![Sample our Environment & Agriculture journals, sign in here to start your access, latest two full volumes FREE to you for 14 days]({"type":"image" , "src" : "/sda/5934/TOC-Subject-Sample-2021-Environment-Agriculture.jpg"})
Abstract
Diffusion theory predicts that, except in the lower part of the daylight range, carbon dioxide supply will always be limiting for photosynthesis in a unistratose leaf. We have used chlorophyll fluorometry to survey the photosynthetic responses of numerous bryophytes to a range of light intensities employing the ‘light curve’ approach. Initially, as light intensity is increased in a stepwise manner, electron transport rate (ETR) in bryophytes follows a saturation curve closely fitted by a negative exponential function, y = A(1 – e–kx ), where y = ETR, x = light intensity (or photosynthetic photon flux density), A is the asymptote (ETR at infinitely high light intensity), k is a rate constant and e is the base of natural logarithms. The initial slope of the response curve, Ak, approximates maximum quantum efficiency (Fv/Fm) which is measured on dark-adapted plant material. However, at higher intensities ETR frequently veers away from the saturation curve owing to the onset of either photoinhibition or the dissipation of the excitation energy by a photoprotective mechanism, probably involving reduction of O2. In the latter case, the measurement of ETR significantly overestimates the rate of photosynthetic carbon fixation. We describe a simple approach that enables these instances of photoprotection and photoinhibition to be identified and discuss the wider significance of the results to the ecology of individual species.
Acknowledgements
We are grateful to the referees for their suggested improvements to earlier drafts of the manuscript.
Taxonomic Additions and Changes: Nil.