Using poultry litter biochars as soil amendments
K. Y. Chan A E , L. Van Zwieten B , I. Meszaros A , A. Downie C D and S. Joseph DA NSW Department of Primary Industries, Locked Bag 4, Richmond, NSW 2753, Australia.
B NSW Department of Primary Industries, Wollongbar, NSW 2477, Australia.
C Best Energies P/L, Somersby, NSW 2250, Australia.
D University of New South Wales, School of Materials Science and Engineering, Sydney, NSW 2052, Australia.
E Corresponding author. Email: yin.chan@dpi.nsw.gov.au
Australian Journal of Soil Research 46(5) 437-444 https://doi.org/10.1071/SR08036
Submitted: 22 February 2008 Accepted: 3 July 2008 Published: 5 August 2008
Abstract
Despite the recent interest in biochars as soil amendments for improving soil quality and increasing soil carbon sequestration, there is inadequate knowledge on the soil amendment properties of these materials produced from different feed stocks and under different pyrolysis conditions. This is particularly true for biochars produced from animal origins. Two biochars produced from poultry litter under different conditions were tested in a pot trial by assessing the yield of radish (Raphanus sativus var. Long Scarlet) as well as the soil quality of a hardsetting Chromosol (Alfisol). Four rates of biochar (0, 10, 25, and 50 t/ha), with and without nitrogen application (100 kg N/ha) were investigated. Both biochars, without N fertiliser, produced similar increases in dry matter yield of radish, which were detectable at the lowest application rate, 10 t/ha. The yield increase (%), compared with the unamended control rose from 42% at 10 t/ha to 96% at 50 t/ha of biochar application. The yield increases can be attributed largely to the ability of these biochars to increase N availability. Significant additional yield increases, in excess of that due to N fertiliser alone, were observed when N fertiliser was applied together with the biochars, highlighting the other beneficial effects of these biochars. In this regard, the non activated poultry litter biochar produced at lower temperature (450°C) was more effective than the activated biochar produced at higher temperature (550°C), probably due to higher available P content. Biochar addition to the hardsetting soil resulted in significant but different changes in soil chemical and physical properties, including increases in C, N, pH, and available P, but reduction in soil strength. These different effects of the 2 different biochars can be related to their different characteristics. Significantly different changes in soil biology in terms of microbial biomass and earthworm preference properties were also observed between the 2 biochars, but the underlying mechanisms require further research. Our research highlights the importance of feedstock and process conditions during pyrolysis on the properties and, hence, soil amendment values of biochars.
Additional keywords: hardsetting soil, char, soil carbon sequestration, earthworms, microbial biomass, poultry manure, pyrolysis.
Acknowledgements
We acknowledge the financial support of NSW Department of Environment and Climate Change, BEST Energies Australia, and NSW Department of Primary Industries for jointly funding this research. We thank Josh Rust and Scott Petty for their assistance in conducting the soil biological analyses.
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