Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Soil Research Soil Research Society
Soil, land care and environmental research
Shopping Cart: ( empty )
You are here: Home > Journals > SR > SR07103
RESEARCH ARTICLE
Contents Vol 46(1)

Absorption of gypsum solution by a potassic soil: a data set

D. E. Smiles A B and C. J. Smith A
+ Author Affiliations
- Author Affiliations

A CSIRO Land and Water, PO Box 1666, Canberra, ACT 2601, Australia.

B Corresponding author. Email: david.smiles@csiro.au

Australian Journal of Soil Research 46(1) 67-75 https://doi.org/10.1071/SR07103
Submitted: 19 July 2007  Accepted: 5 December 2007   Published: 8 February 2008

Abstract

Reliable experimental data required to test hydrodynamic dispersion/chemical reaction models are scarce. This paper provides such a dataset based on absorption of gypsum solution by horizontal columns of relatively dry soil with an initially high exchangeable potassium ratio. Initial and boundary conditions are well defined. Water and cation concentration profiles measured after 200 and 400 min lay on single curves when graphed in terms of distance divided by the square root of time. Cation exchange occurred close to the intake surface and calcium derived from the gypsum was confined to a narrow band well behind the notional piston front that separates the absorbed solution from that originally present. Anion exchange was negligible and the solution concentration up to the piston front approximated the anion concentration of the invading solution. The interval between the region of cation exchange and the piston front maintained the original cation adsorption ratios but at a total cation solution concentration approximating that of saturated gypsum (~25 mmolc/L). Some implications of this phenomenon are discussed. Comparison of cation exchange isotherms observed when the virgin soil absorbs effluent-like solutions and when effluent-irrigated soil absorbs saturated gypsum suggest that, operationally, these isotherms may be considered to be unaffected by hysteresis in the exchange reactions.

Additional keywords: adsorption isotherms, effluent irrigation, cation exchange, cation ratios, solute retardation, water-soluble cations, soil structure stability.


Acknowledgments

Professor N Collis-George and Dr Freeman Cook offered comments; Seija Tuomi and Adrian Beech carried out chemical analyses; the project was funded by CSIRO and Australian Pork Limited.


References


Biswas TK, Higginson FR, Shannon I (1999) Effluent nutrient management and resource recovery in intensive rural industries for the protection of natural waters. Water Science and Technology 40, 19–27.
Crossref | GoogleScholarGoogle Scholar | open url image1

Bolt GH , Bruggenwert MGM , Kamphorst A (1976) Adsorption of cations by soil. In ‘Soil chemistry. Part A. Basic elements’. (Eds GH Bolt, MGM Bruggenwert) pp. 54–90. (Elsevier: Amsterdam)

Bond WJ, Phillips IR (1990) Cation exchange isotherms obtained with batch and miscible-displacement techniques. Soil Science Society of America Journal 54, 722–728. open url image1

Crank J (1956) ‘The mathematics of diffusion’. pp. 121 et seq. (Oxford: London)

Hutson JL , Wagenet RJ (1992) LEACHM. A process based model of water and solute movement, transformations, plant uptake and chemical reactions in the unsaturated zone. Version 3. Cornell University Department of Soil, Crop and Atmospheric Sciences Research Series No. 92–3, September 1992.

Kruger I , Taylor G , Ferrier M (1995) ‘Effluent at work. Australian pig housing series.’ (NSW Agriculture: Tamworth, NSW)

Mackenzie DH (2002) Field measurement of saturated hydraulic conductivity using the well permeameter. In ‘Soil physical measurement and interpretation for land evaluation’. (Eds N McKenzie, K Coughlan, H Cresswell) pp. 131–149. (CSIRO Publishing: Collingwood, Vic.)

McKenzie NJ , Cresswell HP (2002) Selecting a method for hydraulic conductivity. In ‘Soil physical measurement and interpretation for land evaluation’. (Eds N McKenzie, K Coughlan, H Cresswell) pp. 90–107. (CSIRO Publishing: Collingwood, Vic.)

Parkhurst DL , Appelo CAJ (1999) User’s guide to PHREEQC (Version 2) – a computer program for speciation, batch-reaction, one-dimensional transport, and inverse geochemical calculations. U.S. Geological Survey Water-Resources Investigations Report 99-4259.

Philip JR (1957) Theory of infiltration. 4. Sorptivity and algebraic infiltration equations. Soil Science 84, 257–264. open url image1

Phillips IR, Bond WJ (1989) Extraction procedure for determining solution and exchangeable ions in the same soil sample. Soil Science Society of America Journal 53, 1294–1297. open url image1

Raats PAC, Klute A (1968) Transport in soils: the balance of mass. Soil Science Society of America Proceedings 32, 161–166. open url image1

Rassam D , Šimůnek J , van Genuchten M-Th (2004) ‘Modelling variably saturated flow with HYDRUS-2D.’ 2nd edn (ND Consult: Brisbane, Qld)

Rayment GE , Higginson FR (1992) ‘Australian laboratory handbook of soil and water chemical methods. Australian soil and land survey handbook.’ (Inkata Press: Melbourne)

Reiniger P, Bolt GH (1972) Theory of chromatography and its application to cation exchange in soils. Netherlands Journal of Agricultural Science 20, 301–313. open url image1

Rengasamy P, Greene RSB, Ford GW, Mehanni AH (1984) Identification of dispersive behaviour and management of Red Brown Earths. Australian Journal of Soil Research 22, 413–431.
Crossref | GoogleScholarGoogle Scholar | open url image1

Richards LA (Ed.) (1954) ‘Diagnosis and improvement of saline and alkali soils.’ Agriculture Handbook 60. (USDA: Washington, DC)

Šimůnek J, Jacques D, van Genuchten M-Th, Mallants D (2006) Multicomponent geochemical transport modeling using hydrus-1D and HP1. Journal of the American Water Resources Association 42, 1537–1547.
Crossref | GoogleScholarGoogle Scholar | open url image1

Smiles DE (2000) Material coordinates and solute movement in consolidating clay. Chemical Engineering Science 55, 773–781.
Crossref | GoogleScholarGoogle Scholar | open url image1

Smiles DE (2001) Chemical reaction and Co-60 retardation in unsteady unsaturated soil water flow: the effect of clay content. Australian Journal of Soil Research 39, 1059–1075.
Crossref | GoogleScholarGoogle Scholar | open url image1

Smiles DE, Perroux KM, Zegelin SJ, Raats PAC (1981) Hydrodynamic dispersion during constant rate absorption of water by soil. Soil Science Society of America Journal 45, 453–458. open url image1

Smiles DE, Philip JR (1978) Solute transport during absorption of water by soil: laboratory studies and their practical implications. Soil Science Society of America Journal 42, 537–544. open url image1

Smiles DE, Smith CJ (2004a) A survey of the cation content of piggery effluents and some chemical consequences of their use to irrigate soils. Australian Journal of Soil Research 42, 231–246.
Crossref | GoogleScholarGoogle Scholar | open url image1

Smiles DE, Smith CJ (2004b) Absorption of artificial piggery effluent by soil: a laboratory study. Australian Journal of Soil Research 42, 961–975.
Crossref | GoogleScholarGoogle Scholar | open url image1

Suarez DL (2001) Sodic soil reclamation: modelling and field study. Australian Journal of Soil Research 39, 1225–1246.
Crossref | GoogleScholarGoogle Scholar | open url image1

Suarez DL, Šimůnek J (1997) UNSATCHEM: unsaturated water and solute transport model with equilibrium and kinetic chemistry. Soil Science Society of America Journal 61, 1633–1646. open url image1

White GN , Zelazny LW (1986) Charge properties of soil colloids. In ‘Soil physical chemistry’. (Ed. DL Sparks) pp. 56–63. (CRC Press: Boca Raton, FL)