Atkins CA, Pate JS, Layzell DB (1979) Assimilation and Transport of Nitrogen in Nonnodulated (NO3-grown) Lupinus albus L. Plant Phys 64: 1078-1082.
Barberon M, Geldner N (2014) Radial transport of nutrients: The plant root as a polarized epithelium. Plant Physiol 166: 528–537
Bramley H, Turner NC, Turner DW, Tyerman SD (2009) Roles of morphology, anatomy, and aquaporins in determining contrasting hydraulic behavior of roots. Plant Physiol 150: 348-364
Chaumont F, Tyerman SD (2014) Aquaporins: highly regulated channels controlling plant water relations. Plant Physiol 164: 1600-1618
Daniels MJ, Chaumont F, Mirkov TE, Chrispeels MJ (1996) Characterization of a new vacuolar membrane aquaporins sensitive to mercury at a unique site. Plant Cell 8: 587-599
Dixon HH (1914) Transpiration and the ascent of sap in plants. Macmillan, London
Dixon HH, Joly J (1894) On the ascent of sap. Phil Trans Royal Soc (London) Series B, 186: 563-576
Findlay GP, Findlay N (1975) Anatomy and movement of the column of Stylidium. Aust J Plant Physiol 2: 597-621
Geldner N (2013) The endodermis. Annu Rev Plant Biol 64: 531–558
Hose E, Clarkson DT, Steudle E et al. (2001) The exodermis: a variable apoplastic barrier. J Exp Bot 52: 2245-2264
Huang CX, van Steveninck RFM (1988) Effect of moderate salinity on patterns of potassium, sodium and chloride accumulation in cells near the root tip of barley: Role of differentiating xylem vessels. Physiol Plant 73: 525-533
Jeschke WD, Pate JS, Atkins CA (1986) Effects of NaCl salinity on growth, development, ion transport and ion storage in white lupin (Lupinus alba L. cv. Ultra). J Plant Physiol 124: 237-274
LaBarbera M (1990) Principles of design of fluid transport systems in zoology. Science 249: 992-1000
Kramer PF, Boyer JS (1995) Water relations of plants and soils. http://udspace.udel.edu/handle/19716/2830
Maurel C, Kado RT , Guern J, Chrispeels M (1995) Phosphorylation regulates the water channel activity of the seed-specific aquaporin α-TIP. EMBO J 14: 3028-3035
Melchior W, Steudle E (1993) Water transport in onion roots: Changes of axial and radial hydraulic conductivities during root development. Plant Physiol 101: 1305-1315
McCully ME (1994) Accumulation of high levels of potassium in the developing xylem elements in roots of soybean and some other dicotyledons. Protoplasma 183: 116-125
McCully ME , Canny MJ (1988) Pat hways and processes of water and nutrient movement in roots. Plant Soil 111: 159-170
Munns R (1985) Na+, K+ and Cl- in xylem sap flowing to shoots of NaCl-treated barley. J Exp Bot 36: 1032-1042
Munns R, Passioura JB (1984) Hydraulic resistance of plants. III. Effects of NaCl in barley and lupin. Aust J Plant Physiol 11: 351-359
Nobel PS (2005) Physicochemical and environmental plant physiology (3rd edition). Elsevier Academic Press, Burlington, MA
Passioura JB (1980) The meaning of matric potential. J Exp Bot 31:1161-1169
Passioura JB (2010) Plant–Water Relations. In: Encyclopedia of Life Sciences. Wiley, Chichester. DOI: 10.1002/9780470015902.a0001288.pub2
Passioura JB (2006) The perils of pot experiments. Funct Plant Biol 33: 1075–1079
Passioura JB (1980) The transport of water from soil to shoot in wheat seedlings. J Exp Bot 31: 333-345
Perumalla CJ, Peterson CA, Enstone DE (1990) A survey of angiosperm species to detect Casparian bands. I. Roots with a uniseriate hypodermis and epidermis. Bot J Linnean Soc 103: 93-112
Peuke AD (2010) Correlations in concentrations, xylem and phloem flows, and partitioning of elements and ions in [intact plants. A summary and statistical re-evalution of modelling experiments in Ricinus communis. J Exp Bot 61: 6344-655
Plett DC, Moller IS (2010) Na+ transport in glycophytic plants. Plant Cell Environ 33: 612-626
Schütz K, Tyerman SD (1997) Water channels in Chara correlina. J Exp Bot 48: 1511-1518
Strazburger E (1893) Über das saftsteigen. Fischer: Jena, Germany.
Tyerman SD, Steudle E (1982) Comparison between osmotic and hydrostatic water flows in a higher plant cell. Aust J Plant Physiol 9: 416-479
Watt M, Magee LJ, McCully ME (2008) Types, structure and potential for axial water flow in the deepest roots of field-grown cereals. New Phytol 178: 135-146