Water and Solute Permeability of Plant Cuticles: Measurement and ...

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References Abraham MH, McGowan JC (1987) The use of characteristic volumes to measure cavity terms in reversed phase liquid chromatography. Chromatographia, Springer, Heidelberg Adamson AW (1976) Physical chemistry of surfaces. Wiley, New York Albert A, Serjeant EP (1971) The determination of ionization constant. Chapman & Hall, London Amelunxen F, Morgenroth K, Picksack T (1967) Untersuchungen an der Epidermis mit dem Steroscan-Elektronenmikroskop. Pflanzenphysiol 57:79–95 Andersen SO (1979) Biochemistry of insect cuticle. Annu Rev Entomol 24:29–59 Archer RJ, La Mer VK (1955) The rate of evaporation of water through fatty acid monolayers. J Phys Chem 59:200–208 Baker EA (1982) Chemistry and morphology of plant epicuticular waxes. In: Cutler DE, Alvin KL, Price CE (eds) The plant cuticle. Academic Press, London, pp 139–165 Baker EA, Procopiou J (1975) The cuticles of citrus species. Composition of the intramolecular lipids of leaves and fruits. J Sci Food Agric 26:1347–1352 Baker EA, Procopiou J, Hunt GM (1975) The cuticles of citrus species. Composition of leaf and fruit waxes. J Sci Food Agric 26:1093–1101 Baker EA, Bukovac MJ, Hunt GM (1982) Composition of tomato fruit cuticle as related to fruit growth and development. In: Cutler DF, Alvin KL, Price CE (eds) The plant cuticle. Academic Press, London, pp 33–44 Banderup J, Immergut EH (1966) Polymer handbook. Wiley, New York Barrie JA (1968) Water in polymers. In: Crank J, Park GS (eds) Diffusion in polymers. Academic Press, London Barrow GM (1961) Physical chemistry. McGraw-Hill, New York Barthlott W (1990) Scanning electron microscopy of the epidermal surface of plants. In: Claugher D (ed) Scanning EM in taxonomy and functional morphology. Systematics Association’s Special, Vol. 41. Clarendon, Oxford, pp 69–94 Barthlott W, Frölich D (1983) Mikromorphologie und Orientierungsmuster epicuticularer Wachs-Kristalloide: Ein neues systematisches Merkmal bei Monokotylen. Plant Syst Evol 142:171–185 Bauer L (1953) Zur Frage der Stoffbewegung in der Pflanze mit besonderer Berücksichtigung der Wanderung von Fluorochromen. Planta 42:347–451 Bauer H, Schönherr J (1992) Determination of mobilities of organic compounds in plant cuticles and correlation with molar volumes. Pestic Sci 35:1–11 Baur P (1997) Lognormal distribution of water permeability and organic solute mobility in plant cuticles. Plant Cell Environ 20:167–177 Baur P (1998) Mechanistic aspects of foliar penetration of agrochemicals and the effect of adjuvants. Recent Res Dev Agric Food Chem 2:809–837 285
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Water and Solute Permeability of Pl
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Professor Dr. Lukas Schreiber Ecoph
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vi Preface This is not a review abo
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Contents 1 Chemistry and Structure
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Contents xi 4.6.3 Diffusion Coeffic
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Contents xiii 7.4.2 Effects of Plas
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2 1 Chemistry and Structure of Cuti
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10 1 Chemistry and Structure of Cut
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Chapter 2 Quantitative Description
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2.1 Models for Analysing Mass Trans
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2.3 Steady State Diffusion Across a
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2.4 Steady State Diffusion of a Sol
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2.4 Steady State Diffusion of a Sol
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2.5 Diffusion Across a Membrane wit
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2.5 Diffusion Across a Membrane wit
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2.6 Determination of the Diffusion
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Solutions 51 2.7 Summary In this ch
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Chapter 3 Permeance, Diffusion and
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3.1 Units of Permeability 55 3.1.1
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3.1 Units of Permeability 57 identi
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3.3 Partition Coefficients 59 The d
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Chapter 4 Water Permeability All te
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4.1 Water Permeability of Synthetic
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4.2 Isoelectric Points of Polymer M
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4.2 Isoelectric Points of Polymer M
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4.3 Ion Exchange Capacity 69 The hi
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4.3 Ion Exchange Capacity 71 has an
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4.3 Ion Exchange Capacity 73 Counte
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4.4 Water Vapour Sorption and Perme
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4.4 Water Vapour Sorption and Perme
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4.5 Diffusion and Viscous Transport
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4.6 Water Permeability of Isolated
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Problems 121 Our present knowledge
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Solutions 123 5. Ca 2+ , because se
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126 5 Penetration of Ionic Solutes
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146 6 Diffusion of Non-Electrolytes
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206 7 Accelerators Increase Solute
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Page 242 and 243: Chapter 8 Effects of Temperature on
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Page 256 and 257: 8.3 Water Permeability in CM and MX
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Page 266 and 267: Problems 257 E D (kJ/mol) DH S (kJ/
Page 268 and 269: Chapter 9 General Methods, Sources
Page 270 and 271: 9.2 Testing Integrity of Isolated C
Page 272 and 273: 9.4 Distribution of Water and Solut
Page 274 and 275: 9.6 Cutin and Wax Analysis and Prep
Page 276 and 277: 9.7 Measuring Water Permeability 26
Page 278 and 279: 9.8 Measuring Solute Permeability 2
Page 284 and 285: 276 Appendix A Abbreviations (conti
Page 286 and 287: 278 Appendix A Symbols (continued)
Page 288 and 289: 280 Appendix B Physico-chemical pro
Page 290 and 291: Appendix C Index of Plants Botanica
Page 294 and 295: References 287 Doty PM, Aiken WH, M
Page 296 and 297: References 289 Kolattukudy P (2004)
Page 298 and 299: References 291 Sabljic A, Güsten H
Page 300 and 301: References 293 Schreiber L, Schönh
Page 302 and 303: Index 2,4-D, 46 2,4-Dichlorophenoxy
Page 304 and 305: Index 297 leaf disks, 130 leaf surf
Page 306: Index 299 water molar volume, 110 p
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