Soil aggregate size distribution and total organic carbon in intra-aggregate fractions as affected by addition of biochar and organic amendments

George O. Odugbenro, Zhihua Liu, Yankun Sun

Abstract


A two-year field trial on maize (Zea mays L.) production was established to determine the influence of biochar, maize straw, and poultry manure on soil aggregate stability, aggregate size distribution, total organic carbon (TOC), and soil microbial biomass carbon (MBC). Seven treatments with four replications, namely CK, control; S, 12.5 Mg ha-1 straw; B1, 12.5 Mg ha-1 biochar; B2, 25 Mg ha-1 biochar; SB1, straw + 12.5 Mg ha-1 biochar; SB2, straw + 25 Mg ha-1 biochar; and M, 25 Mg ha-1 manure were tested at four soil depths (0–10, 10–20, 20–30, and 30–40 cm). Aggregates were grouped into large macro-aggregates (5–2 mm), small macro-aggregates (2–0.25 mm), micro-aggregates (0.25–0.053 mm) and silt + clay (<0.053 mm). Biochar, straw, and manure applications all had significant effects (p < 0.05) on aggregate stability, with B2 at 20 cm soil depth showing the greatest increase (62.1%). SB1 of small macro-aggregate fraction showed the highest aggregate proportion (50.59% ± 10.48) at the 20–30 cm soil depth. The highest TOC was observed in SB2  (40.9 g kg-1) of large macro-aggregate at 10–20 cm soil depth. Treatment effects on soil MBC was high, with B1 showing the greatest value (600.0 µg g-1) at the 20–30 cm soil depth. Our results showed that application of biochar, straw, and manure to soil increased aggregate stability, TOC as well as MBC.


Keywords


biochar; aggregate stability; aggregate size distribution; microbial biomass carbon; total organic carbon

Full Text:

PDF

References


Abdelhafez, A., Li, J., Abbas, M.H.H., 2014. Feasibility of biochar manufactured from organic wastes on the stabilization of heavy metals in a metal smelter contaminated soil. Chemosphere, 117, 66–71.

An, T., Schaeffer, S., Zhuang, J., Radosevich, M., Li, S., Li, H., Pei, J., Wang, J., 2015. Dynamics and distribution of 13C-labeled straw carbon by microorganisms as affected by soil fertility levels in the Black Soil region of Northeast China. Biol. Fertil. Soils. 51, 605–613.

Biederman, L.A., Harpole, W.S., 2013. Biochar and its effects on plant productivity and nutrient cycling: a meta-analysis. GCB Bioenergy, 5 (2), 202–214.

Blanco-Canqui, H., Francis, C.A., Galusha, T.D., 2017. Does organic farming accumulate carbon in deeper soil profiles in the long term? Geoderma, 288, 213–221.

Chaudhary, V., Bowker, M., O’dell, T., Grace, J., Redman, A., Rillig, M., Johnson, N., 2009. Untangling the biological contributions to soil stability in semiarid shrublands. Ecol. Applns. 19, 110–122.

Cheng, M., Xiang, Y., Xue, Z.J., An, S.S., Darboux, F., 2015. Soil aggregation and intra-aggregate carbon fractions in relation to vegetation succession on the Loess Plateau, China. Catena, 124, 77–84.

Chenu, C., 1989. Influence of a fungal polysaccharide scleroglucan, on clay microstructures. Soil Biology and Biochemistry, 21, 299–305.

Christensen, B.T., 2001. Physical fractionation of soil and structural and functional complexity in organic matter turnover. European Journal of Soil Science, 52, 345–353.

Demisie, W., Liu, Z., Zhang, M., 2014. Effect of biochar on carbon fractions and enzyme activity of red soil. Catena, 121, 214–221.

Domingo-Olive, F., Bosch-Serra, A.D., Yague, M.R., Poch, R.M., Boixadera, J., 2016. Long term application of dairy cattle manure and pig slurry to winter cereals improve soil quality. Nutrient Cycling in Agroecosystems, 104, 39–51.

Duchicela, J., Sullivan, T., Bontti, E., Bever, J., 2013. Soil aggregate stability increase is strongly related to fungal community succession along an abandoned agricultural field chronosequence in the Bolivian Altiplano. Journal of Applied Ecology, 50, 1266–1273.

Duchicela, J., Vogelsang, K., Schultz, P., Kaonongbua, W., Middleton, E., Bever, J., 2012. Non-native plants and soil microbes: potential contributors to the consistent reduction in soil aggregate stability caused by the disturbance of North American grasslands. New Phytologist, 196, 212–222.

Elliott, E.T., 1986. Aggregate structure and carbon, nitrogen, and phosphorus in native and cultivated soils. Soil Science Society of America Journal, 50, 627–633.

Enders, A., Hanley, K., Whitman, T., Joseph, S., Lehmann, J., 2012. Characterization of biochars to evaluate recalcitrance and agronomic performance. Bioresour.Technol., 114: 644–653.

Gentile, R., Vanlauwe, B., Kavoo, A., Chivenge , P., Six, J., 2010. Residue quality and N fertilizer do not influence aggregate stabilization of C and N in two tropical soils with contrasting texture. Nutr. Cycl. Agroecosyst., 88, 121–131.

Gioacchini, P., Cattaneo, F., Barbanti, L., Montecchio, D., Ciavatta, C., Marzadori, C., 2016. Carbon sequestration and distribution in soil aggregate fractions under Miscanthus and giant reed in the Mediterranean area. Soil and Tillage Research 163, 235–242.

Guan, S., Dou, S., Chen, G., Wang, G., Zhuang, J., 2015. Isotopic characterization of sequestration and transformation of plant residue carbon in relation to soil aggregation dynamics. Applied Soil Ecology, 96, 18–24.

Guggenberger, G., Zech, W., Haumaie, L., Christensen, B.T., 1995. Land-use effects on the composition of organic matter in particle size separates of soils: II. CPMAS and solution 13C NMR analysis. European Journal of Soil Science, 46, 147–158.

Hao, X., Yang, C., Yuan, Y., Han, X., Li, L., Jiang, H., 2013. Effects of continuous straw returning on organic carbon content in aggregates and fertility of black soil. Chinese Agriculture Science Bulletin, 29 (35), 263–269.

Hartley, W., Riby, P., Waterson, J., 2016. Effects of three different biochars on aggregate stability, organic carbon motility and micronutrient bioavailability. Journal of Environmental Management, 181, 770–778.

Helfrich, M., Ludwig, B., Potthoff, M., Flessa H., 2008. Effect of litter quality and soil fungi on macroaggregate dynamics and associated partitioning of litter carbon and nitrogen. Soil Biology and Biochemistry, 40, 1823–1835.

Jien, S.H., Wang, C.S., 2013. Effects of biochar on soil properties and erosion potential in a highly weathered soil. Catena, 110, 225–233.

Kinsbursky R.S., Levanon D., Yaron B., 1989. Role of fungi in stabilizing aggregates of sewage sludge Amended soils. Soil Science Society of America Journal, 53, 1086–1091.

Le Guillou, C., Angers, D.A., Maron, P.A., Leterme, P., Menasseri-Aubry, S., 2012. Linking microbial community to soil water-stable aggregation during crop residue decomposition. Soil Biology and Biochemistry, 50, 126–133.

Lehmann, J., Joseph, S., 2009. Biochar for environmental management: an introduction. In: J. Lehmann, S. Joseph (Eds.), Biochar for Environmental Management-Science and Technology. Earthscan, Sterling, VA. pp. 1–12.

Lehmann, J., Rillig, M.C., Thies, J., Masiello, C.A., Hockaday, W.C., 2011. Biochar effects on soil biota – A review. Soil Biology and Biochemistry, 43, 1812–1836.

Liu, Z., Chen, X., Jing, Y., Li, Q., Zhang, J., Huang, Q., 2014. Effects of biochar amendment on rapeseed and sweet potato yields and water stable aggregate in upland red soil. Catena, 123, 45–51.

Ma, N., Zhang, L., Zhang, Y., Yang, L., Yu, C., Yin, G. et al., 2016. Biochar Improves Soil Aggregate Stability and Water Availability in a Mollisol after Three Years of Field Application. PLoS ONE, 11 (5), e0154091.

Nimmo, J.R., 2004. Aggregation. Physical aspects, in Hillel D., ed., Encyclopedia of Soils in the Environment: London, Academic Press.

Nyamangara, J., Gotosa, J., Mpofu, S.E., 2001. Cattle manure effects on structural stability and water retention capacity of a granitic sandy soil in Zimbabwe. Soil and Tillage Research, 62: 157–162

Obia, A., Mulder, J., Martinsen, V., Cornelissen, G., Børresen, T., 2016. In situ effects of biochar on aggregation, water retention and porosity in light-textured tropical soils. Soil and Tillage Research, 155, 35–44.

Odugbenro, G.O., Liu, Z., Sun, Y., 2019. Dynamics of C and N in a clay loam soil amended with biochar and corn straw. Indian Journal ofAgricultural Research, 53(6): 675–680.

Papadopoulos, A., Bird, N.R.A., Whitmore, A.P., Mooney, S.J., 2009. Investigating the effects of organic and conventional management on soil aggregate stability using X-ray computed tomography. European Journal of Soil Science, 60 (3), 360–368.

Poirier, V., Angers, D.A., Whalen, J.K., 2014. Formation of millimetric-scale aggregates and associated retention of 13C – 15N-labelled residues are greater in subsoil than topsoil. Soil Biology and Biochemistry, 75, 45–53.

Portella, C., Guimarães, M., Feller, C., Batista Fonseca, I., Tavares Filho, J., 2012. Soil aggregation under different management systems. Revista Brasileira de Ciência do Solo, 36, 1868-1877 (in Portuguese, with abstract in English).

Qian, K., Kumar, A., Zhang, H., Bellmer, D., Huhnke, R., 2015. Recent advances in utilization of biochar. Renewable and Sustainable Energy Reviews, 42, 1055–1064.

Regelink, I.C., Stoof ,C.R., Roueeeva, S., Weng, L.P., Lair, G.J., Kram, P., Comans, R.N.J. et al., 2015. Linkages between aggregate formation, porosity and soil chemical properties. Geoderma, 247-248, 24–37.

Six, J., Bossuyt, H., Degryze, S., Denef, K., 2004. A history of research on the link between (micro) aggregates, soil biota, and soil organic matter dynamics. Soil and Tillage Research, 79, 7–31.

Six, J., Elliott, E.T., Paustian, K., 2000. Soil structure and soil organic matter: II: a normalized stability index and the effect of mineralogy. Soil Science Society of America Journal, 64, 1042–1049.

Sun, F, Lu, S., 2013. Biochars improve aggregate stability, water retention, and porespace properties of clayey soil. Journal of Plant Nutrition and Soil Science, 177: 26–33.

Tisdall, J.M., Oades, J.M., 1982. Organic matter and water stable aggregates in soils. Journal of Soil Science, 33, 141–163.

USDA Natural Resources Conservation Service., 1999. Soil Taxonomy: A Basic System of Soil Classification for Making and Interpreting Soil Surveys. Agriculture Handbook, No 436.

USDA Natural Resources Conservation Service., 2008. Soil Quality Indicators: Aggregate Stability.

Vance, E.D., Brookes, P.C., Jenkinson, D.S., 1987. An Extraction Method for Measuring Soil Microbial Biomass C. Soil Biology and Biochemistry, 19, 703–707.

Verchot, L.V., Dutaur, L., Shepherd, K.D., Albrecht, A., 2011. Organic matter stabilization in soil aggregates: understanding the biogeochemical mechanisms that determine the fate of carbon inputs in soils. Geoderma, 161, 182–193.

Wang, T., Camps Arbestain, M., Hedley, M., Bishop, P., 2012. Chemical and bioassay characterization of nitrogen availability in biochar produced from dairy manure and biosolids. Organic Geochemistry, 51, 45–54.

Zhang, Q., Du, Z., Lou, Y., He, X., 2015. A one-year short-term biochar application improved carbon accumulation in large macro-aggregate fractions. Catena, 127: 26–31.

Zhang, Q-z., Dijkstra, F.A., Liu, X-r., Wang, Y-d., Huang, J., 2014. Effects of Biochar on Soil Microbial Biomass after Four Years of Consecutive Application in the North China Plain. PLoS ONE, 9 (7), e102062.




DOI: http://dx.doi.org/10.17951/pjss.2020.53.1.41
Date of publication: 2020-06-22 04:38:00
Date of submission: 2019-02-19 18:13:09


Statistics


Total abstract view - 2127
Downloads (from 2020-06-17) - PDF - 1203

Indicators



Refbacks

  • There are currently no refbacks.


Copyright (c) 2020 George Oluwaseun Odugbenro, Zhihua Liu, Yankun Sun

Creative Commons License
This work is licensed under a Creative Commons Attribution 4.0 International License.