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Climatology. --- Pollution atmosphérique --- Carbon dioxide cycle --- Ecophysiology --- Ecosystems --- Mineral balance --- Nitrogen cycle --- Periodic variations --- Photosynthesis --- Plants --- Primary biological productivity --- Solar radiation --- Temperature --- Water balance --- Water cycle
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This textbook on the physiology and ecology of seaweed deals principally with the physical, chemical, and biological factors that affect growth and distribution. The authors lay stress on the interplay between environment and organism throughout. The topics examined include the way in which seaweeds are influenced by environmental factors such as light, temperature and water motion; the way they interact with each other and with marine animals; the way seaweeds develop from spores to mature plants; and the ways in which man can apply knowledge of these aspects of seaweed biology to the cultivation of commercially useful species.
Marine algae --- Ecophysiology. --- ALG Algae --- ecology --- marine Algae --- physiology --- WATER --- MOTION --- SALINITY --- TEMPERATURE --- LIGHT --- PHOTOSYNTHESIS --- PHYSIOLOGY --- SEAWEEDS --- MARICULTURE --- MORPHOGENESIS --- SEASHORES --- COMMUNITIES --- POLLUTION --- CARBON DIOXIDE CYCLE --- ECOLOGY
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SPORULATION --- ANTIMETABOLITES --- ACTINOMYCIN --- DEHYDROGENASES --- HISTOCHEMISTRY --- AUTORADIOGRAPHY --- SUCROSE --- IN VIVO ANALYSIS --- IN VITRO ANALYSIS --- GIBBERELLINS --- GROWTH REGULATORS --- PLANT HORMONES --- CARBON DIOXIDE CYCLE --- CHLOROPLASTS --- NUCLEIC ACIDS --- BUDS --- PROTEIN METABOLISM --- METABOLIC INHIBITORS --- FLOWERING --- PLANT METABOLISM --- MITOSIS --- MERISTEMS --- APICAL DOMINANCE --- VERNALISATION --- CHLOROPHYLLS --- METABOLISM --- NUCLEIC ACIDS --- SPORULATION --- ANTIMETABOLITES --- ACTINOMYCIN --- DEHYDROGENASES --- HISTOCHEMISTRY --- AUTORADIOGRAPHY --- SUCROSE --- IN VIVO ANALYSIS --- IN VITRO ANALYSIS --- GIBBERELLINS --- GROWTH REGULATORS --- PLANT HORMONES --- CARBON DIOXIDE CYCLE --- CHLOROPLASTS --- NUCLEIC ACIDS --- BUDS --- PROTEIN METABOLISM --- METABOLIC INHIBITORS --- FLOWERING --- PLANT METABOLISM --- MITOSIS --- MERISTEMS --- APICAL DOMINANCE --- VERNALISATION --- CHLOROPHYLLS --- METABOLISM --- NUCLEIC ACIDS
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This Special Issue is a compilation of the recent advances in thermal fluid engineering related to supercritical CO2 power cycle development. The supercritical CO2 power cycle is considered to be one of the most promising power cycles for distributed power generation, waste heat recovery, and a topping cycle of coal, nuclear, and solar thermal heat sources. While the cycle benefits from dramatic changes in CO2 thermodynamic properties near the critical point, design, and analysis of the power cycle and its major components also face certain challenges due to the strong real gas effect and extreme operating conditions. This Special Issue will present a series of recent research results in heat transfer and fluid flow analyses and experimentation so that the accumulated knowledge can accelerate the development of this exciting future power cycle technology.
History of engineering & technology --- emergency diesel generator --- supercritical carbon dioxide cycle --- waste heat recovery system --- bottoming cycle --- re-compression Brayton cycle --- carbon dioxide --- supercritical --- thermodynamic --- exergy --- cycle simulation --- design point analysis --- radial-inflow turbine --- supercritical carbon dioxide --- air --- rotor solidity --- aerodynamic performance --- centrifugal compressor --- aerodynamic optimization design --- numerical simulation --- radial turbine --- utility-scale --- turbomachinery design --- NET Power --- supercritical CO2 --- heat exchanger --- flow analysis --- thermal stress analysis --- LCoE --- CSP --- concentrated-solar power --- axial turbine design --- micro-scale turbomachinery design --- emergency diesel generator --- supercritical carbon dioxide cycle --- waste heat recovery system --- bottoming cycle --- re-compression Brayton cycle --- carbon dioxide --- supercritical --- thermodynamic --- exergy --- cycle simulation --- design point analysis --- radial-inflow turbine --- supercritical carbon dioxide --- air --- rotor solidity --- aerodynamic performance --- centrifugal compressor --- aerodynamic optimization design --- numerical simulation --- radial turbine --- utility-scale --- turbomachinery design --- NET Power --- supercritical CO2 --- heat exchanger --- flow analysis --- thermal stress analysis --- LCoE --- CSP --- concentrated-solar power --- axial turbine design --- micro-scale turbomachinery design
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This Special Issue is a compilation of the recent advances in thermal fluid engineering related to supercritical CO2 power cycle development. The supercritical CO2 power cycle is considered to be one of the most promising power cycles for distributed power generation, waste heat recovery, and a topping cycle of coal, nuclear, and solar thermal heat sources. While the cycle benefits from dramatic changes in CO2 thermodynamic properties near the critical point, design, and analysis of the power cycle and its major components also face certain challenges due to the strong real gas effect and extreme operating conditions. This Special Issue will present a series of recent research results in heat transfer and fluid flow analyses and experimentation so that the accumulated knowledge can accelerate the development of this exciting future power cycle technology.
History of engineering & technology --- emergency diesel generator --- supercritical carbon dioxide cycle --- waste heat recovery system --- bottoming cycle --- re-compression Brayton cycle --- carbon dioxide --- supercritical --- thermodynamic --- exergy --- cycle simulation --- design point analysis --- radial-inflow turbine --- supercritical carbon dioxide --- air --- rotor solidity --- aerodynamic performance --- centrifugal compressor --- aerodynamic optimization design --- numerical simulation --- radial turbine --- utility-scale --- turbomachinery design --- NET Power --- supercritical CO2 --- heat exchanger --- flow analysis --- thermal stress analysis --- LCoE --- CSP --- concentrated-solar power --- axial turbine design --- micro-scale turbomachinery design --- n/a
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This Special Issue is a compilation of the recent advances in thermal fluid engineering related to supercritical CO2 power cycle development. The supercritical CO2 power cycle is considered to be one of the most promising power cycles for distributed power generation, waste heat recovery, and a topping cycle of coal, nuclear, and solar thermal heat sources. While the cycle benefits from dramatic changes in CO2 thermodynamic properties near the critical point, design, and analysis of the power cycle and its major components also face certain challenges due to the strong real gas effect and extreme operating conditions. This Special Issue will present a series of recent research results in heat transfer and fluid flow analyses and experimentation so that the accumulated knowledge can accelerate the development of this exciting future power cycle technology.
emergency diesel generator --- supercritical carbon dioxide cycle --- waste heat recovery system --- bottoming cycle --- re-compression Brayton cycle --- carbon dioxide --- supercritical --- thermodynamic --- exergy --- cycle simulation --- design point analysis --- radial-inflow turbine --- supercritical carbon dioxide --- air --- rotor solidity --- aerodynamic performance --- centrifugal compressor --- aerodynamic optimization design --- numerical simulation --- radial turbine --- utility-scale --- turbomachinery design --- NET Power --- supercritical CO2 --- heat exchanger --- flow analysis --- thermal stress analysis --- LCoE --- CSP --- concentrated-solar power --- axial turbine design --- micro-scale turbomachinery design --- n/a
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Plants --- Nutrition --- Metabolism --- 581.13 --- Plant nutrition --- Plant physiology --- Plant metabolism --- Assimilation. Nutrition. Reserves. Secretions. Metabolism --- Metabolism. --- Nutrition. --- Effect of anaerobiosis on --- 581.13 Assimilation. Nutrition. Reserves. Secretions. Metabolism --- Plantes --- Alimentation --- Microorganisms. --- Mineral metabolism. --- Energy Metabolism. --- Fermentation --- Plants - Nutrition --- Plants - Metabolism --- Energy Metabolism --- Bacterial metabolism --- Bacterial photosynthesis --- Carbon dioxide cycle --- Curing --- Enzymology --- Fruits --- Germination --- Photosynthesis --- Plant chemistry --- Water balance --- RHIZOGENESIS --- VERNALISATION --- PHOTOSYNTHESIS --- FLOWERING --- INHIBITION --- SEED COAT --- DORMANCY --- EMBRYOS --- GERMINATION --- PHOTOPERIODISM --- PHOTOMORPHOGENESIS --- QUANTITATIVE ANALYSIS --- PHYTOCHROME --- REGULATION --- ENZYMES --- GENE EXPRESSION --- CELL DIVISION --- CELL ELONGATION --- GROWTH SUBSTANCES --- PLANTS --- MOLECULAR BIOLOGY --- PLANT DEVELOPMENT --- PLANT GROWTH --- MORPHOGENESIS --- DIFFERENTIATION --- THERMOPERIODISM --- SYNTHESIS
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