Eucalyptus reforestation induces soil water repellency
L. L. Walden A , R. J. Harper A C , D. S. Mendham B , D. J. Henry A and J. B. Fontaine AA School of Veterinary and Life Sciences, Murdoch University, 90 South Street, Murdoch, WA 6150, Australia.
B CSIRO Land and Water, Private Bag 12, Hobart, Tas. 7001, Australia.
C Corresponding author. Email: r.harper@murdoch.edu.au
Soil Research 53(2) 168-177 https://doi.org/10.1071/SR13339
Submitted: 24 November 2013 Accepted: 7 October 2014 Published: 25 February 2015
Abstract
There is an increasing interest in eucalypt reforestation for a range of purposes in Australia, including pulp-wood production, carbon mitigation and catchment water management. The impacts of this reforestation on soil water repellency have not been examined despite eucalypts often being associated with water repellency and water repellency having impacts on water movement across and within soils. To investigate the role of eucalypt reforestation on water repellency, and interactions with soil properties, we examined 31 sites across the south-west of Western Australia with paired plots differing only in present land use (pasture v. plantation). The incidence and severity of water repellency increased in the 5–8 years following reforestation with Eucalyptus globulus. Despite this difference in water repellency, there were no differences in soil characteristics, including soil organic carbon content or composition, between pasture and plantation soils, suggesting induction by small amounts of hydrophobic compounds from the trees. The incidence of soil water repellency was generally greater on sandy-surfaced (<10% clay content) soils; however, for these soils 72% of the pasture sites and 31% of the plantation were not water repellent, and this was independent of measured soil properties. Computer modelling revealed marked differences in the layering and packing of waxes on kaolinite and quartz surfaces, indicating the importance of interfacial interactions in the development of soil water repellency. The implications of increased water repellency for the management of eucalyptus plantations are considered.
References
Andersen HC (1980) Molecular dynamics simulations at constant pressure and/or temperature. The Journal of Chemical Physics 72, 2384Barrett G, Slaymaker O (1989) Identification, characterization, and hydrological implications of water repellency in mountain soils, southern British Columbia. Catena 16, 477–489.
| Identification, characterization, and hydrological implications of water repellency in mountain soils, southern British Columbia.Crossref | GoogleScholarGoogle Scholar |
Barton AFM, Tjandra J, Nicholas PG (1989) Chemical evaluation of volatile oils in Eucalyptus species. Journal of Agricultural and Food Chemistry 37, 1253–1257.
| Chemical evaluation of volatile oils in Eucalyptus species.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaL1MXlt1SmurY%3D&md5=3714a9653af7787b1b49dc7aeba6518eCAS |
Bauters TW, Steenhuis TS, Parlange J-Y, DiCarlo DA (1998) Preferential flow in water-repellent sands. Soil Science Society of America Journal 62, 1185–1190.
| Preferential flow in water-repellent sands.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXmvVOqt74%3D&md5=500d2aa7a5e71587dd21015ca2cd9ee1CAS |
Blackwell PS (2000) Management of water repellency in Australia, and risks associated with preferential flow, pesticide concentration and leaching. Journal of Hydrology 231–232, 384–395.
| Management of water repellency in Australia, and risks associated with preferential flow, pesticide concentration and leaching.Crossref | GoogleScholarGoogle Scholar |
Booth TH (2013) Eucalypt plantations and climate change. Forest Ecology and Management 301, 28–34.
| Eucalypt plantations and climate change.Crossref | GoogleScholarGoogle Scholar |
Cawson JG, Sheridan GJ, Smith HG, Lane PNJ (2012) Surface runoff and erosion after prescribed burning and the effect of different fire regimes in forests and shrublands: a review. International Journal of Wildland Fire 21, 857–872.
| Surface runoff and erosion after prescribed burning and the effect of different fire regimes in forests and shrublands: a review.Crossref | GoogleScholarGoogle Scholar |
Coelho COA, Laouina A, Regaya K, Ferreira AJD, Carvalho TMM, Chaker M, Naafa R, Naciri R, Boulet AK, Keizer JJ (2005) The impact of soil water repellency on soil hydrological and erosional processes under Eucalyptus and evergreen Quercus forests in the Western Mediterranean. Australian Journal of Soil Research 43, 309–318.
| The impact of soil water repellency on soil hydrological and erosional processes under Eucalyptus and evergreen Quercus forests in the Western Mediterranean.Crossref | GoogleScholarGoogle Scholar |
Cowie AL, Smith P, Johnson D (2006) Does soil carbon loss in biomass production systems negate the greenhouse benefits of bioenergy? Mitigation and Adaptation Strategies for Global Change 11, 979–1002.
| Does soil carbon loss in biomass production systems negate the greenhouse benefits of bioenergy?Crossref | GoogleScholarGoogle Scholar |
Crockford H, Topalidis S, Richardson DP (1991) Water-repellence in a dry sclerophyll eucalypt forest—measurements and processes. Hydrological Processes 5, 405–420.
| Water-repellence in a dry sclerophyll eucalypt forest—measurements and processes.Crossref | GoogleScholarGoogle Scholar |
DeBano LF (1981) Water repellent soils: a state of the art. U.S. Department of Agriculture Forest Service, Pacific South West Forest and Range Experimental Station, General Technical Report No. PSW-46, Albany, CA, USA.
Diaz-Chavez R, Berndes G, Neary D, Neto AE, Fall M (2011) Water quality assessment of bioenergy production. Biofuels, Bioproducts and Biorefining 5, 445–463.
| Water quality assessment of bioenergy production.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3MXovVWnsrg%3D&md5=0e115e4a16f6b5497ee74a3b5c8a3ecfCAS |
Doerr SH, Shakesby RA, Walsh RPD (1996) Soil hydrophobicity variations with depth and particle size fraction in burned and unburned Eucalyptus globulus and Pinus pinaster forest terrain in the Agueda Basin, Portugal. Catena 27, 25–47.
| Soil hydrophobicity variations with depth and particle size fraction in burned and unburned Eucalyptus globulus and Pinus pinaster forest terrain in the Agueda Basin, Portugal.Crossref | GoogleScholarGoogle Scholar |
Doerr SH, Shakesby RA, Walsh RPD (1998) Spatial variability of soil hydrophobicity in fire-prone eucalyptus and pine forests, Portugal. Soil Science 163, 313–324.
| Spatial variability of soil hydrophobicity in fire-prone eucalyptus and pine forests, Portugal.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXivFKrsbk%3D&md5=176d5780e1571bcf15acd3f80fb6337aCAS |
Doerr SH, Shakesby RA, Walsh RPD (2000) Soil water repellency: Its causes, characteristics and hydro-geomorphological significance. Earth-Science Reviews 51, 33–65.
| Soil water repellency: Its causes, characteristics and hydro-geomorphological significance.Crossref | GoogleScholarGoogle Scholar |
Doerr SH, Leighton-Boyce G, Coelho COA, Ferreira AJD, Walsh RPD, Shakesby RA (2003) Soil water repellency as a potential parameter in rainfall-runoff modelling: Experimental evidence at point to catchment scales from Portugal. Hydrological Processes 17, 363–377.
| Soil water repellency as a potential parameter in rainfall-runoff modelling: Experimental evidence at point to catchment scales from Portugal.Crossref | GoogleScholarGoogle Scholar |
Doerr SH, Llewellyn CT, Douglas P, Morley CP, Mainwaring KA, Haskins C, Johnsey L, Ritsema CJ, Stagnitti F, Allinson G, Ferreira AJD, Keizer JJ, Ziogas AK, Diamantis J (2005) Extraction of compounds associated with water repellency in sandy soils of different origin. Australian Journal of Soil Research 43, 225–237.
| Extraction of compounds associated with water repellency in sandy soils of different origin.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXks1ehsro%3D&md5=041c20c67c30313853d89623b0f01683CAS |
FAO (2014) ‘World reference base for soil resources 2014.’ International soil classification system for naming soils and creating legends for soil maps. World Soil Resources Reports No. 106. (Food and Agriculture Organization of the United Nations: Rome)
Ferreira AJD, Coelho COA, Walsh RPD, Shakesby RA, Ceballos A, Doerr SH (2000) Hydrological implications of soil water-repellency in Eucalyptus globulus forests, north-central Portugal. Journal of Hydrology 231–232, 165–177.
| Hydrological implications of soil water-repellency in Eucalyptus globulus forests, north-central Portugal.Crossref | GoogleScholarGoogle Scholar |
Franco CMM, Clarke PJ, Tate ME, Oades JM (2000) Hydrophobic properties and chemical characterisation of natural water repellent materials in Australian sands. Journal of Hydrology 231–232, 47–58.
| Hydrophobic properties and chemical characterisation of natural water repellent materials in Australian sands.Crossref | GoogleScholarGoogle Scholar |
Gavran M (2013) Australian plantation statistics 2013 update. Australian Bureau of Agricultural and Resource Economics and Sciences, Technical Report 13.3, Canberra, ACT.
Gee GW, Bauder JW (1986) Particle-size analysis. In ‘Methods of soil analysis, Part 1. Physical and mineralogical methods’. (Ed. A Klute) pp. 383–411. (American Society of Agronomy-Soil Science Society of America: Madison, WI, USA)
Gerbens-Leenes W, Hoekstra AY, Van Der Meer TH (2009) The water footprint of bioenergy. Proceedings of the National Academy of Sciences of the United States of America 106, 10219–10223.
| The water footprint of bioenergy.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD1MXot1Gkur8%3D&md5=0024d355921d22ba79e09eb484664670CAS | 19497862PubMed |
Grove TS, O’Connell AM, Mendham D, Barrow NJ, Rance SJ (2001) Sustaining the productivity of tree crops on agricultural land in south-western Australia. Rural Industries Research and Development Corporation, RIRDC Publication No. 01/09, Canberra, ACT.
Harper RJ, McKissock I, Gilkes RJ, Carter DJ, Blackwell PS (2000) A multivariate framework for interpreting the effects of soil properties, soil management and landuse on water repellency. Journal of Hydrology 231–232, 371–383.
| A multivariate framework for interpreting the effects of soil properties, soil management and landuse on water repellency.Crossref | GoogleScholarGoogle Scholar |
Harper RJ, Smettem KRJ, Reid RF, Callister A, McGrath JF, Brennan PD (2009) Pulpwood Crops. In ‘Agroforestry for natural resource management’. (Eds RF Reid, I Nuberg) pp. 199–218. (CSIRO Publishing: Melbourne)
Harper RJ, Okom AEA, Stilwell AT, Tibbett M, Dean C, George SJ, Sochacki SJ, Mitchell CD, Mann SS, Dods K (2012) Reforesting degraded agricultural landscapes with Eucalypts: effects on soil carbon storage and soil fertility after 26 years. Agriculture, Ecosystems & Environment 163, 3–13.
| Reforesting degraded agricultural landscapes with Eucalypts: effects on soil carbon storage and soil fertility after 26 years.Crossref | GoogleScholarGoogle Scholar |
Harper RJ, Sochacki SJ, Smettem KRJ, Robinson N (2014) Managing water in agricultural landscapes with short-rotation biomass plantations. GCB Bioenergy 6, 544–555.
| Managing water in agricultural landscapes with short-rotation biomass plantations.Crossref | GoogleScholarGoogle Scholar |
Henry DJ, Lukey CA, Evans E, Yarovsky I (2005) Theoretical study of adhesion between graphite, polyester and silica surfaces. Molecular Simulation 31, 449–455.
| Theoretical study of adhesion between graphite, polyester and silica surfaces.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXmtlSrt7k%3D&md5=d1f344d15f8bb515ab832ac048da4c4aCAS |
Henry DJ, Evans E, Yarovsky I (2006) Classical molecular dynamics study of [60]fullerene interactions with silica and polyester surfaces. The Journal of Physical Chemistry B 110, 15963–15972.
| Classical molecular dynamics study of [60]fullerene interactions with silica and polyester surfaces.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD28Xntl2gsLk%3D&md5=a208e0ad6ad542dd23d8b9e56ff5b31fCAS | 16898752PubMed |
Isbell RF (1996) ‘The Australian Soil Classification System.’ (CSIRO Publishing: Melbourne)
Jackson RB, Jobbágy EG, Avissar R, Roy SB, Barrett DJ, Cook CW, Farley KA, le Maitre DC, McCarl BA, Murray BC (2005) Trading water for carbon with biological carbon sequestration. Science 310, 1944–1947.
| Trading water for carbon with biological carbon sequestration.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2MXhtlagurrF&md5=3cfaa62cb1524268647dd388f549c30eCAS | 16373572PubMed |
King PM (1981) Comparison of methods for measuring severity of water repellence of sandy soils and assessment of some factors that affect its measurement. Australian Journal of Soil Research 19, 275–285.
| Comparison of methods for measuring severity of water repellence of sandy soils and assessment of some factors that affect its measurement.Crossref | GoogleScholarGoogle Scholar |
Mainwaring K, Hallin IL, Douglas P, Doerr SH, Morley CP (2013) The role of naturally occurring organic compounds in causing soil water repellency. European Journal of Soil Science 64, 667–680.
| The role of naturally occurring organic compounds in causing soil water repellency.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXhsFGgsbnM&md5=668785c75e1f8f6497bdf464f235f409CAS |
McGhie DA (1980) The contribution of the Mallet Hill surface to run-off and erosion in the Narrogin region of Western Australia. Australian Journal of Soil Research 18, 299–307.
| The contribution of the Mallet Hill surface to run-off and erosion in the Narrogin region of Western Australia.Crossref | GoogleScholarGoogle Scholar |
McGhie DA, Posner AM (1980) Water repellence of a heavy-textured Western Australian surface soil. Australian Journal of Soil Research 18, 309–323.
| Water repellence of a heavy-textured Western Australian surface soil.Crossref | GoogleScholarGoogle Scholar |
McKissock I, Gilkes RJ, Van Bronswijk W (2003) The relationship of soil water repellency to aliphatic C and kaolin measured using DRIFT. Australian Journal of Soil Research 41, 251–265.
| The relationship of soil water repellency to aliphatic C and kaolin measured using DRIFT.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXktFKisrs%3D&md5=10d11299a08b411c6b34da9dec7308dfCAS |
Mendham DS, Mathers NJ, O’Connell AM, Grove TS, Saffigna PG (2002a) Impact of land-use on soil organic matter quality in south-western Australia—characterization with 13C CP/MAS NMR spectroscopy. Soil Biology & Biochemistry 34, 1669–1673.
| Impact of land-use on soil organic matter quality in south-western Australia—characterization with 13C CP/MAS NMR spectroscopy.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD38Xps12ltLw%3D&md5=f373c84a3551eb88345a027726736019CAS |
Mendham DS, O’Connell AM, Grove TS (2002b) Organic matter characteristics under native forest, long-term pasture, and recent conversion to Eucalyptus plantations in Western Australia: microbial biomass, soil respiration, and permanganate oxidation. Australian Journal of Soil Research 40, 859–872.
| Organic matter characteristics under native forest, long-term pasture, and recent conversion to Eucalyptus plantations in Western Australia: microbial biomass, soil respiration, and permanganate oxidation.Crossref | GoogleScholarGoogle Scholar |
Mendham DS, O’Connell AM, Grove TS (2003) Change in soil carbon after land clearing or afforestation in highly weathered lateritic and sandy soils of south-western Australia. Agriculture, Ecosystems & Environment 95, 143–156.
| Change in soil carbon after land clearing or afforestation in highly weathered lateritic and sandy soils of south-western Australia.Crossref | GoogleScholarGoogle Scholar |
Mendham DS, Heagney EC, Corbeels M, O’Connell AM, Grove TS, McMurtrie RE (2004) Soil particulate organic matter effects on nitrogen availability after afforestation with Eucalyptus globulus. Soil Biology & Biochemistry 36, 1067–1074.
| Soil particulate organic matter effects on nitrogen availability after afforestation with Eucalyptus globulus.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2cXltVKiu78%3D&md5=8d3821bfb5291336c336f3c76d8c0410CAS |
Mendham DS, White DA, Battaglia M, McGrath JF, Short TM, Ogden GN, Kinal J (2011) Soil water depletion and replenishment during first- and early second-rotation Eucalyptus globulus plantations with deep soil profiles. Agricultural and Forest Meteorology 151, 1568–1579.
| Soil water depletion and replenishment during first- and early second-rotation Eucalyptus globulus plantations with deep soil profiles.Crossref | GoogleScholarGoogle Scholar |
Mitchell CD, Harper RJ, Keenan RJ (2012) Status and prospects of carbon forestry in Australia. Australian Forestry 75, 200–212.
| Status and prospects of carbon forestry in Australia.Crossref | GoogleScholarGoogle Scholar |
O’Connell AM, Grove TS, Mendham DS, Rance SJ (2003) Changes in soil N status and N supply rates in agricultural land afforested with eucalypts in south-western Australia. Soil Biology & Biochemistry 35, 1527–1536.
| Changes in soil N status and N supply rates in agricultural land afforested with eucalypts in south-western Australia.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD3sXosVyitLk%3D&md5=1d039fbc30728f1d5d38703274b917e2CAS |
Payne WA (2010) Are biofuels antithetic to long-term sustainability of soil and water resources? Advances in Agronomy 105, 1–46.
| Are biofuels antithetic to long-term sustainability of soil and water resources?Crossref | GoogleScholarGoogle Scholar |
Prosser IP, Williams L (1998) The effect of wildfire on runoff and erosion in native Eucalyptus forest. Hydrological Processes 12, 251–265.
| The effect of wildfire on runoff and erosion in native Eucalyptus forest.Crossref | GoogleScholarGoogle Scholar |
Rayment GE, Higginson FR (1992) ‘Australian laboratory handbook of soil and water chemical methods.’ (Inkata Press: Melbourne)
Roberts FJ, Carbon BA (1972) Water repellence in sandy soils of south-western Australia. II. Some chemical characteristics of the hydrophobic skins. Australian Journal of Soil Research 10, 35–42.
| Water repellence in sandy soils of south-western Australia. II. Some chemical characteristics of the hydrophobic skins.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaE38XhsFanu7s%3D&md5=ec9870b6273bde1b94425aaea4949a38CAS |
Rodríguez-Alleres M, Benito E (2011) Spatial and temporal variability of surface water repellency in sandy loam soils of NW Spain under Pinus pinaster and Eucalyptus globulus plantations. Hydrological Processes 25, 3649–3658.
| Spatial and temporal variability of surface water repellency in sandy loam soils of NW Spain under Pinus pinaster and Eucalyptus globulus plantations.Crossref | GoogleScholarGoogle Scholar |
Roper MM, Ward PR, Kuelen AF, Hill JR (2013) Under no-tillage and stubble retention, soil water content and crop growth are poorly related to soil water repellency. Soil & Tillage Research 126, 143–150.
| Under no-tillage and stubble retention, soil water content and crop growth are poorly related to soil water repellency.Crossref | GoogleScholarGoogle Scholar |
Scarlat N, Dallemand J (2011) Recent developments of biofuels/bioenergy sustainability certification: A global overview. Energy Policy 39, 1630–1646.
| Recent developments of biofuels/bioenergy sustainability certification: A global overview.Crossref | GoogleScholarGoogle Scholar |
Shakesby RA (2011) Post-wildfire soil erosion in the Mediterranean: Review and future research directions. Earth-Science Reviews 105, 71–100.
| Post-wildfire soil erosion in the Mediterranean: Review and future research directions.Crossref | GoogleScholarGoogle Scholar |
Shakesby RA, Doerr SH, Walsh RPD (2000) The erosional impact of soil hydrophobicity: current problems and future research directions. Journal of Hydrology 231–232, 178–191.
| The erosional impact of soil hydrophobicity: current problems and future research directions.Crossref | GoogleScholarGoogle Scholar |
Shakesby RA, Wallbrink PJ, Doerr SH, English PM, Chafer CJ, Humphreys GS, Blake WH, Tomkins KM (2007) Distinctiveness of wildfire effects on soil erosion in south-east Australian eucalypt forests assessed in a global context. Forest Ecology and Management 238, 347–364.
| Distinctiveness of wildfire effects on soil erosion in south-east Australian eucalypt forests assessed in a global context.Crossref | GoogleScholarGoogle Scholar |
Sochacki SJ, Harper RJ, Smettem KRJ, Dell B, Wu H (2013) Evaluating a sustainability index for nutrients in a short rotation energy cropping system. GCB Bioenergy 5, 315–326.
| Evaluating a sustainability index for nutrients in a short rotation energy cropping system.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BC3sXosVKltro%3D&md5=a8d50a196cf41237f4faea1f7ef70e43CAS |
Squires V, Tow PG (1991) ‘Dryland farming: A systems approach. An analysis of dryland agriculture in Australia.’ (Sydney University Press: Sydney)
Sun H (1998) COMPASS: An ab initio force-field optimized for condensed-phase applications—overview with details on alkane and benzene compounds. The Journal of Physical Chemistry B 102, 7338–7364.
| COMPASS: An ab initio force-field optimized for condensed-phase applications—overview with details on alkane and benzene compounds.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK1cXlslart7g%3D&md5=9b27f627dc19348259fa137e735258e9CAS |
Townsend PV, Harper RJ, Brennan PD, Dean C, Wu S, Smettem KRJ, Cook SE (2012) Multiple environmental services as an opportunity for watershed restoration. Forest Policy and Economics 17, 45–58.
| Multiple environmental services as an opportunity for watershed restoration.Crossref | GoogleScholarGoogle Scholar |
Wallis MG, Horne DJ (1992) Soil water repellency. Advances in Soil Science 20, 91–146.
| Soil water repellency.Crossref | GoogleScholarGoogle Scholar |
Witter JV, Jungerius PD, ten Harkel MJ (1991) Modelling water erosion and the impact of water repellency. Catena 18, 115–124.
| Modelling water erosion and the impact of water repellency.Crossref | GoogleScholarGoogle Scholar |
Wu H, Fu Q, Giles R, Bartle J (2008) Production of mallee biomass in Western Australia: energy balance analysis. Energy & Fuels 22, 190–198.
| Production of mallee biomass in Western Australia: energy balance analysis.Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DC%2BD2sXhtVOns7fK&md5=48e12eff333280c723a7ab2d8e928c59CAS |