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RESEARCH ARTICLE
Contents Vol 42(7)

Biological and chemical assays to estimate nitrogen supplying power of soils with contrasting management histories

D. Curtin A B and F. M. McCallum A
+ Author Affiliations
- Author Affiliations

A New Zealand Institute for Crop and Food Research Limited, Private Bag 4704, Christchurch, New Zealand.

B Corresponding author. Email: curtind@crop.cri.nz

Australian Journal of Soil Research 42(7) 737-746 https://doi.org/10.1071/SR03158
Submitted: 14 November 2003  Accepted: 27 April 2004   Published: 12 November 2004

Abstract

Nitrogen (N) mineralised from soil organic matter can be an important source of N for crop uptake, particularly following cultivation of pastures. Difficulty in predicting the contribution of mineralisation continues to be a serious obstacle to implementating best management practices for fertiliser N. We evaluated biological tests (i.e. net N mineralised in a 28-day aerobic incubation and anaerobically mineralisable N, AMN) and chemical tests (ammonium-N hydrolysis in hot 2 m KCl) as predictors of N supply to a glasshouse-grown oat (Avena sativa L.) crop. The oat plants were grown to maturity without added N on 30 soils representing a range of management histories, including soils collected from long-term pastures and intensive arable cropping sites. The majority (average 83%) of the N accumulated in grain and straw was mineralised N. Plant N derived from mineralisation (PNDM), estimated by subtracting soil mineral N at sowing from N uptake, was generally higher for long-term pasture soils (mean 82 mg/kg, n = 9) than for long-term arable soils (mean 48 mg/kg, n = 9). The 2 measures of N mineralisation were not closely related [R2 = 0.11 (0.37*** when one outlying observation was omitted)], indicating that aerobic and anaerobic assays can give quite different N fertility rankings. Aerobically mineralisable N was the best predictor of PNDM (R2 = 0.79***). The ratio of CO2-C evolved to net N mineralised in the aerobic incubation was highly variable (e.g. mean of 13.6 for pasture soils v. 7.5 for long-term arable soils), likely due to differences in N immobilisation. The correlations of AMN (R2 = 0.32**) and hot KCl N (R2 = 0.24**) with PNDM were not much better than that between total soil N and PNDM (R2 = 0.16*), suggesting that these tests would not provide reliable estimates of N mineralisation potential in soils with diverse management histories.

Additional keywords: N mineralisation, plant N uptake, hot KCl-extractable N, microbial biomass, N immobilisation, incubation assays.


Acknowledgments

Funding for this work was provided by the Foundation for Research, Science and Technology (contracts C02X0024 and C020218) and the New Zealand Fertiliser Manufacturers’ Research Association. We thank Charles Wright for technical assistance and Ruth Butler for statistical advice.


References


Beare MH, Cabrera ML, Hendrix PF, Coleman DC (1994) Aggregate-protected and unprotected organic matter pools in conventional- and no-tillage soils. Soil Science Society of America Journal 58, 787–795. open url image1

Campbell CA, Jame YW, Akinremi OO, Beckie HJ (1994) Evaluating potential nitrogen mineralization for predicting fertilizer nitrogen requirements of long-term field experiments. ‘Soil testing: Prospects for improving nutrient recommendations’. pp. 81–100. (Soil Science Society of America: Madison, WI)

Cornforth, I (1998). (‘Practical soil management’. (Lincoln University Press: Lincoln, New Zealand)

Curtin D, Wen G (1999) Organic matter fractions contributing to soil nitrogen mineralization potential. Soil Science Society of America Journal 63, 410–415. open url image1

Fox RH, Piekielek WP (1984) Relationships among anaerobically mineralized nitrogen, chemical indexes, and nitrogen availability to corn. Soil Science Society of America Journal 48, 1087–1090. open url image1

Francis GS, Tabley FJ, White KM (2001) Soil degradation under cropping and its effect on wheat yield on a weakly structured New Zealand silt loam. Australian Journal of Soil Research 39, 291–305.
Crossref | GoogleScholarGoogle Scholar | open url image1

Franzluebbers AJ, Haney RL, Hons FM, Zuberer DA (1996) Determination of microbial biomass and nitrogen mineralization following rewetting of dried soil. Soil Science Society of America Journal 60, 1133–1139. open url image1

Gianello C, Bremner JM (1986) Comparison of chemical methods of assessing potentially available nitrogen in soils. Communications in Soil Science and Plant Analysis 17, 215–236. open url image1

Goh KM (1983) Predicting nitrogen requirements for arable farming: a critical review and appraisal. Proceedings of the Agronomy Society of New Zealand 13, 1–14. open url image1

Haynes RJ (1991) Influence of mixed cropping rotations (pasture-arable) on organic matter content, water stable aggregation and clod porosity in a group of soils. Soil and Tillage Research 19, 77–87.
Crossref | GoogleScholarGoogle Scholar | open url image1

Horwath WR, Paul EA (1994) Microbial biomass. ‘Methods of soil analysis. Part 2. Microbiological and biochemical properties’. (Ed. RW Weaver) pp. 753–773. (Soil Science Society of America: Madison, WI)

Jalil A, Campbell CA, Schoenau J, Henry JL, Jame YW, Lafond GP (1996) Assessment of two chemical extraction methods as indices of available nitrogen. Soil Science Society of America Journal 60, 1954–1960. open url image1

Jarvis SC, Stockdale EA, Shepherd MA, Powlson DS (1996) Nitrogen mineralization in temperate agricultural soils: processes and measurement. Advances in Agronomy 57, 187–235. open url image1

Kaiser K, Guggenberger G (2000) The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils. Organic Geochemistry 31, 711–725.
Crossref | GoogleScholarGoogle Scholar | open url image1

Keeney DR (1982) Nitrogen – availability indices. ‘Methods of soil analysis. Part 2’. 2nd edn(Ed. AL Page .) pp. 711–733. (American Society of Agronomy and Soil Science Society of America: Madison, WI)

Keeney DR, Bremner JM (1966) Comparison and evaluation of laboratory methods of obtaining an index of soil nitrogen availability. Agronomy Journal 58, 498–503. open url image1

Kumar K, Goh KM (2000) Crop residues and management practices: effects on soil quality, soil nitrogen dynamics, crop yield, and nitrogen recovery. Advances in Agronomy 68, 197–319. open url image1

Ledgard SF, Jarvis SC, Hatch D (1998) Short-term nitrogen fluxes in grassland soils under different long-term nitrogen management regimes. Soil Biology and Biochemistry 30, 1233–1241.
Crossref | GoogleScholarGoogle Scholar | open url image1

Metherell AK, Stevenson K, Risk WH, Baird AD (1989) MAF soil fertility service nitrogen index and nitrogen recommendations for cereal crops. ‘Workshop on Nitrogen in New Zealand Agriculture and Horticulture’. Massey University, Palmerston North. Massey University Occasional Report No. 3.

Myrold DD (1987) Relationship between microbial biomass nitrogen and a nitrogen availability index. Soil Science Society of America Journal 51, 1047–1049. open url image1

Olsen SR, Cole CV, Watanabe FS, Dean LA (1954) Estimation of available phosphate in soils by extraction with sodium bicarbonate. United States Department of Agriculture, Circular 939, Washington, DC.

Orbell GE (1974) Soils of the government horticultural research areas, Pukekohe, New Zealand. New Zealand Soil Bureau, Department of Scientific and Industrial Research, Wellington.

Paul KI, Polglase PJ, O'Connell AM, Carlyle JC, Smethurst PJ, Khanna PK (2002) Soil nitrogen availability predictor (SNAP): a simple model for predicting mineralisation of nitrogen in forest soils. Australian Journal of Soil Research 40, 1011–1026. open url image1

Ponnamperuma FN (1972) The chemistry of submerged soils. Advances in Agronomy 24, 29–96. open url image1

Ross DJ (1991) Microbial biomass in a stored soil: a comparison of different estimation procedures. Soil Biology and Biochemistry 23, 1005–1007.
Crossref | GoogleScholarGoogle Scholar | open url image1

Saggar S, Yeates GW, Shepherd TG (2001) Cultivation effects on soil biological properties, microfauna and organic matter dynamics in Eutric Gleysol and Gleyic Luvisol soils in New Zealand. Soil and Tillage Research 58, 55–68.
Crossref | GoogleScholarGoogle Scholar | open url image1

Selles F, Campbell CA, McConkey BG, Brandt SA, Messer D (1999) Relationships between biological and chemical measures of N supplying power and total N at field scale. Canadian Journal of Plant Science 79, 353–366. open url image1

Stanford G, Smith SJ (1972) Nitrogen mineralization potentials of soils. Soil Science Society of America Proceedings 36, 465–472. open url image1

Stenger R, Priesack E, Beese F (1995) Rates of net nitrogen mineralisation in disturbed and undisturbed soils. Plant and Soil 171, 323–332. open url image1

Tabatabai MA (1982) Sulfur. ‘Methods of soil analysis. Part 2’. 2nd edn(Ed. AL Page) pp. 501–538. (American Society of Agronomy and Soil Science Society of America: Madison, WI)

Thicke FE, Russelle MP, Hesterman OB, Sheaffer CC (1993) Soil nitrogen mineralization indexes and corn response in crop rotations. Soil Science 156, 322–335. open url image1

Vance ED, Brookes PC, Jenkinson DS (1987) An extraction method for measuring microbial biomass C. Soil Biology and Biochemistry 19, 703–707.
Crossref | GoogleScholarGoogle Scholar | open url image1

Wang W, Smith CJ, Chalk PM, Chen D (2001) Evaluating chemical and physical indices of nitrogen mineralization capacity with an unequivocal reference. Soil Science Society of America Journal 65, 368–376. open url image1