Academic literature on the topic 'Dehyration'

Abstract. We report the first high-precision measurements of δ18O and Δ17O at high southern latitudes that can resolve changes in the isotopic composition of water vapor in the lowermost stratosphere and upper troposphere. A strong increase of δ18O with decreasing mixing ratio above the tropopause is found. Since also the water vapor mixing ratio decreases above the tropopause, the isotope data can be explained by mixing of relatively moist air from the tropopause with dry stratospheric air. However, the nature of dehyration process that produced this dry stratospheric, e.g., fast transport from the extratropical tropopause or mixing with air from the dehydrated polar vortex, cannot be clearly identified. The magnitude of the Δ17O-anomaly (departure from mass-dependent fractionation (MDF)) was below 2 for each datapoint, and the mean is consistent with a zero anomaly in lower level stratospheric water vapor. Various transport histories for the stratospheric data are discussed based on the mixing ratio and isotope data.

Three perennial tropical Panicum species were grown under ambient and elevated (900 ppm) carbon dioxide concentrations in especially designed microclimate chambers. The study aimed to investigate the influence of high carbon dioxide concentrations on morphology/anatomy with physiological change among three closely related species possessing distinctly different photosynthetic pathways. The anatomy of the leaf was investigated using light microscopy (LM), transmission electron microscopy (TEM), and graphics image analysis. A suitable schedule for fixation, dehydration and embedding of leaf specimens for both forms of microscopy was developed. The anatomy of the species investigated did not change qualitatively, but there were detectable changes in leaf thickness and tissue proportions of the epidermis, mesophyll and thickened tissues (sclerenchyma, bundle sheath, vascular elements) that differed with species. This study is also relevant to the investigation of the evolution of C4, although species, and the progression involved in plants with characteristics intermediate between those of C3 and C4 species. These intermediate species have been mainly characterized by CO2 exchange and biochemical analysis, but they also display anatomical characteristics in between those of C3 and C4 plants. The evolutionary progression of the C3 to C4 species remains unsolved, although current studies indicate that the evolutionary step was from the C3 plant to the C4. Thus the intermediate C3/C4 plants may not be intermediate in an evolutionary sense and they could be seen as a simple hybridization between a C3 plant and C4 plant. In most of the parameters measured the C3/C4 P. decipiens resembled either the C3 P. tricanthum or the C4 P. antidotale. It may therefore be likened to a physiological chimera rather than to a true intermediate form
Doctor of Philosophy (PhD)

Three perennial tropical Panicum species were grown under ambient and elevated (900 ppm) carbon dioxide concentrations in especially designed microclimate chambers. The study aimed to investigate the influence of high carbon dioxide concentrations on morphology/anatomy with physiological change among three closely related species possessing distinctly different photosynthetic pathways. The anatomy of the leaf was investigated using light microscopy (LM), transmission electron microscopy (TEM), and graphics image analysis. A suitable schedule for fixation, dehydration and embedding of leaf specimens for both forms of microscopy was developed. The anatomy of the species investigated did not change qualitatively, but there were detectable changes in leaf thickness and tissue proportions of the epidermis, mesophyll and thickened tissues (sclerenchyma, bundle sheath, vascular elements) that differed with species. This study is also relevant to the investigation of the evolution of C4, although species, and the progression involved in plants with characteristics intermediate between those of C3 and C4 species. These intermediate species have been mainly characterized by CO2 exchange and biochemical analysis, but they also display anatomical characteristics in between those of C3 and C4 plants. The evolutionary progression of the C3 to C4 species remains unsolved, although current studies indicate that the evolutionary step was from the C3 plant to the C4. Thus the intermediate C3/C4 plants may not be intermediate in an evolutionary sense and they could be seen as a simple hybridization between a C3 plant and C4 plant. In most of the parameters measured the C3/C4 P. decipiens resembled either the C3 P. tricanthum or the C4 P. antidotale. It may therefore be likened to a physiological chimera rather than to a true intermediate form