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Soil, land care and environmental research
RESEARCH ARTICLE

Decomposition of 13C and 15N labelled plant residue materials in two different soil types and its impact on soil carbon, nitrogen, aggregate stability, and aggregate formation.

Nelly Blair A C , R. D. Faulkner A , A. R. Till A and P. Sanchez B
+ Author Affiliations
- Author Affiliations

A University of New England, Armidale, NSW 2351, Australia.

B University of the Philippines Los Baños College, Laguna 4031, Philippines.

C Corresponding author. Present address: Ourfing Partnership, ‘Nioka’, 640 Booralong Rd., Armidale, NSW 2350, Australia. Email: ourfing@bigpond.com

Australian Journal of Soil Research 43(7) 873-886 https://doi.org/10.1071/SR04137
Submitted: 20 September 2004  Accepted: 19 July 2005   Published: 9 November 2005

Abstract

Increasing soil organic matter (SOM) is a major factor in overcoming soil degradation. An incubation experiment using 2 soil types (Red Clay and Black Earth) and 2 different rotations, a clover (Trifolium subterraneum)/cereal rotation and a long fallow/cereal rotation, from a long-term crop rotation trial located at Tamworth, NSW, Australia was conducted to investigate the decomposition of 3 different plant materials, medic (Medicago truncatula) (C : N = 13), rice straw (Oryza sativa) (C : N = 25) and flemingia leaf (Flemingia macrophylla) (C : N = 13), labelled with 13C and 15N. A control treatment with no added residue was also included. The impact of the residue decomposition on total organic carbon, labile carbon, total nitrogen, aggregate stability and the formation of large macro-aggregates from smaller macro-aggregates were studied. Total C (CT), stable carbon isotope composition (δ13C), total N (NT), and %15N excess were measured by catalytic combustion and an isotope ratio mass spectrophotometer, while labile C (CL) was determined by oxidation with KMnO4. Aggregate stability [mean weight diameter (MWD)] was determined by immersion wet sieving. Correlations of C fractions with MWD were also investigated. The location of the newly added plant residue materials within soil aggregates was studied using a soil aggregate eroding machine.

Loss of C from the added plant residues was highest for the medic and lowest for the flemingia, while the rice straw initially lost C at a slower rate but by 200 days was equal to the medic. The medic treatment was the only residue to lose N by gaseous loss during the experiment and it was all lost during the first 10 days. In both soils, the addition of residues increased CT and CL compared with the control treatment, with flemingia showing the greatest increase. Factors other than their C : N ratio were clearly determining C turnover.

Addition of medic residues resulted in a rapid increase in MWD in both soils in the first 10 days compared with that at the commencement of the experiment. However, this was not maintained for the 200 days by which time MWD had decreased, but it was still greater than the starting point. By contrast, the addition of flemingia leaf exhibited a slower but more sustained increase to have the highest MWD at 200 days, equal to that of the medic treatment at 10 days. There was a positive correlation of CL with MWD at 200 days for both soils. Results from the soil aggregate eroding machine showed that a higher percentage of CT was derived from added plant residues in the outer one-third of the soil aggregates than in the inner two-thirds, with the greatest difference being for the flemingia treatment. There was no difference between different residue materials in the amount of CT derived from the added residues in the inner parts of soil aggregates. These results showed that soil macro-aggregates were forming around a central old aggregate by binding of smaller aggregates to it, with products formed as a result of the breakdown of plant residues binding them together. From the results obtained, and those of other researchers, a concept of macro-aggregate formation under different agricultural systems is proposed.

Additional keywords: residue decomposition, labile carbon, soil organic matter, carbon isotope composition, soil aggregation.


Acknowledgments

This study would not have been possible without the support and funding supplied by postgraduate scholarships from the Grains Research and Development Corporation and the Australian Institute of Nuclear Science and Engineering. Our thanks go to Graham Crocker of the NSW DPI for allowing us to sample the Tamworth site. We are particularly grateful for the assistance provided by the technical staff of Agronomy and Soil Science and Environmental Engineering. We especially acknowledge the technical help provided by Leanne Lisle and Gary Cluley. We sincerely thank the staff at the Department of Environmental Research of the Austrian Research Centres, Seibesdorf, Austria, for the help and support provided by them whilst conducting the incubation experiment. We are also extremely grateful to the staff of the Soils Unit at the International Atomic Energy Agency/Food and Agriculture Laboratories at Seibesdorf, Austria, for the assistance and support they provided.


References


Aita C, Recous S, Angers DA (1997) Short-term kinetics of residual wheat straw C and N under field conditions: characterization by 13C15N tracing and soil particle size fractionation. European Journal of Soil Science 48, 283–294.
Crossref | GoogleScholarGoogle Scholar | open url image1

Amezkeka E (1999) Soil aggregate stability: a review. Journal of Sustainable Agriculture 14, 83–151.
Crossref | GoogleScholarGoogle Scholar | open url image1

Blair GJ, Lefroy RDB, Lisle L (1995) Soil carbon fractions, based on their degree of oxidation, and the development of a carbon management index for agricultural systems. Australian Journal of Agricultural Research 46, 1459–1466.
Crossref | GoogleScholarGoogle Scholar | open url image1

Blair N, Crocker GJ (2000) Crop rotation effects on soil carbon and physical fertility of two Australian soils. Australian Journal of Soil Research 38, 71–84. open url image1

Blair N, Daniel H (1996) The impact of cropping on soil aggregate stability and carbon content. In ‘ASSSI and NZSSS National Soils Conference, Oral Papers’. (ASSSI and NZSSS: Melbourne, Vic.)


Blair N, Faulkner RD, Till AR, Crocker GJ (2005) Long-term management impacts on soil C, N and physical fertility. III. Tamworth crop rotation experiment. Soil and Tillage Research , open url image1

Conteh A, Blair GJ, Lefroy RDB, Whitbread AM (1999) Labile organic carbon determined by permanganate oxidation and its relationships to other measurements of soil organic carbon. Humic Substances in the Environment Journal 1, 3–15. open url image1

Craswell ET, Waring SA (1972) Effect of grinding on the decomposition of soil organic matter II Oxygen uptake and nitrogen mineralization in virgin and cultivated soils. Soil Biology and Biochemistry 4, 435–442.
Crossref | GoogleScholarGoogle Scholar | open url image1

Dell C, Kavdir Y, Smucker AJM (2001) Management modifications of concentric gradients within soil aggregates. ‘Proceedings of the 4th Eastern Canada Soil Structure/Carbon Workshop’. Leamington, Ontario. (Ed.  WD Reynolds , CF Drury , CS Tan ) pp. 177–187. (Harrow Press: Canada)


Denef K, Six J, Bossuyt H, Frey SD, Elliot ET, Merckx R, Paustian K (2001a) Influence of dry-wet cycles on the interrelationship between aggregate, particulate organic matter and microbial community dynamics. Soil Biology and Biochemistry 33, 1599–1611.
Crossref | GoogleScholarGoogle Scholar | open url image1

Denef K, Six J, Paustian K, Merckx R (2001b) Importance of macro-aggregate dynamics in controlling soil carbon stabilization: short-term effects of physical disturbance induced by dry-wet cycles. Soil Biology and Biochemistry 33, 2145–2153.
Crossref | GoogleScholarGoogle Scholar | open url image1

FAO (1990) FAO-UNESCO soil map of the world: revised legend. World Soil Resources Report 60, FAO, Rome.

Follett RF (2001) Soil management concepts and carbon sequestration in cropland soils. Soil and Tillage Research 61, 77–92.
Crossref | GoogleScholarGoogle Scholar | open url image1

Gachengo CN, Vanlauwe B, Palm CA, Cadisch G (2004) Chemical characterisation of a standard set of organic materials. ‘Modelling nutrient management in tropical cropping systems’. ACIAR Proceedings No. 114. (Eds RJ Delve, ME Probert) pp. 48–53. (Australian Centre for International Agricultural Research: Canberra, ACT)

Heal OW, Anderson JM, Swift MJ (1997) Plant litter quality and decomposition: An historical overview. In ‘Driven by nature, plant litter quality and decomposition’. (Eds G Cadish, KE Giller) pp. 3–30. (CAB International: Wallingford, UK)

Henriksen TM, Breland TA (1999) Evaluation of criteria for describing crop residue degradability in a model of carbon and nitrogen turnover in soil. Soil Biology and Biochemistry 31, 1135–1149.
Crossref | GoogleScholarGoogle Scholar | open url image1

Karlen DL, Cambardella CA (1996) Conservation strategies for improving soil quality and organic matter storage. ‘Structure and organic matter storage in agricultural soils’. Advances in Soil Science. (Eds MR Carter, BA Stewart) pp. 395–420. (CRC Press, Inc.: Boca Raton, FL)

La Van An, Nguyen Thi Hoa Ly, Dao Thi Phuong (2002) Forages as a protein source for livestock in upland farming systems of Vietnam. Seafrad News, Southeast Asia Feed Resources and Development Network 12, 2–3. open url image1

Lowry, JB , Petheram, JR ,  and  Tangendjaja, B (1992). ‘Plants fed to village ruminants in Indonesia.’ ACIAR Technology Reports 22. (Australian Centre for International Agricultural Research: Canberra, ACT)

Martens DA (2000) Plant residue biochemistry regulates soil carbon cycling and carbon sequestration. Soil Biology and Biochemistry 32, 361–369.
Crossref | GoogleScholarGoogle Scholar | open url image1

Naidu R, McLure S, McKenzie NJ, Fitzpatrick RW (1996) Soil solution composition and aggregate stability changes caused by long-term farming at four contrasting sites in South Australia. Australian Journal of Soil Research 34, 511–527.
Crossref | GoogleScholarGoogle Scholar | open url image1

Oades JM (1993) The role of biology in the formation, stabilisation and degradation of soil structure. In ‘International Workshop on Methods of Research on Soil Structure/Soil Biota Interrelatonships’. (Eds L. Brussaard, MJ Kooistra). Geoderma 56, 377–400.
Crossref |
open url image1

Oades JM (1984) Soil organic matter and structural stability: mechanisms and implications for management. Plant and Soil 76, 310–337.
Crossref |
open url image1

Palm CA, Sanchez PA (1991) Nitrogen release from the leaves of some tropical legumes as affected by their lignin and polyphenolic contents. Soil Biology and Biochemistry 23, 83–88.
Crossref | GoogleScholarGoogle Scholar | open url image1

Plante AF, McGill WB (2002a) Soil aggregate dynamics and the retention of organic matter in laboratory-incubated soil with differing simulated tillage frequencies. Soil and Tillage Research 66, 79–92.
Crossref | GoogleScholarGoogle Scholar | open url image1

Plante AF, McGill WB (2002b) Intra-seasonal soil macro-aggregate dynamics in two contrasting field soils using a labeled tracer sphere technique. Soil Science Society of America Journal 66, 1285–1295. open url image1

Sanchez P (2002) Production of labelled plant materials to trace the fate of residue derived carbon, nitrogen and sulfur. ‘Proceedings of the International Symposium on Nuclear Techniques in Intergrated Plant Nutrient, Water and Soil Management’. Vienna, Austria, 16–20 October 2000. (Food and Agriculture Organization of the United Nations and the International Atomic Energy Agency)


Santos D, Murphy SLS, Taubner H, Smucker AJM, Horn R (1997) Uniform separation of concentric surface layers from soil aggregates. Soil Science Society of America Journal 61, 720–724. open url image1

Six J, Elliot ET, Paustian K (1999) Aggregate and soil organic matter dynamics under conventional and no-tillage systems. Soil Science Society of America Journal 63, 1350–1358. open url image1

Six J, Elliot ET, Paustian K (2000) Soil macro-aggregate turnover and microaggregate formation: a mechanism for C sequestration under no-tillage agriculture. Soil Biology and Biochemistry 32, 2099–2103.
Crossref | GoogleScholarGoogle Scholar | open url image1

Six J, Elliot ET, Paustian K, Doran JW (1998) Aggregation and soil organic matter accumulation in cultivated and native grassland soils. Soil Science Society of America Journal 62, 1367–1377. open url image1

Smucker AJM, Santos D, Kavdir Y, Paul EA (1998) Concentric gradients within stable soil aggregates. ‘Proceeding of the 16th World Congress of Soil Science’. 20–26 August 1998,. (Montpellier: France)


Swift RS (2001) Sequestration of carbon by soil. Soil Science 166, 858–871.
Crossref | GoogleScholarGoogle Scholar | open url image1

Tian G, Salako FK, Ishida F (2001) Replenishment of C, N and P in a degraded Alfisol under humid tropical conditions: effect of fallow species and litter polyphenols. Soil Science 166, 614–621.
Crossref | GoogleScholarGoogle Scholar | open url image1

Tisdall JM, Oades JM (1982) Organic matter and water-stable aggregates in soils. Journal of Soil Science 33, 141–163. open url image1

Trinsoutrot I, Jocteur Monrozier L, Cellier J, Waton H, Almercery S, Nicolardot B (2001) Assessment of the biochemical composition of oilseed rape (Brassica napus L.) 13C-labelled residues by global methods, FTIR and 13C NMR CP/MAS. Plant and Soil 234, 61–72.
Crossref | GoogleScholarGoogle Scholar | open url image1

Trinsoutrot I, Recous S, Nicolardot B (2000) C and N fluxes of decomposing 13C and 15N Brassica napus L.: effects of residue composition and N content. Soil Biology and Biochemistry 32, 1717–1730.
Crossref | GoogleScholarGoogle Scholar | open url image1

Villegas-Pangga G, Blair G, Lefroy R (2000) Measurement of decomposition and associated nutrient release from straw (Oryza sativa L.) of different rice varieties using a perfusion system. Plant and Soil 223, 1–11.
Crossref | GoogleScholarGoogle Scholar | open url image1

Whitbread AM, Lefroy RDB, Blair GJ (1998) A survey of the impact of cropping on soil physical and chemical properties in north-western New South Wales. Australian Journal of Soil Research 36, 669–681.
Crossref | GoogleScholarGoogle Scholar | open url image1

Yoder RE (1936) A direct method of aggregate analysis of soils and a study of the physical nature of erosion losses. Journal of the American Society of Agronomy 28, 337–351. open url image1