Verfügbarkeit: Physicochemical and environmental plant physiology

Physicochemical and environmental plant physiology:

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Bibliographische Detailangaben
1. Verfasser:	Nobel, Park S. (VerfasserIn)
Format:	Buch
Sprache:	English
Veröffentlicht:	Amsterdam [u.a.] Elsevier, Acad. Press 2009
Ausgabe:	4. ed.
Schriftenreihe:	Plant biology
Schlagworte:	Plant physiology Botanical chemistry Plant ecophysiology Plant cells and tissues Umweltfaktor Autökologie Biochemie Biophysik Pflanzen Pflanzenphysiologie
Online-Zugang:	Inhaltsverzeichnis
Beschreibung:	Includes bibliographical references
Beschreibung:	XXI, 582 S. Ill., graph. Darst.
ISBN:	9780123741431 0123741432

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Datensatz im Suchindex

_version_	1804138362573946880
adam_text	Contents Preface xiii Symbols and Abbreviations xv 1. Cells and Diffusion 3 1.1. Cell Structure 3 1.1 A. Generalized Plant Cell 3 1.1B. Leaf Anatomy 5 1.1C. Vascular Tissue 7 1.1D. Root Anatomy 9 1.2. Diffusion 11 1.2 A. Fick s First Law 12 1.2B. Continuity Equation and Fick s Second Law 14 1.2C. Time-Distance Relation for Diffusion 16 1.2D. Diffusion in Air 19 1.3. Membrane Structure 21 1.3A. Membrane Models 21 1.3B. Organelle Membranes 23 1.4. Membrane Permeability 25 1.4 A. Concentration Difference Across a Membrane 26 1.4B. Permeability Coefficient 28 1.4C. Diffusion and Cellular Concentration 29 1.5. Cell Walls 31 1.5 A. Chemistry and Morphology 33 1.5B. Diffusion Across Cell Walls 34 1.5C. Stress-Strain Relations of Cell Walls 37 1.5D. Elastic Modulus, Viscoelasticity 39 1.6. Problems 40 1.7. References and Further Reading 42 2. Water 45 2.1. Physical Properties 46 2.1A. Hydrogen Bonding—Thermal Relations 47 2. IB. Surface Tension 49 2.1C. Capillary Rise 50 2. ID. Capillary Rise in the Xylem 53 Contents 2.1E. Tensile Strength, Viscosity 54 2.1F. Electrical Properties 55 2.2. Chemical Potential 56 2.2A. Free Energy and Chemical Potential 56 2.2B. Analysis of Chemical Potential 60 2.2C. Standard State 63 2.2D. Hydrostatic Pressure 64 2.2E. Water Activity and Osmotic Pressure 65 2.2F. Van t Hoff Relation 66 2.2G. Matric Pressure 69 2.2H. Water Potential 71 2.3. Central Vacuole and Chloroplasts 72 2.3 A. Water Relations of the Central Vacuole 73 2.3B. Boyle-Van t Hoff Relation 74 2.3C. Osmotic Responses of Chloroplasts 76 2.4. Water Potential and Plant Cells 78 2.4A. Incipient Plasmolysis 78 2.4B. Höfler Diagram and Pressure-Volume Curve 81 2.4C. Chemical Potential and Water Potential of Water Vapor 84 2.4D. Plant-Air Interface 87 2.4E. Pressure in the Cell Wall Water 88 2.4F. Water Flux 91 2.4G. Cell Growth 93 2.4H. Kinetics of Volume Changes 95 2.5. Problems 96 2.6. References and Further Reading 98 3. Solutes 101 3.1. Chemical Potential of Ions 102 3.1A. Electrical Potential 103 3.1B. Electroneutrality and Membrane Capacitance 104 3.1C. Activity Coefficients of Ions 106 3.1D. Nernst Potential 108 3.1E. Example of ΕΝκ 110 3.2. Fluxes and Diffusion Potentials 112 3.2A. Flux and Mobility 113 3.2B. Diffusion Potential in a Solution 116 3.2C. Membrane Fluxes 119 3.2D. Membrane Diffusion Potential—Goldman Equation 122 3.2E. Application of Goldman Equation 125 3.2F. Donnan Potential 127 3.3. Characteristics of Crossing Membranes 129 3.3A. Electrogenicity 130 3.3B. Boltzmann Energy Distribution and Ql0, a Temperature Coefficient 131 3.3C. Activation Energy and Arrhenius Plots 135 3.3D. Ussing-Teorell Equation 137 3.3E. Example of Active Transport 140 Vil Contents 3.3F. Energy for Active Transport 142 3.3G. Speculation on Active Transport 143 3.4. Mechanisms for Crossing Membranes 144 3.4A. Carriers, Porters, Channels, and Pumps 145 3.4B. Michaelis-Menten Formalism 149 3.4C. Facilitated Diffusion 151 3.5. Principles of Irreversible Thermodynamics 153 3.5A. Fluxes, Forces, and Onsager Coefficients 154 3.5B. Water and Solute Flow 156 3.5C. Flux Densities, Lp, and σ 158 3.5D. Values for Reflection Coefficients 161 3.6. Solute Movement Across Membranes 163 3.6 A. Influence of Reflection Coefficients on Incipient Plasmolysis 165 3.6B. Extension of the Boyle-Van t Hoff Relation 167 3.6C. Reflection Coefficients of Chloroplasts 169 3.6D. Solute Flux Density 169 3.7. Problems 170 3.8. References and Further Reading 173 4. Light 177 4.1. Wavelength and Energy 179 4.1A. Lightwaves 179 4.1B. Energy of Light 182 4.1C. Illumination, Photon Flux Density, and Irradiance 185 4.1D. Sunlight 188 4.1E. Planck s and Wien s Formulae 190 4.2. Absorption of Light by Molecules 191 4.2A. Role of Electrons in Absorption Event 192 4.2B. Electron Spin and State Multiplicity 194 4.2C. Molecular Orbitals 195 4.2D. Photoisomerization 198 4.2E. Light Absorption by Chlorophyll 199 4.3. Deexcitation 201 4.3 A. Fluorescence, Radiationless Transition, and Phosphorescence 202 4.3B. Competing Pathways for Deexcitation 203 4.3C. Lifetimes 206 4.3D. Quantum Yields 208 4.4. Absorption Spectra and Action Spectra 208 4.4A. Vibrational Subleveis 210 4.4B. The Franck-Condon Principle 211 4.4C. Absorption Bands, Absorption Coefficients, and Beer s Law 214 4.4D. Application of Beer s Law 216 4.4E. Conjugation 217 4.4F. Action Spectra 219 4.4G. Absorption and Action Spectra of Phytochrome 220 VIH Contents 4.5. Problems 223 4.6. References and Further Reading 225 5. Photochemistry of Photosynthesis 229 5.1. Chlorophyll—Chemistry and Spectra 232 5.1A. Types and Structures 232 5. IB. Absorption and Fluorescence Emission Spectra 233 5.1C. Absorption in Vivo—Polarized Light 236 5.2. Other Photosynthetic Pigments 238 5.2A. Carotenoids 238 5.2B. Phycobilins 242 5.2C. General Comments 244 5.3. Excitation Transfers Among Photosynthetic Pigments 245 5.3A. Pigments and the Photochemical Reaction 246 5.3B. Resonance Transfer of Excitation 247 5.3C. Specific Transfers of Excitation 248 5.3D. Excitation Trapping 250 5.4. Groupings of Photosynthetic Pigments 253 5.4A. Photon Processing 253 5.4B. Excitation Processing 253 5.4C. Photosynthetic Action Spectra and Enhancement Effects 256 5.4D. Two Photosystems Plus Light-Harvesting Antennae 256 5.5. Electron Flow 260 5.5A. Electron Flow Model 260 5.5B. Components of the Electron Transfer Pathway 262 5.5C. Types of Electron Flow 268 5.5D. Assessing Photochemistry using Fluorescence 269 5.5E. Photophosphorylation 271 5.5F. Vectorial Aspects of Electron Flow 271 5.6. Problems 273 5.7. References and Further Reading 274 6. Bioenergetics 277 6.1. Gibbs Free Energy 278 6.1A. Chemical Reactions and Equilibrium Constants 280 6.1B. Interconversion of Chemical and Electrical Energy 283 6.1C. RedoxPotentials 285 6.2. Biological Energy Currencies 286 6.2A. ATP-Structure and Reactions 287 6.2B. Gibbs Free Energy Change for ATP Formation 291 6.2C. NADP+-NADPH Redox Couple 293 6.3. Chloroplast Bioenergetics 295 6.3A. Redox Couples 295 6.3B. № Chemical Potential Differences Caused by Electron Flow 299 6.3C. Evidence for Chemiosmotic Hypothesis 300 6.3D. Coupling of Flows 302 IX Contents 6.4. Mitochondrial Bioenergetics 303 6.4A. Electron Flow Components— RedoxPotentials 304 6.4B. Oxidative Phosphorylation 307 6.5. Energy Flow in the Biosphere 310 6.5A. Incident Light—Stefan-Boltzmann Law 311 6.5B. Absorbed Light and Photosynthetic Efficiency 313 6.5C. Food Chains and Material Cycles 314 6.6. Problems 315 6.7. References and Further Reading 317 7. Temperature and Energy Budgets 319 7.1. Energy Budget—Radiation 320 7.1A. Solar Irradiation 322 7.1B. Absorbed Infrared Irradiation 326 7.1C. Emitted Infrared Radiation 327 7.1D. Values for a, a,R, and eIR 328 7.1E. Net Radiation 330 7.1F. Examples for Radiation Terms 330 7.2. Heat Conduction and Convection 333 7.2A. Wind 334 7.2B. Air Boundary Layers 336 7.2C. Boundary Layers for Bluff Bodies 339 7.2D. Heat Conduction/Convection Equations 340 7.2E. Dimensionless Numbers 341 7.2F. Examples of Heat Conduction/Convection 345 7.3. Latent Heat—Transpiration 346 7.3 A. Heat Flux Density Accompanying Transpiration 346 7.3B. Heat Flux Density for Dew or Frost Formation 347 7.3C. Examples of Frost and Dew Formation 348 7.4. Further Examples of Energy Budgets 350 7.4A. Leaf Shape and Orientation 350 7.4B. Shaded Leaves within Plant Communities 352 7.4C. Heat Storage 352 7.4D. Time Constants 354 7.5. Soil 355 7.5 A. Thermal Properties 356 7.5B. Soil Energy Balance 357 7.5C. Variations in Soil Temperature 358 7.6. Problems 360 7.7. References and Further Reading 362 8. Leaves and Fluxes 365 8.1. Resistances and Conductances—Transpiration 366 8.1 A. Boundary Layer Adjacent to Leaf 368 8.1B. Stornata 371 8.1С. Stomatal Conductance and Resistance 373 Contents 8.1D. Cuticle 376 8.1E. Intercellular Air Spaces 376 8.1F. Fick s First Law and Conductances 377 8.2. Water Vapor Fluxes Accompanying Transpiration 380 8.2A. Conductance and Resistance Network 380 8.2B. Values of Conductances 383 8.2C. Effective Lengths and Resistance 384 8.2D. Water Vapor Concentrations, Mole Fractions and Partial Pressures for Leaves 385 8.2E. Examples of Water Vapor Levels in a Leaf 387 8.2F. Water Vapor Fluxes 389 8.2G. Control of Transpiration 390 8.3. CO2 Conductances and Resistances 392 8.3A. Resistance and Conductance Network 392 8.3B. Mesophyll Area 394 8.3C. Resistance Formulation for Cell Components 397 8.3D. Partition Coefficient for CO2 398 8.3E. Cell Wall Resistance 399 8.3F. Plasma Membrane Resistance 400 8.3G. Cytosol Resistance 401 8.3H. Mesophyll Resistance 402 8.31. Chloroplast Resistance 402 8.4. CO2 Fluxes Accompanying Photosynthesis 403 8.4A. Photosynthesis 403 8.4B. Respiration and Photorespiration 406 8.4C. Comprehensive CO2 Resistance Network 410 8.4D. Compensation Points 412 8.4E. Fluxes of CO2 416 8.4F. CO2 Conductances 418 8.4G. Photosynthetic Rates 420 8.4H. Environmental Productivity Index 420 8.5. Water-Use Efficiency 422 8.5 A. Values for WUE 423 8.5B. Elevational Effects on WUE 425 8.5C. Stomatal Control of WUE 426 8.5D. C3 versus C4 Plants 429 8.6. Problems 432 8.7. References and Further Reading 434 9. Plants and Fluxes 439 9.1. Gas Fluxes above Plant Canopy 440 9.1A. Wind Speed Profiles 441 9. IB. Flux Densities 442 9.1C. Eddy Diffusion Coefficients 443 9. ID. Resistance of Air above Canopy 445 9.1E. Transpiration and Photosynthesis 445 9.1F. Values for Fluxes and Concentrations 446 9.1G. Condensation 448 9.2. Gas Fluxes within Plant Communities 449 9.2A. Eddy Diffusion Coefficient and Resistance 449 Xl Contents 9.2B. Water Vapor 451 9.2C. Attenuation of the Photosynthetic Photon Flux 453 9.2D. Values for Foliar Absorption Coefficient 454 9.2E. Light Compensation Point 455 9.2F. CO2 Concentrations and Fluxes 456 9.2G. CO2 at Night 458 9.3. Water Movement in Soil 459 9.3A. Soil Water Potential 460 9.3B. Darcy sLaw 462 9.3C. Soil Hydraulic Conductivity Coefficient 463 9.3D. Fluxes for Cylindrical Symmetry 465 9.3E. Fluxes for Spherical Symmetry 467 9.4. Water Movement in the Xylem and the Phloem 469 9.4A. Root Tissues 469 9.4B. Xylem 470 9.4C. Poiseuille s Law 471 9.4D. Applications of Poiseuille s Law 472 9.4E. Phloem 476 9.4F. Phloem Contents and Speed of Movement 478 9.4G. Mechanism of Phloem Flow 479 9.4H. Values for Components of the Phloem Water Potential 480 9.5. Soil-Plant-Atmosphere Continuum 483 9.5A. Values for Water Potential Components 483 9.5B. Resistances and Areas 485 9.5C. Values for Resistances and Resistivities 487 9.5D. Root-Soil Air Gap and Hydraulic Conductances 490 9.5E. Capacitance and Time Constants 492 9.5F. Daily Changes 495 9.5G. Global Climate Change 497 9.6. Problems 500 9.7. References and Further Reading 503 Solutions To Problems 507 Appendix I. Numerical Values of Constants and Coefficients 545 Appendix II. Conversion Factors and Definitions 553 Appendix HI. Mathematical Relations 557 IILA. Prefixes (for units of measure) 557 III.B. Areas and Volumes 557 III.C. Logarithms 557 III.D. Quadratic Equation 558 III.E.Trignometric Functions 558 III.F. Differential Equations 558 Appendix IV. Gibbs Free Energy and Chemical Potential 561 IVA. Entropy and Equilibrium 561 IV.B. Gibbs Free Energy 563 IV.C. Chemical Potential 565 I V.D. Pressure Dependence of μ . 565 IVE. Concentration Dependence of μ. 568 Index 571
adam_txt	Contents Preface xiii Symbols and Abbreviations xv 1. Cells and Diffusion 3 1.1. Cell Structure 3 1.1 A. Generalized Plant Cell 3 1.1B. Leaf Anatomy 5 1.1C. Vascular Tissue 7 1.1D. Root Anatomy 9 1.2. Diffusion 11 1.2 A. Fick's First Law 12 1.2B. Continuity Equation and Fick's Second Law 14 1.2C. Time-Distance Relation for Diffusion 16 1.2D. Diffusion in Air 19 1.3. Membrane Structure 21 1.3A. Membrane Models 21 1.3B. Organelle Membranes 23 1.4. Membrane Permeability 25 1.4 A. Concentration Difference Across a Membrane 26 1.4B. Permeability Coefficient 28 1.4C. Diffusion and Cellular Concentration 29 1.5. Cell Walls 31 1.5 A. Chemistry and Morphology 33 1.5B. Diffusion Across Cell Walls 34 1.5C. Stress-Strain Relations of Cell Walls 37 1.5D. Elastic Modulus, Viscoelasticity 39 1.6. Problems 40 1.7. References and Further Reading 42 2. Water 45 2.1. Physical Properties 46 2.1A. Hydrogen Bonding—Thermal Relations 47 2. IB. Surface Tension 49 2.1C. Capillary Rise 50 2. ID. Capillary Rise in the Xylem 53 Contents 2.1E. Tensile Strength, Viscosity 54 2.1F. Electrical Properties 55 2.2. Chemical Potential 56 2.2A. Free Energy and Chemical Potential 56 2.2B. Analysis of Chemical Potential 60 2.2C. Standard State 63 2.2D. Hydrostatic Pressure 64 2.2E. Water Activity and Osmotic Pressure 65 2.2F. Van't Hoff Relation 66 2.2G. Matric Pressure 69 2.2H. Water Potential 71 2.3. Central Vacuole and Chloroplasts 72 2.3 A. Water Relations of the Central Vacuole 73 2.3B. Boyle-Van't Hoff Relation 74 2.3C. Osmotic Responses of Chloroplasts 76 2.4. Water Potential and Plant Cells 78 2.4A. Incipient Plasmolysis 78 2.4B. Höfler Diagram and Pressure-Volume Curve 81 2.4C. Chemical Potential and Water Potential of Water Vapor 84 2.4D. Plant-Air Interface 87 2.4E. Pressure in the Cell Wall Water 88 2.4F. Water Flux 91 2.4G. Cell Growth 93 2.4H. Kinetics of Volume Changes 95 2.5. Problems 96 2.6. References and Further Reading 98 3. Solutes 101 3.1. Chemical Potential of Ions 102 3.1A. Electrical Potential 103 3.1B. Electroneutrality and Membrane Capacitance 104 3.1C. Activity Coefficients of Ions 106 3.1D. Nernst Potential 108 3.1E. Example of ΕΝκ 110 3.2. Fluxes and Diffusion Potentials 112 3.2A. Flux and Mobility 113 3.2B. Diffusion Potential in a Solution 116 3.2C. Membrane Fluxes 119 3.2D. Membrane Diffusion Potential—Goldman Equation 122 3.2E. Application of Goldman Equation 125 3.2F. Donnan Potential 127 3.3. Characteristics of Crossing Membranes 129 3.3A. Electrogenicity 130 3.3B. Boltzmann Energy Distribution and Ql0, a Temperature Coefficient 131 3.3C. Activation Energy and Arrhenius Plots 135 3.3D. Ussing-Teorell Equation 137 3.3E. Example of Active Transport 140 Vil Contents 3.3F. Energy for Active Transport 142 3.3G. Speculation on Active Transport 143 3.4. Mechanisms for Crossing Membranes 144 3.4A. Carriers, Porters, Channels, and Pumps 145 3.4B. Michaelis-Menten Formalism 149 3.4C. Facilitated Diffusion 151 3.5. Principles of Irreversible Thermodynamics 153 3.5A. Fluxes, Forces, and Onsager Coefficients 154 3.5B. Water and Solute Flow 156 3.5C. Flux Densities, Lp, and σ 158 3.5D. Values for Reflection Coefficients 161 3.6. Solute Movement Across Membranes 163 3.6 A. Influence of Reflection Coefficients on Incipient Plasmolysis 165 3.6B. Extension of the Boyle-Van't Hoff Relation 167 3.6C. Reflection Coefficients of Chloroplasts 169 3.6D. Solute Flux Density 169 3.7. Problems 170 3.8. References and Further Reading 173 4. Light 177 4.1. Wavelength and Energy 179 4.1A. Lightwaves 179 4.1B. Energy of Light 182 4.1C. Illumination, Photon Flux Density, and Irradiance 185 4.1D. Sunlight 188 4.1E. Planck's and Wien's Formulae 190 4.2. Absorption of Light by Molecules 191 4.2A. Role of Electrons in Absorption Event 192 4.2B. Electron Spin and State Multiplicity 194 4.2C. Molecular Orbitals 195 4.2D. Photoisomerization 198 4.2E. Light Absorption by Chlorophyll 199 4.3. Deexcitation 201 4.3 A. Fluorescence, Radiationless Transition, and Phosphorescence 202 4.3B. Competing Pathways for Deexcitation 203 4.3C. Lifetimes 206 4.3D. Quantum Yields 208 4.4. Absorption Spectra and Action Spectra 208 4.4A. Vibrational Subleveis 210 4.4B. The Franck-Condon Principle 211 4.4C. Absorption Bands, Absorption Coefficients, and Beer's Law 214 4.4D. Application of Beer's Law 216 4.4E. Conjugation 217 4.4F. Action Spectra 219 4.4G. Absorption and Action Spectra of Phytochrome 220 VIH Contents 4.5. Problems 223 4.6. References and Further Reading 225 5. Photochemistry of Photosynthesis 229 5.1. Chlorophyll—Chemistry and Spectra 232 5.1A. Types and Structures 232 5. IB. Absorption and Fluorescence Emission Spectra 233 5.1C. Absorption in Vivo—Polarized Light 236 5.2. Other Photosynthetic Pigments 238 5.2A. Carotenoids 238 5.2B. Phycobilins 242 5.2C. General Comments 244 5.3. Excitation Transfers Among Photosynthetic Pigments 245 5.3A. Pigments and the Photochemical Reaction 246 5.3B. Resonance Transfer of Excitation 247 5.3C. Specific Transfers of Excitation 248 5.3D. Excitation Trapping 250 5.4. Groupings of Photosynthetic Pigments 253 5.4A. Photon Processing 253 5.4B. Excitation Processing 253 5.4C. Photosynthetic Action Spectra and Enhancement Effects 256 5.4D. Two Photosystems Plus Light-Harvesting Antennae 256 5.5. Electron Flow 260 5.5A. Electron Flow Model 260 5.5B. Components of the Electron Transfer Pathway 262 5.5C. Types of Electron Flow 268 5.5D. Assessing Photochemistry using Fluorescence 269 5.5E. Photophosphorylation 271 5.5F. Vectorial Aspects of Electron Flow 271 5.6. Problems 273 5.7. References and Further Reading 274 6. Bioenergetics 277 6.1. Gibbs Free Energy 278 6.1A. Chemical Reactions and Equilibrium Constants 280 6.1B. Interconversion of Chemical and Electrical Energy 283 6.1C. RedoxPotentials 285 6.2. Biological Energy Currencies 286 6.2A. ATP-Structure and Reactions 287 6.2B. Gibbs Free Energy Change for ATP Formation 291 6.2C. NADP+-NADPH Redox Couple 293 6.3. Chloroplast Bioenergetics 295 6.3A. Redox Couples 295 6.3B. № Chemical Potential Differences Caused by Electron Flow 299 6.3C. Evidence for Chemiosmotic Hypothesis 300 6.3D. Coupling of Flows 302 IX Contents 6.4. Mitochondrial Bioenergetics 303 6.4A. Electron Flow Components— RedoxPotentials 304 6.4B. Oxidative Phosphorylation 307 6.5. Energy Flow in the Biosphere 310 6.5A. Incident Light—Stefan-Boltzmann Law 311 6.5B. Absorbed Light and Photosynthetic Efficiency 313 6.5C. Food Chains and Material Cycles 314 6.6. Problems 315 6.7. References and Further Reading 317 7. Temperature and Energy Budgets 319 7.1. Energy Budget—Radiation 320 7.1A. Solar Irradiation 322 7.1B. Absorbed Infrared Irradiation 326 7.1C. Emitted Infrared Radiation 327 7.1D. Values for a, a,R, and eIR 328 7.1E. Net Radiation 330 7.1F. Examples for Radiation Terms 330 7.2. Heat Conduction and Convection 333 7.2A. Wind 334 7.2B. Air Boundary Layers 336 7.2C. Boundary Layers for Bluff Bodies 339 7.2D. Heat Conduction/Convection Equations 340 7.2E. Dimensionless Numbers 341 7.2F. Examples of Heat Conduction/Convection 345 7.3. Latent Heat—Transpiration 346 7.3 A. Heat Flux Density Accompanying Transpiration 346 7.3B. Heat Flux Density for Dew or Frost Formation 347 7.3C. Examples of Frost and Dew Formation 348 7.4. Further Examples of Energy Budgets 350 7.4A. Leaf Shape and Orientation 350 7.4B. Shaded Leaves within Plant Communities 352 7.4C. Heat Storage 352 7.4D. Time Constants 354 7.5. Soil 355 7.5 A. Thermal Properties 356 7.5B. Soil Energy Balance 357 7.5C. Variations in Soil Temperature 358 7.6. Problems 360 7.7. References and Further Reading 362 8. Leaves and Fluxes 365 8.1. Resistances and Conductances—Transpiration 366 8.1 A. Boundary Layer Adjacent to Leaf 368 8.1B. Stornata 371 8.1С. Stomatal Conductance and Resistance 373 Contents 8.1D. Cuticle 376 8.1E. Intercellular Air Spaces 376 8.1F. Fick's First Law and Conductances 377 8.2. Water Vapor Fluxes Accompanying Transpiration 380 8.2A. Conductance and Resistance Network 380 8.2B. Values of Conductances 383 8.2C. Effective Lengths and Resistance 384 8.2D. Water Vapor Concentrations, Mole Fractions and Partial Pressures for Leaves 385 8.2E. Examples of Water Vapor Levels in a Leaf 387 8.2F. Water Vapor Fluxes 389 8.2G. Control of Transpiration 390 8.3. CO2 Conductances and Resistances 392 8.3A. Resistance and Conductance Network 392 8.3B. Mesophyll Area 394 8.3C. Resistance Formulation for Cell Components 397 8.3D. Partition Coefficient for CO2 398 8.3E. Cell Wall Resistance 399 8.3F. Plasma Membrane Resistance 400 8.3G. Cytosol Resistance 401 8.3H. Mesophyll Resistance 402 8.31. Chloroplast Resistance 402 8.4. CO2 Fluxes Accompanying Photosynthesis 403 8.4A. Photosynthesis 403 8.4B. Respiration and Photorespiration 406 8.4C. Comprehensive CO2 Resistance Network 410 8.4D. Compensation Points 412 8.4E. Fluxes of CO2 416 8.4F. CO2 Conductances 418 8.4G. Photosynthetic Rates 420 8.4H. Environmental Productivity Index 420 8.5. Water-Use Efficiency 422 8.5 A. Values for WUE 423 8.5B. Elevational Effects on WUE 425 8.5C. Stomatal Control of WUE 426 8.5D. C3 versus C4 Plants 429 8.6. Problems 432 8.7. References and Further Reading 434 9. Plants and Fluxes 439 9.1. Gas Fluxes above Plant Canopy 440 9.1A. Wind Speed Profiles 441 9. IB. Flux Densities 442 9.1C. Eddy Diffusion Coefficients 443 9. ID. Resistance of Air above Canopy 445 9.1E. Transpiration and Photosynthesis 445 9.1F. Values for Fluxes and Concentrations 446 9.1G. Condensation 448 9.2. Gas Fluxes within Plant Communities 449 9.2A. Eddy Diffusion Coefficient and Resistance 449 Xl Contents 9.2B. Water Vapor 451 9.2C. Attenuation of the Photosynthetic Photon Flux 453 9.2D. Values for Foliar Absorption Coefficient 454 9.2E. Light Compensation Point 455 9.2F. CO2 Concentrations and Fluxes 456 9.2G. CO2 at Night 458 9.3. Water Movement in Soil 459 9.3A. Soil Water Potential 460 9.3B. Darcy'sLaw 462 9.3C. Soil Hydraulic Conductivity Coefficient 463 9.3D. Fluxes for Cylindrical Symmetry 465 9.3E. Fluxes for Spherical Symmetry 467 9.4. Water Movement in the Xylem and the Phloem 469 9.4A. Root Tissues 469 9.4B. Xylem 470 9.4C. Poiseuille's Law 471 9.4D. Applications of Poiseuille's Law 472 9.4E. Phloem 476 9.4F. Phloem Contents and Speed of Movement 478 9.4G. Mechanism of Phloem Flow 479 9.4H. Values for Components of the Phloem Water Potential 480 9.5. Soil-Plant-Atmosphere Continuum 483 9.5A. Values for Water Potential Components 483 9.5B. Resistances and Areas 485 9.5C. Values for Resistances and Resistivities 487 9.5D. Root-Soil Air Gap and Hydraulic Conductances 490 9.5E. Capacitance and Time Constants 492 9.5F. Daily Changes 495 9.5G. Global Climate Change 497 9.6. Problems 500 9.7. References and Further Reading 503 Solutions To Problems 507 Appendix I. Numerical Values of Constants and Coefficients 545 Appendix II. Conversion Factors and Definitions 553 Appendix HI. Mathematical Relations 557 IILA. Prefixes (for units of measure) 557 III.B. Areas and Volumes 557 III.C. Logarithms 557 III.D. Quadratic Equation 558 III.E.Trignometric Functions 558 III.F. Differential Equations 558 Appendix IV. Gibbs Free Energy and Chemical Potential 561 IVA. Entropy and Equilibrium 561 IV.B. Gibbs Free Energy 563 IV.C. Chemical Potential 565 I V.D. Pressure Dependence of μ . 565 IVE. Concentration Dependence of μ. 568 Index 571
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dewey-search	571.2
dewey-sort	3571.2
dewey-tens	570 - Biology
discipline	Biologie
discipline_str_mv	Biologie
edition	4. ed.
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spelling	Nobel, Park S. Verfasser aut Physicochemical and environmental plant physiology Park S. Nobel Plant physiology 4. ed. Amsterdam [u.a.] Elsevier, Acad. Press 2009 XXI, 582 S. Ill., graph. Darst. txt rdacontent n rdamedia nc rdacarrier Plant biology Includes bibliographical references Botanical chemistry Plant ecophysiology Plant cells and tissues Umweltfaktor (DE-588)4124348-1 gnd rswk-swf Autökologie (DE-588)4143684-2 gnd rswk-swf Biochemie (DE-588)4006777-4 gnd rswk-swf Biophysik (DE-588)4006891-2 gnd rswk-swf Pflanzen (DE-588)4045539-7 gnd rswk-swf Pflanzenphysiologie (DE-588)4045580-4 gnd rswk-swf Pflanzen (DE-588)4045539-7 s Autökologie (DE-588)4143684-2 s DE-604 Pflanzenphysiologie (DE-588)4045580-4 s Umweltfaktor (DE-588)4124348-1 s Biochemie (DE-588)4006777-4 s 1\p DE-604 Biophysik (DE-588)4006891-2 s 2\p DE-604 3\p DE-604 Digitalisierung UB Regensburg application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016993268&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 2\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk 3\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk
spellingShingle	Nobel, Park S. Physicochemical and environmental plant physiology Plant physiology Botanical chemistry Plant ecophysiology Plant cells and tissues Umweltfaktor (DE-588)4124348-1 gnd Autökologie (DE-588)4143684-2 gnd Biochemie (DE-588)4006777-4 gnd Biophysik (DE-588)4006891-2 gnd Pflanzen (DE-588)4045539-7 gnd Pflanzenphysiologie (DE-588)4045580-4 gnd
subject_GND	(DE-588)4124348-1 (DE-588)4143684-2 (DE-588)4006777-4 (DE-588)4006891-2 (DE-588)4045539-7 (DE-588)4045580-4
title	Physicochemical and environmental plant physiology
title_alt	Plant physiology
title_auth	Physicochemical and environmental plant physiology
title_exact_search	Physicochemical and environmental plant physiology
title_exact_search_txtP	Physicochemical and environmental plant physiology
title_full	Physicochemical and environmental plant physiology Park S. Nobel
title_fullStr	Physicochemical and environmental plant physiology Park S. Nobel
title_full_unstemmed	Physicochemical and environmental plant physiology Park S. Nobel
title_short	Physicochemical and environmental plant physiology
title_sort	physicochemical and environmental plant physiology
topic	Plant physiology Botanical chemistry Plant ecophysiology Plant cells and tissues Umweltfaktor (DE-588)4124348-1 gnd Autökologie (DE-588)4143684-2 gnd Biochemie (DE-588)4006777-4 gnd Biophysik (DE-588)4006891-2 gnd Pflanzen (DE-588)4045539-7 gnd Pflanzenphysiologie (DE-588)4045580-4 gnd
topic_facet	Plant physiology Botanical chemistry Plant ecophysiology Plant cells and tissues Umweltfaktor Autökologie Biochemie Biophysik Pflanzen Pflanzenphysiologie
url	http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=016993268&sequence=000002&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA
work_keys_str_mv	AT nobelparks physicochemicalandenvironmentalplantphysiology AT nobelparks plantphysiology

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