Biochar: Difference between revisions
Line 29: | Line 29: | ||
==Carbon Sequestration== | ==Carbon Sequestration== | ||
Biochar has been identified as a key means of sequestering (removing and storing) carbon dioxide from the atmosphere into the Earth's soil. A group of scientists published in Nature in 2019 identified Biochar as | Biochar has been identified as a key means of sequestering (removing and storing) carbon dioxide from the atmosphere into the Earth's soil. A group of scientists published in Nature in 2019 identified Biochar as the negative emissions technology "at the highest technology readiness level."[1] According to their research, the global carbon sequestration potential of biochar (when also using potassium as a low-concentration additive) is over 2.6 billion tons of CO2/year.[1] | ||
===Projects=== | ===Projects=== |
Revision as of 23:03, 12 April 2022
OVERVIEW COPY TEXT
Definition
Technical
Crystal
Cavity
Historical
Archaic
Revival
Production
Feedstocks
Projects
How To
Projects
Application
Carbon Sequestration
Biochar has been identified as a key means of sequestering (removing and storing) carbon dioxide from the atmosphere into the Earth's soil. A group of scientists published in Nature in 2019 identified Biochar as the negative emissions technology "at the highest technology readiness level."[1] According to their research, the global carbon sequestration potential of biochar (when also using potassium as a low-concentration additive) is over 2.6 billion tons of CO2/year.[1]
Projects
Soil Amendment
As a soil amendment, Biochar is the simplest way to increase long-term soil organic carbon content in a form which can endure for thousands of years, as seen in the Amazonian Black Earth.
Additional benefits of Biochar for soil include improved soil texture, nutrient retention, cation exchange capacity,[2] water retention,[3] and microorganism habitat.[4]
Projects
Feed Additive
Projects
Water Filter
Charcoal has been a part of water treatment for at least 4000 years.[1] Biochar’s incredible porosity and surface area give it a high capacity to adsorb a wide variety of contaminants from water.[2]
Laboratory testing shows that biochar can effectively reduce contaminants including:
• Heavy metals like lead, copper, zinc, cadmium, cobalt, and nickel;
• Organics such as gasoline compounds and other volatile organics, polychlorinated biphenyls (PCB), polyaromatic hydrocarbons (PAH), and some herbicides, pesticides and pharmaceuticals;
• Chemical oxygen demand (COD) and biological oxygen demand (BOD);
• Nutrients such as phosphorus and ammonia;
• Totals suspended solids (TSS).[3]
A 2019 study in the Journal of Environmental Management Found that wastewater treatment using biochar in modified sand filters would be able to achieve a similar level of effectiveness in "significant microbe removal" and "reduce the land requirement for implementation of biochar in treatment facilities," overcoming a "major constraint" to wastewater treatment on farms.[4]
How To (Video): https://youtu.be/kazEAzGWuIc
How To (Manual): http://www.aqsolutions.org/images/2010/06/water-system-handbook.pdf
Projects
Insulation
Projects
Supercapacitor
Projects
Asphalt
Ink
Paper
Plastic
Sources
[1] <https://www.nature.com/articles/s41598-019-41953-0>
[2] <https://www.mdpi.com/2071-1050/11/11/3211/pdf>
[3] <https://www.frontiersin.org/articles/10.3389/fpls.2015.00733/full>