Register      Login
Soil Research Soil Research Society
Soil, land care and environmental research
RESEARCH ARTICLE

Targeting changes in soil porosity through modification of compost size and application rate

Dirk Wallace https://orcid.org/0000-0003-2396-4550 A D , Peter Almond B , Sam Carrick C and Steve Thomas https://orcid.org/0000-0002-9202-483X A
+ Author Affiliations
- Author Affiliations

A The New Zealand Institute for Plant & Food Research, Lincoln, New Zealand.

B Agriculture and Life Sciences, Lincoln University, New Zealand.

C Manaaki Whenua Landcare Research, Lincoln, New Zealand.

D Corresponding author. Email: dirk.wallace@plantandfood.co.nz

Soil Research 58(3) 268-276 https://doi.org/10.1071/SR19170
Submitted: 21 June 2019  Accepted: 25 November 2019   Published: 18 December 2019

Abstract

The global demand to increase food production from underperforming, water and nutrient limited soils is increasing, which has resulted in an increased dependency on water for irrigation. As fresh water is a finite resource, the increase in irrigation use has resulted in competition between water used for municipal purposes and that used for food and fibre production for an increasing global population. An opportunity exists to improve the efficiency of both urban and agricultural systems by taking green waste compost generated in urban centres and incorporating it into agricultural soils with poor water retention, thereby increasing the ability of these soils to efficiently retain irrigation water for plant use and also to capture a greater volume of water from rainfall. Addition of amendments to soil changes the pore space. The magnitude and cause for this change depends on amendment type, application rate, soil type and climatic conditions. The aim of this research was to determine if the incorporation of municipal compost (MC) can increase the quantity (total volume) and concentration (total volume per unit volume) of soil pores that hold readily available water (defined as macro-mesopores of 30–3 μm diameter) and plant available water (defined as mesopores of 30–0.3 μm diameter). We hypothesised that increases in total porosity would be positively correlated with MC application rate and increases in water holding porosity (macro-mesoporosity and mesoporosity) would be positively correlated with decreasing MC particle size due to the creation of inter-particle pore spaces < 30 μm in diameter. The MC was screened to three different maximum particle sizes – MC4 (<4 mm), MC2 (<2 mm) and MC0.25 (<0.25 mm) – and incorporated into repacked soil cores at five different rates: 0, 5, 25, 50 and 80% wt/wt. Incorporation of MC0.25 increased the concentration and quantity of macro-mesopores and mesopores at significantly lower application rates than MC4 and MC2. The finding that modification of MC particle size can produce targeted changes in inter-particle porosity suggests that this practice has potential to remediate hydraulic limitations of soils.

Additional keywords: municipal compost, pore volume, porosity, soil, water.


References

Aggelides SM, Londra PA (2000) Effects of compost produced from town wastes and sewage sludge on the physical properties of a loamy and a clay soil. Bioresource Technology 71, 253–259.
Effects of compost produced from town wastes and sewage sludge on the physical properties of a loamy and a clay soil.Crossref | GoogleScholarGoogle Scholar |

Burt CM, Clemmens AJ, Strelkoff TS, Solomon KH, Bliesner RD, Hardy LA, Howell TA, Eisenhauer DE (1997) Irrigation performance measures: efficiency and uniformity. Journal of Irrigation and Drainage Engineering 123, 423–442.
Irrigation performance measures: efficiency and uniformity.Crossref | GoogleScholarGoogle Scholar |

Carter MR, Sanderson JB, MacLeod JA (2004) Influence of compost on the physical properties and organic matter fractions of a fine sandy loam throughout the cycle of a potato rotation. Canadian Journal of Soil Science 84, 211–218.
Influence of compost on the physical properties and organic matter fractions of a fine sandy loam throughout the cycle of a potato rotation.Crossref | GoogleScholarGoogle Scholar |

Chang C, Ellert B, Hao X, Clayton G (2007) Elevation-based soil sampling to assess temporal changes in soil constituents. Soil Science Society of America Journal 71, 424–429.
Elevation-based soil sampling to assess temporal changes in soil constituents.Crossref | GoogleScholarGoogle Scholar |

Doublet J, Francou C, Pétraud JP, Dignac MF, Poitrenaud M, Houot S (2010) Distribution of C and N mineralization of a sludge compost within particle-size fractions. Bioresource Technology 101, 1254–1262.
Distribution of C and N mineralization of a sludge compost within particle-size fractions.Crossref | GoogleScholarGoogle Scholar | 19819691PubMed |

FAO (2006) World reference base for soil resources. FAO, World Soil Resources Reports No. 103, FAO, Rome.

Foundation for Arable Research (2010) Irrigation management for cropping - a grower’s guide. FAR Focus (4). Foundation for Arable Research: Templeton, New Zealand.

Fraser PM, Curtin D, Beare MH, Meenken ED, Gillespie RN (2010) Temporal changes in soil surface elevation under different tillage systems. Soil Science Society of America Journal 74, 1743–1749.
Temporal changes in soil surface elevation under different tillage systems.Crossref | GoogleScholarGoogle Scholar |

Gradwell MW (1968) The moisture-holding properties of Waikato soils and methods of their determination. New Zealand Journal of Agricultural Research 11, 631–654.
The moisture-holding properties of Waikato soils and methods of their determination.Crossref | GoogleScholarGoogle Scholar |

Gradwell M, Birrell K (1972). Soil Bureau laboratory methods. C. Methods for physical analysis of soils in New Zealand Soil Bureau Scientific Report 10C. Department of Scientific and Industrial Research, Wellington, New Zealand.

Grafton RQ, Williams J, Perry C, Molle F, Ringler C, Steduto P, Udall B, Wheeler S, Wang Y, Garrick D (2018) The paradox of irrigation efficiency. Science 361, 748–750.
The paradox of irrigation efficiency.Crossref | GoogleScholarGoogle Scholar | 30139857PubMed |

Haug RT (1993) ‘The practical handbook of compost engineering.’ (CRC Press: Boca Raton, USA)

Haynes RJ, Belyaeva ON, Zhou YF (2015) Particle size fractionation as a method for characterizing the nutrient content of municipal green waste used for composting. Waste Management 35, 48–54.
Particle size fractionation as a method for characterizing the nutrient content of municipal green waste used for composting.Crossref | GoogleScholarGoogle Scholar | 25453318PubMed |

Hewitt AE (2010) ‘New Zealand soil classification.’ 3rd edn. Landcare Research Science Series No. 1. (Manaaki Whenua Press: Lincoln, NZ)

Khaleel R, Reddy KR, Overcash MR (1981) Changes in soil physical-properties due to organic waste applications - a review. Journal of Environmental Quality 10, 133–141.
Changes in soil physical-properties due to organic waste applications - a review.Crossref | GoogleScholarGoogle Scholar |

Kinney T, Masiello C, Dugan B, Hockaday W, Dean M, Zygourakis K, Barnes R (2012) Hydrologic properties of biochars produced at different temperatures. Biomass and Bioenergy 41, 34–43.
Hydrologic properties of biochars produced at different temperatures.Crossref | GoogleScholarGoogle Scholar |

Kirkham MB (2005) Field capacity, wilting point, available water, and the nonlimiting water range. In ‘Principles of soil and plant water relations’. (Ed. MB Kirkham.) pp. 101–115. (Academic Press: Burlington, USA)

Lacey K (2017) ‘Calculating readily available water.’ Government of Western Australia. Department of Primary Industries and Regional Development. Perth, Australia. Retrieved from https://agric.wa.gov.au/n/1552.

Liu ZL, Dugan B, Masiello CA, Gonnermann HM (2017) Biochar particle size, shape, and porosity act together to influence soil water properties. PLoS One 12, e0179079
Biochar particle size, shape, and porosity act together to influence soil water properties.Crossref | GoogleScholarGoogle Scholar | 28902911PubMed |

Lu DQ, Shao M, Horton R, Liu CP (2004) Effect of changing bulk density during water desorption measurement on soil hydraulic properties. Soil Science 169, 319–329.
Effect of changing bulk density during water desorption measurement on soil hydraulic properties.Crossref | GoogleScholarGoogle Scholar |

Novak JM, Busscher WJ, Watts DW, Amonette JE, Ippolito JA, Lima IM, Gaskin J, Das KC, Steiner C, Ahmedna M, Rehrah D, Schomberg H (2012) Biochars impact on soil-moisture storage in an Ultisol and two Aridisols. Soil Science 177, 310–320.
Biochars impact on soil-moisture storage in an Ultisol and two Aridisols.Crossref | GoogleScholarGoogle Scholar |

OECD (2015) ‘Environment at a glance.’ (OECD: Paris)

Pagliai M, Vignozzi N, Pellegrini S (2004) Soil structure and the effect of management practices. Soil & Tillage Research 79, 131–143.
Soil structure and the effect of management practices.Crossref | GoogleScholarGoogle Scholar |

Reynolds W, Yang X, Drury C, Zhang T, Tan C (2003) Effects of selected conditioners and tillage on the physical quality of a clay loam soil. Canadian Journal of Soil Science 83, 381–393.
Effects of selected conditioners and tillage on the physical quality of a clay loam soil.Crossref | GoogleScholarGoogle Scholar |

Schipper LA, Sparling GP (2000) Performance of soil condition indicators across taxonomic groups and land uses. Soil Science Society of America Journal 64, 300–311.
Performance of soil condition indicators across taxonomic groups and land uses.Crossref | GoogleScholarGoogle Scholar |

Sparling GP, Schipper LA (2002) Soil quality at a national scale in New Zealand. Journal of Environmental Quality 31, 1848–1857.
Soil quality at a national scale in New Zealand.Crossref | GoogleScholarGoogle Scholar | 12469834PubMed |

Stewart DPC, Cameron KC, Cornforth IS, Sedcole JR (1998) Effects of spent mushroom substrate on soil physical conditions and plant growth in an intensive horticultural system. Australian Journal of Soil Research 36, 899–912.
Effects of spent mushroom substrate on soil physical conditions and plant growth in an intensive horticultural system.Crossref | GoogleScholarGoogle Scholar |

Tester C, Sikora L, Taylor J, Parr J (1979) Decomposition of sewage sludge compost in soil: III. Carbon, nitrogen, and phosphorus transformations in different sized fractions. Journal of Environmental Quality 8, 79–82.
Decomposition of sewage sludge compost in soil: III. Carbon, nitrogen, and phosphorus transformations in different sized fractions.Crossref | GoogleScholarGoogle Scholar |

Vomocil JA (1965) Porosity. In ‘Methods of soil analysis, Part 1. Physical and mineralogical properties, including statistics of measurement and sampling.’ (Ed. CA Black.) pp. 299–314. (American Society of Agronomy: Madison, WI, USA)

VSN International (2016) ‘Genstat for Windows.’ 18th edn. (VSN International: UK)