Difference between revisions of "Biochar"
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| − | [[File:Biochar.jpg|thumb|Biochar <br> Photo credit: [[Acknowledgements|K.salo.85]]]] | + | [[File:Biochar.jpg|500px|thumb|Biochar <br> Photo credit: [[Acknowledgements|K.salo.85]]]] |
===What Is It?=== | ===What Is It?=== | ||
Biochar is a carbon-rich material produced by pyrolysis of organic feedstocks such as municipal, agricultural, and forestry wastes. It has a high surface area, which enhances soil aggregation, water holding capacity, and [[organic matter| organic carbon content]]. However, biochar properties and effectiveness for pollutant sorption depends on feedstock and pyrolysis conditions (Iqbal et al., 2015). <ref name=Iqbal>Iqbal H, Garcia-Perez M, Flury M. 2015. Effect of biochar on leaching of organic carbon, nitrogen, and phosphorus from compost in bioretention systems. Science of the Total Environment. 521-522: 37-45. doi: 10.1016/j.scitotenv.2015.03.060</ref> | Biochar is a carbon-rich material produced by pyrolysis of organic feedstocks such as municipal, agricultural, and forestry wastes. It has a high surface area, which enhances soil aggregation, water holding capacity, and [[organic matter| organic carbon content]]. However, biochar properties and effectiveness for pollutant sorption depends on feedstock and pyrolysis conditions (Iqbal et al., 2015). <ref name=Iqbal>Iqbal H, Garcia-Perez M, Flury M. 2015. Effect of biochar on leaching of organic carbon, nitrogen, and phosphorus from compost in bioretention systems. Science of the Total Environment. 521-522: 37-45. doi: 10.1016/j.scitotenv.2015.03.060</ref> | ||
===How is it being used?=== | ===How is it being used?=== | ||
| − | *Ongoing biochar research at the British Columbia Institute of Technology is testing the response of native plants to various soil/biochar mixes to be used in rain gardens and the comparison of biochar with different physico-chemical characteristics in chemical contaminants removal efficacy (BCIT, 2025) <ref>BCIT. 2025. Biochar Amended Soil Matrix for Green Stormwater Infrastructure. https://commons.bcit.ca/nbs/rain-gardens-bioretention-cells/</ref>. | + | *Biochar additions to [[Green roofs|green roof]] substrate were tested at the University of Toronto. Biochar-amended sedum green roofs presented the best integrated water quality, including reduced discharge concentrations of dissolved P (Liao et al., 2024)<ref>Liao, W., Sidhu, V., Sifton, M., Margolis, L., Drake, J., Thomas, S. 2024. Biochar and vegetation effects on discharge water quality from organic-substrate green roofs,</ref>. |
| − | *A [[Bioretention|bioretention]]system in China used biochar layered with or mixed into lateritic red soil, with some success in contaminant removal. The mixed biochar–soil design achieved the highest water retention, and both biochar-amended systems removed more contaminants (TN, NH₃-N, NO₃⁻, TP, PO₄³⁻, and Cu) than systems without biochar (Premarantha et al., 2023) <ref>Premarathna, K. S. D., Biswas, J. K., Kumar, M., Varjani, S., Mickan, B., Show, P. L., Lau, S. Y., Novo, L. A. B., & Vithanage, M. 2023. Biofilters and bioretention systems: the role of biochar in the blue-green city concept for | + | *Ongoing biochar research at the British Columbia Institute of Technology is testing the response of native plants to various soil/biochar mixes to be used in [[Rain gardens|rain gardens]] and the comparison of biochar with different physico-chemical characteristics in chemical contaminants removal efficacy (BCIT, 2025) <ref>BCIT. 2025. Biochar Amended Soil Matrix for Green Stormwater Infrastructure. https://commons.bcit.ca/nbs/rain-gardens-bioretention-cells/</ref>. |
| + | *A [[Bioretention|bioretention]] system in China used biochar layered with or mixed into lateritic red soil, with some success in contaminant removal. The mixed biochar–soil design achieved the highest water retention, and both biochar-amended systems removed more contaminants (TN, NH₃-N, NO₃⁻, TP, PO₄³⁻, and Cu) than systems without biochar (Premarantha et al., 2023) <ref>Premarathna, K. S. D., Biswas, J. K., Kumar, M., Varjani, S., Mickan, B., Show, P. L., Lau, S. Y., Novo, L. A. B., & Vithanage, M. 2023. Biofilters and bioretention systems: the role of biochar in the blue-green city concept for | ||
stormwater management. Environmental Science: Water Research and Technology, 9(12), 3103-3119. Advance | stormwater management. Environmental Science: Water Research and Technology, 9(12), 3103-3119. Advance | ||
online publication. https://doi.org/10.1039/d3ew00054k. https://pure.sruc.ac.uk/ws/portalfiles/portal/74040133/D3EW00054K_authors_accepted_version.pdf</ref>. | online publication. https://doi.org/10.1039/d3ew00054k. https://pure.sruc.ac.uk/ws/portalfiles/portal/74040133/D3EW00054K_authors_accepted_version.pdf</ref>. | ||
| − | *In Delaware, two roadside filter strips amended with biochar reduced peak flow and runoff volume, but showed no notable change in pollutant concentrations (Center for Watershed Protection, Inc., 2025) <ref>Center for Watershed Protection, Inc. 2025. Biochar for bioretention systems: A Review of Biochar use in Bioretentions, Biofilters, and Bioretention Soil Media. https://www.chesapeakebay.net/files/documents/Appendix-A-Biochar-for-Bioretention-Systems_Literature-Review-031725.pdf</ref>. | + | *In Delaware, two roadside [[Vegetated filter strips|filter strips]] amended with biochar reduced peak flow and runoff volume, but showed no notable change in pollutant concentrations (Center for Watershed Protection, Inc., 2025) <ref>Center for Watershed Protection, Inc. 2025. Biochar for bioretention systems: A Review of Biochar use in Bioretentions, Biofilters, and Bioretention Soil Media. https://www.chesapeakebay.net/files/documents/Appendix-A-Biochar-for-Bioretention-Systems_Literature-Review-031725.pdf</ref>. |
| − | *In field experiments in | + | *In field experiments in Europe, biochar reduced nutrient leaching in [[Green roofs|green roofs]], but did not reduce nutrient concentrations in effluent (Kuoppamäki et al., 2016) <ref>Kuoppamäki, K., Hagner, M., Lehvävirta, S. & Setälä, H. 2016. Biochar amendment in the green roof substrate affects runoff quality and quantity. Ecological Engineering, Vol. 88, pp. 1–9.</ref>. |
| − | |||
===Benefits=== | ===Benefits=== | ||
Latest revision as of 15:29, 19 August 2025
What Is It?[edit]
Biochar is a carbon-rich material produced by pyrolysis of organic feedstocks such as municipal, agricultural, and forestry wastes. It has a high surface area, which enhances soil aggregation, water holding capacity, and organic carbon content. However, biochar properties and effectiveness for pollutant sorption depends on feedstock and pyrolysis conditions (Iqbal et al., 2015). [1]
How is it being used?[edit]
- Biochar additions to green roof substrate were tested at the University of Toronto. Biochar-amended sedum green roofs presented the best integrated water quality, including reduced discharge concentrations of dissolved P (Liao et al., 2024)[2].
- Ongoing biochar research at the British Columbia Institute of Technology is testing the response of native plants to various soil/biochar mixes to be used in rain gardens and the comparison of biochar with different physico-chemical characteristics in chemical contaminants removal efficacy (BCIT, 2025) [3].
- A bioretention system in China used biochar layered with or mixed into lateritic red soil, with some success in contaminant removal. The mixed biochar–soil design achieved the highest water retention, and both biochar-amended systems removed more contaminants (TN, NH₃-N, NO₃⁻, TP, PO₄³⁻, and Cu) than systems without biochar (Premarantha et al., 2023) [4].
- In Delaware, two roadside filter strips amended with biochar reduced peak flow and runoff volume, but showed no notable change in pollutant concentrations (Center for Watershed Protection, Inc., 2025) [5].
- In field experiments in Europe, biochar reduced nutrient leaching in green roofs, but did not reduce nutrient concentrations in effluent (Kuoppamäki et al., 2016) [6].
Benefits[edit]
One study states that the mixing of biochar with compost did not decrease the phosphorus leaching from the mixture (Iqbal et al., 2015). [1] Based on this study, it would seem that biochar is ineffective for phosphorus removal. An Australian study found that phosphorus removal efficiency was inversely related to the biochar content of sand media when used to treat secondary sewage and septage in constructed wetland mesocosms (Rozario et al., 2016)[7]. Another study, located in Portland, found that biochar could reduce metal concentrations in stormwater when used as an amendment to bioretention systems but has a limited impact on nutrients [8].
However, some other papers indicate that biochar mixed with sand was able to retain some trace organic contaminants (TOrCs) (Ulrich et al., 2015), [9] and that after six months of operation, biochar-amended biofilters improved removal of total dissolved phosphorus and other TOrCs by greater than 60% (Ulrich et al., 2017a). [10] Amendment of LID systems with biochar has shown promise for improved removal of heavy metals, bacteria, nutrients, and TOrCs (Ulrich et al., 2017b). [11]
Back to additives.
- ↑ 1.0 1.1 Iqbal H, Garcia-Perez M, Flury M. 2015. Effect of biochar on leaching of organic carbon, nitrogen, and phosphorus from compost in bioretention systems. Science of the Total Environment. 521-522: 37-45. doi: 10.1016/j.scitotenv.2015.03.060
- ↑ Liao, W., Sidhu, V., Sifton, M., Margolis, L., Drake, J., Thomas, S. 2024. Biochar and vegetation effects on discharge water quality from organic-substrate green roofs,
- ↑ BCIT. 2025. Biochar Amended Soil Matrix for Green Stormwater Infrastructure. https://commons.bcit.ca/nbs/rain-gardens-bioretention-cells/
- ↑ Premarathna, K. S. D., Biswas, J. K., Kumar, M., Varjani, S., Mickan, B., Show, P. L., Lau, S. Y., Novo, L. A. B., & Vithanage, M. 2023. Biofilters and bioretention systems: the role of biochar in the blue-green city concept for stormwater management. Environmental Science: Water Research and Technology, 9(12), 3103-3119. Advance online publication. https://doi.org/10.1039/d3ew00054k. https://pure.sruc.ac.uk/ws/portalfiles/portal/74040133/D3EW00054K_authors_accepted_version.pdf
- ↑ Center for Watershed Protection, Inc. 2025. Biochar for bioretention systems: A Review of Biochar use in Bioretentions, Biofilters, and Bioretention Soil Media. https://www.chesapeakebay.net/files/documents/Appendix-A-Biochar-for-Bioretention-Systems_Literature-Review-031725.pdf
- ↑ Kuoppamäki, K., Hagner, M., Lehvävirta, S. & Setälä, H. 2016. Biochar amendment in the green roof substrate affects runoff quality and quantity. Ecological Engineering, Vol. 88, pp. 1–9.
- ↑ P. de Rozari, M. Greenway, A. El Hanandeh. 2016. Phosphorus removal from secondary sewage and septage using sand media amended with biochar in constructed wetland mesocosms. https://doi.org/10.1016/j.scitotenv.2016.06.096.
- ↑ Struzak, M., Poor, C., Wolfand, J., Radke, A. 2024. Evaluation of Biochar as an Amendment for the Removal of Metals, Nutrients, and Microplastics in Bioretention Systems. https://ascelibrary.org/doi/abs/10.1061/JOEEDU.EEENG-7487
- ↑ Ulrich B, Im E, Werner D, Higgins C. 2015. Biochar and Activated Carbon for Enhanced Trace Organic Contaminant Retention in Stormwater Infiltration Systems. Environ. Sci. Technol. 49:6222-6230. doi: 10.1021/acs.est.5b00376.
- ↑ Ulrich B, Loehnert M, Higgins C. 2017a. Improved contaminant removal in vegetated stormwater biofilters amended with biochar. Environ. Sci.: Water Res. Technol. 3:726-734. doi: 10.1039/C7EW00070G
- ↑ Ulrich B, Vignola M, Edgehouse K, Werner D, Higgins C. 2017b. Organic Carbon Amendments for Enhanced Biological Attenuation of Trace Organic Contaminants in Biochar-Amended Stormwater Biofilters. Environ. Sci. Technol. 51:9184-9193. doi: 10.1021/acs.est.7b01164.