Abstract
Tropospheric concentrations of phytotoxic ozone (O3) have undergone a great increase from preindustrial 10–15 ppbv to a present-day concentration of 35–40 ppbv in large parts of the industrialised world due to increased emissions of O3 precursors including NOx, CO, CH4 and volatile organic compounds. The rate of increase in O3 concentration ranges between 1 ppbv per decade in remote locations of the Southern hemisphere and 5 ppbv per decade in the Northern hemisphere, where largest sources of O3 precursors are located. Molecules of O3 penetrating into the leaves through the stomatal apertures trigger the formation of reactive oxygen species, leading thus to the damage of the photosynthetic apparatus. Accordingly, it is assumed, that O3 increase reduces the terrestrial carbon uptake relative to the preindustrial era. Here we summarise the results of previous manipulative experiments in laboratory growth cabinets, field open-top chambers and free-air systems together with O3 flux measurements under natural growth conditions. In particular, we focus on leaf-level physiological responses in trees, variability in stomatal O3 flux and changes in carbon fluxes and biomass production in forest stands. As the results reported in the literature are highly variable, ranging from negligible to severe declines in photosynthetic carbon uptake, we also discuss the possible interactions of O3 with other environmental factors including solar radiation, drought, temperature and nitrogen deposition. Those factors were found to have great potential to modulate stomata openness and O3 fluxes.
Highlights
Changes in O3 ConcentrationConcentrations of O3 ([O3]) have been increasing since the preindustrial era due to an increase of its precursors [1]
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Plant species vary in their sensitivity to [O3], and it seems that genetically based detoxification processes [6] are significant and certainly sufficient to protect plants against any harmful effect of low pre-industrial [O3]
Summary
Concentrations of O3 ([O3]) have been increasing since the preindustrial era due to an increase of its precursors [1]. Plant responses to pollutant levels may well be different when the environmental variables are changed, and extrapolation to present-day ambient conditions may be unwise. Another issue is the non-uniform distribution of gas within the chamber. The environment inside the OTC moreor-less follows the outside environment and plants experience almost natural photon irradiance, photoperiods and seasonality. They have been used successfully in many outdoor settings: for field crops [52], for trees [53] and for natural ecosystems [54]. Researchers have been able to use OTCs in new and imaginative ways, for example, to investigate the important interactions of O3 pollution with nitrogen supply [55], to investigate competition between species in different O3 scenarios [56,57] and to study the impact of O3 on root growth and development [58]
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