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RESEARCH ARTICLE

Carbon sequestration in urban landscapes: the example of a turfgrass system in New Zealand

Keun Young Huh A , Markus Deurer B E , Siva Sivakumaran B , Keith McAuliffe C and Nanthi S. Bolan D
+ Author Affiliations
- Author Affiliations

A Department of Landscape Architecture, Jinju National University, 150 Chilamdong Jinju, Republic of Korea.

B Sustainable Land Use, HortResearch, Private Bag 11 030, Palmerston North, New Zealand.

C New Zealand Sports Turf Institute, PO Box 347, Palmerston North, New Zealand.

D Environmental Science, University of South Australia, SA 5095, Australia.

E Corresponding author. Email: mdeurer@hortresearch.co.nz

Australian Journal of Soil Research 46(7) 610-616 https://doi.org/10.1071/SR07212
Submitted: 27 November 2007  Accepted: 2 July 2008   Published: 8 October 2008

Abstract

Soil carbon sequestration was analysed in the topsoil (0–0.25 m) of putting greens of different ages (5, 9, 20, 30, 40 years) in a golf course in Palmerston North, New Zealand. The soil texture was the same for all putting greens and the intensive management guaranteed that the carbon (C) inputs to the soil were very similar for all ages.

Significant and linear soil C sequestration rates occurred for 40 years. The soil C sequestration rate in 0–0.25 m depth was 69 ± 8 g/m2.year over a 40-year period totalling 28 t/ha over 40 years. The relative microbial activity (dehydrogenase activity/total soil C content) representing the bioavailability of soil C decreased by about 50% over 40 years.

The C sequestration and decrease of bioavailability of soil C was much more pronounced in 0.1–0.25 m depth than in the top 0.1 m. In the top 0.1 m, very little C sequestration occurred, most probably due to the intensive soil management in this depth. We concluded that the C sequestration was mainly caused by the increasing humification of C in the undisturbed part of the soil (0.1–0.25 m depth) as was indicated by a significant decrease in the relative microbial activity. Turfgrass systems such as putting greens are well suited to sequester C in urban areas.

Additional keywords: global worming, CO2 emission, relative microbial activity, dehydrogenase activity.


Acknowledgments

This work was financially supported by New Zealand Sports Turf Institute and Jinju National University. The authors wish to thank those who contributed to the project planning and collection of data, in particular Brendan Hannan (NZSTI) and David Smith (Manawatu Golf Club). We also wish to thank Professor Mike Hedley at Institute of Natural Resources of Massey University, Dr Surinder Saggar at Landcare Research, and Dr Brent Clothier at HortResearch for supporting this work.


References


Apfelbaum SI (2007) Urban lands and carbon management. In ‘Soil carbon management: Economic, environmental and societal benefits’. (Eds JM Kimble, CW Rice, D Reed, S Mooney, RF Follet, R Lal) pp. 235–250. (CRC: New York)

Bandaranayake W, Quian YL, Parton WJ, Ojima DS, Follet RF (2003) Estimation of soil organic carbon changes in turfgrass systems using the CENTURY model. Agronomy Journal 95, 558–563. open url image1

Beard J, Green RL (1994) The role of turfgrass in environmental protection and their benefits to humans. Journal of Environmental Quality 23, 452–460. open url image1

Blakemore LC , Searle PL , Daly BK (1987) ‘Methods for chemical analysis of soils.’ (NZ Soil Bureau: Lower Hutt, New Zealand)

Bloodworth ME, Brown KW, Beard JB, Sifers SI (1993) A new look at the Texas-USGA specifications for root-zone modification. Grounds Maintenance 28, 13–21. open url image1

Burke IC, Lauenroth WK, Coffin DP (1995) Soil organic matter recovery in semiarid grasslands: Implications for the Conservation Reserve Program. Ecological Monographs 5, 793–901. open url image1

Chander K, Brookes PC (1991) Is the dehyrogenase assay invalid as a method to estimate microbial activity in copper-contaminated soils? Soil Biology & Biochemistry 23, 909–915.
Crossref | GoogleScholarGoogle Scholar | open url image1

Cole CV, Duxbury JM, Freney J, Heinemeyer O, Minami K , et al. (1997) Global estimates of potential mitigation of greenhouse gas emissions by agriculture. Nutrient Cycling in Agroecosystems 49, 221–228.
Crossref | GoogleScholarGoogle Scholar | open url image1

Edmond DB, Coles STJ (1958) Some long-term effects of fertilizers on a mown turf of browntop and Chewings fescue. New Zealand Journal of Agricultural Research 1, 665–674. open url image1

Emmons RD (1995) ‘Turfgrass science and management.’ (Delmar Publishers: New York)

Follet RF , Samson-Liebig SE , Kimble JM , Preussner EG , Waltman SW (2001) Carbon sequestration under CRP in the historic grassland soils of the USA. In ‘SSSAJ Special Publication 57’. (Ed. R Lal) pp. 27–49. (SSSA: Madison, WI)

Gebhart DL, Johnson HB, Mayeux HS, Polley HW (1994) The CRP increases in soil organic carbon. Journal of Soil and Water Conservation 49, 488–492. open url image1

Hummel NW (1993) Rationale for the revisions of the USGA green construction specifications. USGA Green Section Record 31, 7–21. open url image1

Jastrow JD, Amonette JE, Bailey VL (2007) Mechanisms controlling soil carbon turnover and their potential for enhancing carbon sequestration. Climatic Change 80, 5–23.
Crossref | GoogleScholarGoogle Scholar | open url image1

Konen ME, Jacobs PM, Burras CL, Talaga BJ, Mason JA (2002) Equations for predicting soil organic carbon using loss-on-ignition for North Central U.S. soils. Soil Science Society of America Journal 66, 1878–1881. open url image1

Kucharik CJ (2007) Impact of prairie age and soil order on carbon and nitrogen sequestration. Soil Science Society of America Journal 71, 430–441.
Crossref | GoogleScholarGoogle Scholar | open url image1

Kucharik CJ, Roth JA, Nabielski RT (2003) Statistical assessment of a paired-site approach for verification of C and N sequestration on Wisconsin Conservation Reserve Programme (CRP) land. Journal of Soil and Water Conservation 58, 58–67. open url image1

Lal R, Follet RF, Kimble JM, Cole CV (1999) Managing U.S. cropland to sequester carbon in soil. Journal of Soil and Water Conservation 54, 374–381. open url image1

Murphy JW, Field TRO, Hichey MJ (1993) Age development in sand-based turf. International Turfgrass Society Research Journal 7, 464–468. open url image1

Óhlinger R , Beck T , Heilmann B , Beese F (1996) Soil respiration. In ‘Methods in soil biology’. (Eds F Schinner, R Óhlinger, E Kandeler, R Margesin) pp. 93–110. (Springer-Verlag: Berlin)

Parton WJ, Scurlock JMO, Ojima DS, Gilmanov TG, Scholes RJ , et al. (1993) Observations and modeling of biomass and soil organic matter dynamics for the grassland biome worldwide. Global Biogeochemical Cycles 7, 785–809.
Crossref | GoogleScholarGoogle Scholar | open url image1

Post WM, Izaurralde RC, Jastrow JD, McCarl BA, Amonette JE, Bailey VL, Jardine PM, West TO, Zhou J (2004) Enhancement of carbon sequestration in US soils. Bioscience 54, 895–908.
Crossref | GoogleScholarGoogle Scholar | open url image1

Post WM, Kwon KC (2000) Soil carbon sequestration and land-use change: processes and potential. Global Change Biology 6, 317–327.
Crossref | GoogleScholarGoogle Scholar | open url image1

Potter DA, Bridges BL, Cordon FC (1985) Effect of N fertilization on earthworm and microarthropod populations in Kentucky bluegrass turf. Agronomy Journal 77, 367–372. open url image1

Potter KN, Torbert HA, Johnson HB, Tischler CR (1999) Carbon storage after long-term grass establishment on degraded soils. Soil Science 164, 718–725.
Crossref | GoogleScholarGoogle Scholar | open url image1

Quian YL, Follet RF (2002) Assessing soil carbon sequestration in turfgrass systems using long-term soil testing data. Agronomy Journal 94, 930–935. open url image1

Reeder JD, Schuman GE, Bowman RA (1998) Soil C and N changes on conservation reserve program lands in the central Great Plains. Soil & Tillage Research 47, 339–349.
Crossref | GoogleScholarGoogle Scholar | open url image1

Sa JCD, Cerri CC, Dick WA, Lal R, Venske SP, Piccolo MC, Feigl BE (2001) Organic matter dynamics and carbon sequestration rates for a tillage chronosequence in a Brazilian Oxisol. Soil Science Society of America Journal 65, 1486–1499. open url image1

Schlesinger WH (1990) Evidence from chronosequence studies for a low carbon-storage potential of soils. Nature 348, 232–234.
Crossref | GoogleScholarGoogle Scholar | open url image1

Scholes RJ, Noble IR (2001) Storing carbon on land. Science 294, 1012–1013.
Crossref | GoogleScholarGoogle Scholar | PubMed | open url image1

Smiley RW, Craven MM (1978) Fungicides in Kentucky bluegrass turf: Effects on thatch and pH. Agronomy Journal 70, 1013–1019. open url image1

Smith P, Powlson DS, Smith JU, Falloon P, Coleman K (2000) Meeting Europe’s climate change commitments: quantitative estimates of the potential for carbon mitigation by agriculture. Global Change Biology 6, 525–539.
Crossref | GoogleScholarGoogle Scholar | open url image1

Smucker AJM, Park E-J, Dorner J, Horn R (2007) Soil micropore development and contributions to soluble carbon transport within macroaggregates. Vadose Zone Journal 6, 282–290.
Crossref | GoogleScholarGoogle Scholar | open url image1

Snow JT (1993) USGA explains its new green specifications. Grounds Maintenance 28, 21–22. open url image1

Taylor DH, Williams CF, Nelson SD (1997) Water retention in root-zone soil mixtures of layered soil profiles used for sports turf. HortScience 32, 82–85. open url image1

Taylor JP, Wilson B, Mills MS, Burns RG (2002) Comparison of microbial numbers and enzymatic activities in surface soils and subsoils using various techniques. Soil Biology & Biochemistry 34, 387–401.
Crossref | GoogleScholarGoogle Scholar | open url image1