynthesis
Plant Physiology
Position measurement
Rice
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Summary:Measured leaf photosynthetic light response (PLR) curves at different positions were fitted by non-rectangular hyperbola (NRH) equation to characterize vertical profile of parameters in NRH equation, namely maximum net photosynthetic rate P nmax , initial quantum yield of assimilation φ , dark respiration rate R d , and convexity of the curve k , at both jointing and heading stages within rice canopy. And leaf-position-specific and canopy average NRH equations were constructed respectively based on measured PLR curves at each specific leaf position and all measured PLR curves within rice canopy. The results showed that the P nmax , φ , and R d reached the maximum at the top second leaf and then decreased at jointing stage and decreased in downward leaves at heading stage. The k increased with lowering leaf position at both stages. The leaf-position-specific NRH equation performed well in estimating net photosynthetic rate P n for all leaves at different positions and stages, while the canopy average NRH equation underestimated leaf P n at upper canopy and overestimated P n at lower canopy. The top fourth leaf was suitable for estimating photosynthetic parameters at canopy scale, as the P nmax , φ , R d , and k of the top fourth leaf were near to these parameters of rice canopy, and the canopy average NRH equation performed well in estimating leaf P n for the top fourth leaf. The results will provide basic information for upscaling leaf photosynthesis to canopy scale.
ISSN:0020-7128
1432-1254
DOI:10.1007/s00484-020-01950-9