BIOCHAR FOR THE IMPROVEMENT OF SOIL AND ROCK WITH ACID POTENTIAL

Erlend Sørmo; Erika Kämäräinen; Matilda Edvardsson; Christian Maurice

doi:10.1051/e3sconf/202019506005

All issues

Volume 195 (2020)

E3S Web Conf., 195 (2020) 06005

References

Open Access

Issue		E3S Web Conf. Volume 195, 2020 4^th European Conference on Unsaturated Soils (E-UNSAT 2020)


Article Number		06005
Number of page(s)		6
Section		Special Session on the Reuse of Waste Geomaterials
DOI		https://doi.org/10.1051/e3sconf/202019506005
Published online		16 October 2020

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E. Sørmo, L. Silvani, G. Thune, H. Gerber, H. P. Schmidt, A. B. Smebye, G. Cronelissen. Waste Timber Pyrolysis in a Medium Scale Unit: Emission Budgets and Biochar Quality. Unpublished. [Google Scholar]
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[1] J. Lehman and S. Joseph. Biochar for Environmental Management. Science, Technology and Implementation (Routledge. 2nd edition, 2015). [Google Scholar]

[2] International Biochar Institute (IBI). Terms and definitions. Available 2017-04-06 from http://www.biochar-international.org/definitions [Google Scholar]

[3] W. Hao, E. Börkman, M. Lilliestråle, N. Hedin. Activated carbons prepared from hydrothermally carbonized waste biomass used as adsorbents for CO2. Applied Energy, 112, 526-532 (2013). [Google Scholar]

[4] S. E. Hale, H. P. Arp, D. Kupryianchyk, G. Cornelissen. A synthesis of parameters related to the binding of netural organic compounds to charcoal. Chemosphere 144, 65-74 (2016). [Google Scholar]

[5] Libra, J., Ro, K., Kammann, C., Funke, A., Berge, N., Neubauer, Y., Titirici, M-M., Fühner, C., Bens, O., Kern, J., Emmerich, K. Hydrothermal carbonization of biomass residuals: a comparative review of the chemistry, processes and applications of wet and dry pyrolysis, Biofuels, 2:1, 71-106 (2011). [Google Scholar]

[6] Amin, F. R., Huang, Y., He, Y., Zhang, R., Liu, G. & Chen, C. Biochar applications and modern techniques for characterization. Clean Technologies and Environmental Policy, 18(5), 1457-1473 (2016). [Google Scholar]

[7] Tan, X., Liu, Y., Zeng, G., Wang, X., Hu, X., Gu, Y. & Yang, Z. Application of biochar for the removal of pollutants from aqueous solutions. Chemosphere, 125, 70-85 (2015). [Google Scholar]

[8] E. Sørmo, L. Silvani, G. Thune, H. Gerber, H. P. Schmidt, A. B. Smebye, G. Cronelissen. Waste Timber Pyrolysis in a Medium Scale Unit: Emission Budgets and Biochar Quality. Unpublished. [Google Scholar]

[9] A. Hindar and D. K. Nordstrom. Effects and quantification of acid runoff from sulfid-bearing rock deposited during construction of Highway E18, Norway. Applied Geochemistry, 62, 150-163 (2005). [CrossRef] [Google Scholar]

[10] A. Pearce. A Mineralogical and Geochemical Description of Potentially Acid-producing Gneisses from the Lillesand Area. Implications for leaching behaviour. Master thesis in Geosciences, Environmental Geology. Department of Geology, the University of Oslo (2018). [Google Scholar]

[11] MEND. Acid Rock Drainage Prediction Manual. MEND Project 1.16.1b. Department of Energy, Mines and Resources Canada (1991). [Google Scholar]