The decarbonization trend continues to grow across all sectors of life as part of a global consensus to save the earth. Biomass plays a strategic role through biotransition, where biomass acts as a carbon-neutral fuel, thus preventing it from contributing to increased CO2 emissions in the atmosphere, and through carbon-negative programs with carbon sequestration. Substantively, decarbonization through carbon-negative programs (CDR/carbon dioxide removal) will be effective if biomass fuel, as a carbon-neutral fuel, or the use of other renewable energy sources, is also increased. In other words, efforts to reduce atmospheric CO2 concentrations cannot simply involve absorbing CO2 from the atmosphere (carbon capture and storage). In the context of biomass-based renewable energy, the practical application of wood chip and wood pellet production as carbon-neutral renewable fuels will complement biochar (carbon-negative). Read more details here.
Biochar, a product of biomass pyrolysis, or biocarbon products used as a medium for climate change mitigation through carbon sequestration/carbon sinks, is not yet as popular as the use of biomass as a renewable energy source, such as wood chips, wood pellets, or palm kernel shells (PKS). For comparison, global biochar production in 2023 was 350,000 tons, while wood pellet production was 47 million tons. With a conversion of biomass to biochar of approximately 30%, the amount of dry biomass processed into biochar in 2023 was 1.2 million tons, compared to 47 million tons of wood pellets in the same year, or only about 2.6% of the biomass used for wood pellets—a significant gap. However, biochar is predicted to gain momentum and be produced on a large scale globally. The application of biochar as part of carbon capture and storage (CCS) is currently experiencing the fastest growth compared to other CO2 reduction (CDR) efforts. Biochar leads in CDR credits in the voluntary carbon market (VCM), with over 90% globally by 2023 as per the cdr.fyi database.
Furthermore, carbon capture and storage (CCS) applications using absorber-stripper columns, where the captured carbon dioxide is stored in the Earth's crust, remain expensive. Pyrolysis technology for biochar production, meanwhile, is increasingly developing, making it easy to operate, efficient, and environmentally friendly, with the potential to produce various by-products that offer additional benefits. These pyrolysis units can even be integrated with processing plants, such as palm oil mills. For more details, read here.
Including the BECCS (Bioenergy with Carbon Capture and Storage) application which is overall a carbon negative program or CO2 removal from the atmosphere (CDR / Carbon Dioxide Removal) but building a bioenergy unit such as a biomass power plant itself is also not cheap, especially with the addition of carbon capture and storage (CCS) equipment. A number of countries that already have many biomass power plants, for example Japan with around 300 biomass power plants, to become carbon negative operations or part of CO2 removal from the atmosphere (CDR / Carbon Dioxide Removal) will be easier by upgrading them with the installation of carbon capture and storage (CCS) equipments. But in general, to absorb CO2 in the atmosphere and achieve climate targets, the application of biochar produced with pyrolysis units is easier, cheaper and strategic.
To anticipate and prepare for the growing era of CO2 removal from the atmosphere (CDR), biochar research must also be enhanced. Pyrolysis equipment that can cover or carry out comprehensive biochar production trials under all measurable production process operating conditions is crucial. Biochar product quality parameters are determined by three factors: the raw material or type of biomass, the production process, and the biomass pretreatment. For more details, read here. Important variables in the biochar production process in the pyrolysis unit, such as duration/residence time, temperature, and heating rate, must also be able to be handled with this equipment.
Furthermore, the issue of exhaust emissions is also crucial. This is because carbon standards organizations like Puro, Verra, and CSI require exhaust emissions to meet certain thresholds. Furthermore, excess heat from pyrolysis and/or liquid and gaseous products must be utilized. This means that laboratory-scale pyrolysis equipment must be sophisticated enough to meet these requirements. Following the methodologies developed by these standards organizations is essential for producing certified biochar to earn carbon credits. With each ton of CO2 equivalent removed from the atmosphere, or CO2 Removal Certificates (CORCs), worth over $150, this is certainly very attractive.
The diverse uses of biochar, such as in agriculture, animal husbandry, and even for concrete construction, further encourage its implementation in the future. Even if there is a question, for example, about the use of biochar in the agricultural sector: should biochar be prioritized for soil fertility or climate solutions first? This is certainly not a dichotomous question, but rather a driving force for its application, which is strongly influenced by factors that are problematic in the region or area. For more details, read here. To achieve the best performance while minimizing the risks of biochar production, increasing biochar production capacity is necessary, starting from the laboratory scale, pilot scale, demo scale, and finally commercial plants. By understanding the characteristics of the production process gradually and in depth, the hope is that the success rate of large-scale or commercial production will also be high.
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