Book contents
- BiocharA Regional Supply Chain Approach in View of Climate Change Mitigation
- Biochar
- Copyright page
- Dedication
- Contents
- Contributors
- Preface
- 1 Biochar in the View of Climate Change Mitigation: the FOREBIOM Experience
- Part I The Interdisciplinary Approach
- Part II Sustainable Biomass Resources
- Part III Biochar Production
- Part IV Biochar Application as a Soil Amendment
- 14 Biochar Applications to Agricultural Soils in Temperate Climates – More Than Carbon Sequestration?
- 15 Opportunities and Uses of Biochar on Forest Sites in North America
- 16 The Role of Mycorrhizae and Biochar in Plant Growth and Soil Quality
- 17 The Use of Stable Isotopes in Understanding the Impact of Biochar on the Nitrogen Cycle
- 18 Biochar Amendment Experiments in Thailand: Practical Examples
- Index
- Plate Section (PDF Only)
- References
16 - The Role of Mycorrhizae and Biochar in Plant Growth and Soil Quality
from Part IV - Biochar Application as a Soil Amendment
Published online by Cambridge University Press: 01 December 2016
Book contents
- BiocharA Regional Supply Chain Approach in View of Climate Change Mitigation
- Biochar
- Copyright page
- Dedication
- Contents
- Contributors
- Preface
- 1 Biochar in the View of Climate Change Mitigation: the FOREBIOM Experience
- Part I The Interdisciplinary Approach
- Part II Sustainable Biomass Resources
- Part III Biochar Production
- Part IV Biochar Application as a Soil Amendment
- 14 Biochar Applications to Agricultural Soils in Temperate Climates – More Than Carbon Sequestration?
- 15 Opportunities and Uses of Biochar on Forest Sites in North America
- 16 The Role of Mycorrhizae and Biochar in Plant Growth and Soil Quality
- 17 The Use of Stable Isotopes in Understanding the Impact of Biochar on the Nitrogen Cycle
- 18 Biochar Amendment Experiments in Thailand: Practical Examples
- Index
- Plate Section (PDF Only)
- References
Summary
Abstract
Arbuscular mycorrhizal fungi (AMF) are key organisms of the soil–plant system, and contribute to the uptake of nutrients and water. AMF also play a role in the aggregation and structural stability of soil. Biochar may provide a suitable habitat for mycorrhizal growth, which is also favorable in view of productive soils. The impact of a combination of biochar and mycorrhizae on plant growth was assessed in case studies. One of the main findings was that biochar application alone at 40 Mg ha-1 did not influence growth of citrus seedlings. However, biochar and mycorrhizae species inoculation significantly increased shoot and root dry weight. In general, the contribution of mycorrhizae seemed to be higher than the biochar contribution alone and a combination performed best. This might be a result of the mycorrhizae inoculum activating the biochar when added into the rhizosphere, which is a rich medium for other beneficial soil organisms. Although the relationship between biochar and mycorrhizal colonization is not yet entirely clear, the effect of physical protection of hyphae from fungal grazers might be facilitated as a consequence of the pore structure of biochar. The results also provide evidence for competition between biochar and plant nutrient uptake.
- Type
- Chapter
- Information
- BiocharA Regional Supply Chain Approach in View of Climate Change Mitigation, pp. 336 - 350Publisher: Cambridge University PressPrint publication year: 2016
References
Ameloot, N., Graber, E. R., Verheijen, F. G. A. and De Neve, S. (2013). Interactions between biochar stability and soil organisms: review and research needs. European Journal of Soil Science, 64, pp. 379–390.CrossRefGoogle Scholar
Bearden, B. N. (2001). Influence of arbuscular mycorrhizal fungi on soil structure and soil water characteristics of vertisols. Plant and Soil, 229, pp. 245–258.CrossRefGoogle Scholar
Blackwell, P., Krull, E., Butler, G., Herbert, A. and Solaiman, Z. (2010). Effect of banded biochar on dryland wheat production and fertiliser use in south-western Australia: an agronomic and economic perspective. Australian Journal of Soil Research, 48, pp. 531–545.CrossRefGoogle Scholar
Caravaca, F., Alguacil, M. M., Azcon, R. and Roldan, A. (2006). Formation of stable aggregates in rhizosphere soil of Juniperus oxycedrus: Effect of AM fungi and organic amendments. Applied Soil Ecology, 33, pp. 30–38.CrossRefGoogle Scholar
Daynes, C. N., Field, D. J., Saleeba, J. A., Cole, M. A. and McGee, P. A. (2013). Development and stabilisation of soil structure via interactions between organic matter, arbuscular mycorrhizal fungi and plant roots. Soil Biology and Biochemistry, 57, pp. 683–694.CrossRefGoogle Scholar
Elmer, W. H. and Pignatello, J. J. (2011). Effect of biochar amendments on mycorrhizal associations and Fusarium Crown and Root Rot of asparagus in replant soils. Plant Disease, 95, pp. 960–966.CrossRefGoogle ScholarPubMed
Gill, R. A., Kelly, R. H., Parton, W. J., Day, K. A., Jackson, R. B., Morgan, J. A., Scurlock, J. M. O., Tieszen, L. L., Castle, J. V., Ojima, D. S. and Zhang, X. S. (2002). Using simple environmental variables to estimate below-ground productivity in grasslands. Global Ecology and Biogeography, 11, pp. 79–86.CrossRefGoogle Scholar
Golchin, A., Oades, J. M., Skjemstad, J. O. and Clarke, P. (1994). Soil-structure and carbon cycling. Australian Journal of Soil Research, 32, pp. 1043–1068.CrossRefGoogle Scholar
Grant, C., Bittman, S., Montreal, M., Plenchette, C. and Morel, C. (2005). Soil and fertilizer phosphorus: effects on plant P supply and mycorrhizal development. Canadian Journal of Plant Science, 85, pp. 3–14.CrossRefGoogle Scholar
Hammer, E. C., Balogh-Brunstad, Z., Jakobsen, I., Olsson, P. A., Stipp, S. L. S. and Rillig, M. C. (2014). A mycorrhizal fungus grows on biochar and captures phosphorus from its surfaces. Soil Biology and Biochemistry, 77, pp. 252–260.CrossRefGoogle Scholar
Ishii, T. and Kadoya, K. (1994). Effects of charcoal as a soil conditioner on citrus growth and vesicular-arbuscular mycorrhizal development. Journal of the Japanese Society for Horticultural Science, 63, pp. 529–535.CrossRefGoogle Scholar
Jastrow, J. D., Miller, R. M. and Lussenhop, J. (1998). Contributions of interacting biological mechanisms to soil aggregate stabilization in restored prairie. Soil Biology and Biochemistry, 30, pp 905–916.CrossRefGoogle Scholar
Jeffery, S., Bezemer, T. M., Cornelissen, G., Kuyper, T. W., Lehmann, J., Mommer, L., Sohi, S. P., van de Voorde, T. F. J., Wardle, D. A. and van Groenigen, J. W. (2015). The way forward in biochar research: targeting trade-offs between the potential wins. Global Change Biology Bioenergy, 7, pp. 1–13.CrossRefGoogle Scholar
Jones, D. L. and Edwards, A. C. (1998). Influence of sorption on the biological utilization of two simple carbon substrates. Soil Biology and Biochemistry, 30, pp. 1895–1902.CrossRefGoogle Scholar
Karandashov, V. and Bucher, M. (2005). Symbiotic phosphate transport in arbuscular mycorrhizas. Trends in Plant Science, 10, pp. 22–29.CrossRefGoogle ScholarPubMed
Lal, R. and Kimble, J. M. (1997). Conservation tillage for carbon sequestration. Nutrient Cycling in Agroecosystems, 49, pp. 243–253.CrossRefGoogle Scholar
LeCroy, C., Masiello, C. A., Rudgers, J. A., Hockaday, W. C. and Silberg, J. J. (2013). Nitrogen, biochar, and mycorrhizae: alteration of the symbiosis and oxidation of the char surface. Soil Biology and Biochemistry, 58, pp. 248–254.CrossRefGoogle Scholar
Lehmann, J., Gaunt, J. and Rondon, M. (2006). Biochar sequestration in terrestrial ecosystems – a review. Mitigation and Adaptation Strategies for Global Change, 11, pp. 403–427.CrossRefGoogle Scholar
Lehmann, J., Rillig, M. C., Thies, J., Masiello, C. A., Hockaday, W. C. and Crowley, D. (2011). Biochar effects on soil biota – a review. Soil Biology and Biochemistry, 43, pp. 1812–1836.CrossRefGoogle Scholar
Lorenz, K. and Lal, R. (2014). Biochar application to soil for climate change mitigation by soil organic carbon sequestration. Journal of Plant Nutrition and Soil Science, 177, pp. 651–670.CrossRefGoogle Scholar
Medina, A. and Azcon, R. (2010). Effectiveness of the application of arbuscular mycorrhiza fungi and organic amendments to improve soil quality and plant performance under stress conditions. Journal of Soil Science and Plant Nutrition, 10, pp. 354–372.CrossRefGoogle Scholar
Miller, R. M., and Jastrow, J. D. (1990). Hierarchy of root and mycorrhizal fungal interactions with soil aggregation. Soil Biology and Biochemistry, 22, pp. 579–584.CrossRefGoogle Scholar
Nadian, H., Hashemi, M. and Herbert, S. J. (2009). Soil aggregate size and mycorrhizal colonization effect on root growth and phosphorus accumulation by Berseem clover. Communications in Soil Science and Plant Analysis, 40, pp. 2413–2425.CrossRefGoogle Scholar
Nichols, K. A. and Wright, S. F. (2005). Comparison of glomalin and humic acid in eight native US soils. Soil Science, 170, pp. 985–997.CrossRefGoogle Scholar
NOAA (2015). Global carbon dioxide concentrations surpass 400 parts per million for the first month since measurements began. [online] Available at: http://research.noaa.gov/News/NewsArchive/LatestNews/TabId/684/ArtMID/1768/ArticleID/11153/Greenhouse-gas-benchmark-reached-.aspx [Accessed 18 January 2016]Google Scholar
Ortas, I. (2003). Effect of selected mycorrhizal inoculation on phosphorus sustainability in sterile and non-sterile soils in the Harran Plain in South Anatolia. Journal of Plant Nutrition, 26, pp. 1–17.CrossRefGoogle Scholar
Ortas, I. (2006). Soil biological degradation. In: Lal, R. (ed.) Encyclopedia of Soil Science. New York: Marcel Dekker, pp. 264–267.Google Scholar
Ortas, I., Akpinar, C. and Lal, R. (2013). Long-term impacts of organic and inorganic fertilizers on carbon sequestration in aggregates of an Entisol in Mediterranean Turkey. Soil Science, 178, pp. 12–23.CrossRefGoogle Scholar
Rasse, D. P., Rumpel, C. and Dignac, M. F. (2005). Is soil carbon mostly root carbon? Mechanisms for a specific stabilisation. Plant and Soil, 269, pp. 341–356.CrossRefGoogle Scholar
Rillig, M. C. (2004). Arbuscular mycorrhizae, glomalin, and soil aggregation. Canadian Journal of Soil Science, 84, pp. 355–363.CrossRefGoogle Scholar
Rillig, M. C., Mardatin, N. F., Leifheit, E. F. and Antunes, P. M. (2010). Mycelium of arbuscular mycorrhizal fungi increases soil water repellency and is sufficient to maintain water-stable soil aggregates. Soil Biology and Biochemistry, 42, pp. 1189–1191.CrossRefGoogle Scholar
Rillig, M. C., Ramsey, P. W., Morris, S. and Paul, E. A. (2003). Glomalin, an arbuscular-mycorrhizal fungal soil protein, responds to land-use change. Plant and Soil, 253, pp. 293–299.CrossRefGoogle Scholar
Saito, M. (1990). Charcoal as a microhabitat for VA mycorrhizal fungi, and its practical implication. Agriculture Ecosystems and Environment, 29, pp. 341–344.CrossRefGoogle Scholar
Singh, S., Mishra, R., Singh, A., Ghoshal, N. and Singh, K. P. (2009). Soil physicochemical properties in a grassland and agroecosystem receiving varying organic inputs. Soil Science Society of America Journal, 73, pp. 1530–1538.CrossRefGoogle Scholar
Six, J., Bossuyt, H., Degryze, S. and 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, pp. 7–31.CrossRefGoogle Scholar
Smith, S. E. and Read, D. J. (2008). Mycorrhizal Symbiosis. 3rd Edition. San Diego, CA: Academic Press.Google Scholar
Sohi, S. P., Krull, E., Lopez-Capel, E. and Bol, R. (2010). A review of biochar and its use and function in soil. In: Sparks, D. L. (ed.) Advances in Agronomy, 105. San Diego, CA: Elsevier Academic Press, pp. 47–82.Google Scholar
Solaiman, Z. M., Blackwell, P., Abbott, L. K. and Storer, P. (2010). Direct and residual effect of biochar application on mycorrhizal root colonisation, growth and nutrition of wheat. Australian Journal of Soil Research, 48, pp. 546–554.CrossRefGoogle Scholar
Sundermeier, A. P., Islam, K. R., Raut, Y., Reeder, R. C. and Dick, W. A. (2011). Continuous no-till impacts on soil biophysical carbon sequestration. Soil Science Society of America Journal, 75, pp. 1779–1788.CrossRefGoogle Scholar
Tisdall, J. M., Smith, S. E. and Rengasamy, P. (1997). Aggregation of soil by fungal hyphae. Australian Journal of Soil Research, 35, pp. 55–60.CrossRefGoogle Scholar
Treseder, K. K. and Turner, K. M. (2007). Glomalin in ecosystems. Soil Science Society of America Journal, 71, pp.1257–1266.CrossRefGoogle Scholar
Vanek, S. J. and Lehmann, J. (2015). Phosphorus availability to beans via interactions between mycorrhizas and biochar. Plant and Soil, 395, pp. 105–123.CrossRefGoogle Scholar
Warnock, D. D., Lehmann, J., Kuyper, T. W. and Rillig, M. C. (2007). Mycorrhizal responses to biochar in soil – concepts and mechanisms. Plant and Soil, 300, pp. 9–20.CrossRefGoogle Scholar
Warnock, D. D., Mummey, D. L., McBride, B., Major, J., Lehmann, J. and Rillig, M. C. (2010). Influences of non-herbaceous biochar on arbuscular mycorrhizal fungal abundances in roots and soils: results from growth-chamber and field experiments. Applied Soil Ecology, 46, pp. 450–456.CrossRefGoogle Scholar
Whitman, T., Scholz, S. M. and Lehmann, J. (2010). Biochar projects for mitigating climate change: an investigation of critical methodology issues for carbon accounting. Carbon Management, 1, pp. 89–107.CrossRefGoogle Scholar
Wilkinson, D. M. (2008) Testate amoebae and nutrient cycling: peering into the black box of soil ecology. Trends in Ecology & Evolution, 23, 596–599.CrossRefGoogle ScholarPubMed
Wright, S. F. and Upadhyaya, A. (1998). A survey of soils for aggregate stability and glomalin, a glycoprotein produced by hyphae of arbuscular mycorrhizal fungi. Plant and Soil, 198, pp. 97–107.CrossRefGoogle Scholar
Zuccarini, P. (2010). Biological and technological strategies against soil and water salinization rhizosphere. Journal of Plant Nutrition, 33, pp. 1287–1300.CrossRefGoogle Scholar
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