Tests confirm biochar can be used as fertilizer
Oct. 5, 2016 - The use of biochar in agriculture improves soil fertility, especially in tropical regions, and mitigates greenhouse gas emissions. A project funded by the Austrian Science Fund FWF studied the positive impact of the "fertiliser of the future" on ecosystems and nutrient cycles.
October 4, 2016 By PR&D – Public Relations for Research & Education
In agriculture and in science, expectations for the benefits of biochar have been high in recent years. Modelled on the ancient practices of Amazonian farmers, charred biodegradable waste is used as fertiliser on arable land. Soils fertilised in this way have proven extremely fertile, just like the black earth – called “terra preta” – that has been found in several parts of the Amazon region.
Initial testing in the laboratory confirmed that biochar made from organic matter such as wood off-cuts, straw, dung or kitchen scraps not only increases soil fertility, but also reduces greenhouse gas emissions, as carbon is trapped in the soil and prevented from escaping into the atmosphere. Rebecca Hood-Nowotny of the Austrian Institute of Technology (AIT) has exhaustively studied the “fertiliser of the future”, for the first time also analysing pilot field trials. In a recently concluded project, Hood-Nowotny, a holder of the FWF’s Elise Richter Fellowship, focused on the soil nitrogen cycle, which is also affected by biochar.
Cooperation with the International Institute of Tropical Agriculture (IITA, www.iita.org) and AIT allowed Hood-Nowotny to carry out analyses of an experimental site of tropical soil in Kenya, as well as two sites in Lower Austria and Styria. She compared nitrogen cycles in both soil types with and without biochar addition, as well as with and without artificial fertiliser.
For both tropical and temperate soils, Hood-Nowotny was able to prove that biochar addition increased nitrification rates and that in tropical soils this led to greater nitrogen uptake by plants and enhanced growth. Moreover, she found that in all soils studied biochar addition decelerated the organic nitrogen cycle, as it appears the biochar protects organic matter from degradation by soil enzymes. Hood-Nowotny suspects that the large surface area and macro-pore structure of biochar provides favourable microhabitats for soil microbial biomass.
As a consequence, nutrient and water retention is improved, stabilising the soil overall. As for mitigating climate change: tonnes of carbon are potentially locked up for decades and if more nitrogen remains in the soil, nitrous oxide emissions are reduced. “Our research has shown, for instance, that biochar improves water retention and plant water use efficiency in both soil types”, notes Hood-Nowotny. These are valuable insights when it comes to developing technological solutions for ensuring plant growth during droughts, she points out. Moreover, in Kenya’s tropical soils, biochar also has liming effects, which Hood-Nowotny says may explain the increase in nitrification rates.
Field trials and greenhouse studies conducted as part of the FWF-funded project indicate that biochar combined with small quantities of inorganic fertiliser yielded the best results. In tropical soils, it increased crop yield by 75 per cent. “Biochar has an extremely positive impact on soil nutrient cycles – resulting in marked increases in grain yield, for instance. This holds particularly true for infertile tropical soils with low soil organic matter content”, Hood-Nowotny explains.
Hood-Nowotny studies such biogeochemical processes using stable isotopes. These chemical elements serve to “label” the fertilizer or biochar, enabling researchers to track turnover processes, retention periods, or the molecular origins of certain substances in the soil.
Rebecca Clare Hood-Nowotny is a biogeochemist at the Austrian Institute of Technology (AIT, www.ait.ac.at/?L=1). She qualified as a professor at the University of Natural Resources and Life Sciences, Vienna, in the field of forest and soil sciences. She is an environmental scientist and an expert on isotope analysis, and studies interactions between vegetation, climate and soil nitrogen and carbon cycles in order to investigate nature-based decarbonisation solutions.
Hood-Nowotny, R (2016). Biochar: A regional Supply Chain Approach in View of Climate Change Mitigation Ed. Viktor Bruckman Cambridge University Press. Use of stable isotopes in understanding the impact of biochar on the nitrogen cycle (2016). In press
Prommer, J., Wankek, W., Hofhansl, F., Trojan, D., Offre, P., URICH, T., … & Hood-Nowotny, R. C. (2014). Biochar decelerates soil organic nitrogen cycling but stimulates soil nitrification in a temperate arable field. PLOS ONE, 9(1), E86388.
Hood-Nowotny and B Vanlauwe: Priming effects of biochar elucidated using stable isotope techniques. Geophysical Research Abstracts: Vol. 14, EGU2012-4889, 2012 R. adsabs.harvard.edu/abs/2012EGUGA..14.4889H
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