Abstract
Natural processes and human activities produce vast amounts of dead vegetation which return CO2 to the atmosphere through decay and combustion. If such vegetation could be converted into biocoal and sequestered on the ocean floor, it could reduce the accumulation of atmospheric CO2 without involving sequestration in the form of CO2. Given that raw vegetation is unsuitable for large-scale energy applications, a process was developed to convert raw vegetation into a form of biocoal, termed Black Pellets, that solves the logistical and energy conversion problems of using raw vegetation for power generation. Seemingly overlooked is that properties of Black Pellets—higher density than seawater and resistance to microbial decay—may offer an environmentally safe way of sequestering vegetation carbon on the sea floor. Sequestering vegetation carbon by depositing biocoal as Black Pellets in the deep ocean (oceanic sequestration of biocoal—OSB) would be a means of achieving long-lasting negative emissions. Sacrificing the energy content of the deposited pellets would require substituting energy from other sources. If the substitute energy could be from lower-carbon natural gas or carbon-free sources, the effects would be less accumulation of atmospheric CO2 compared to using the pellets for energy and a nearly 60 to 100% reduction in the need for geologic sequestration compared to bioenergy carbon capture and storage (BECCS). If confirmed by research, OSB would be an addition to the sparse toolbox of negative emission technologies (NETs) which would give humankind more flexibility in meeting the goals of the Paris Agreement.
Highlights
IntroductionRaw vegetation has properties that make it unsuitable for large-scale energy applications
1.1 Properties of Black Pellets and their existing use in generating useful energyRaw vegetation has properties that make it unsuitable for large-scale energy applications
“burn” indicates two baseline scenarios in which Black Pellets are used for their “conventional” purpose of producing electricity in direct-fired power plants, Page 7 of 23 29 namely: (1) first, the Black Pellets are burned as an net-zero-emissions power source, and (2) the pellets are burned to produce power and negative emissions in a Black Pellet power with capture and geologic storage (CCS) (BECCS) configuration
Summary
Raw vegetation has properties that make it unsuitable for large-scale energy applications. Its low energy density and high moisture content make it inefficient for generating useful energy. Its high moisture content leads to decomposition and greenhouse gas emissions which, coupled with its irregular shapes and low bulk density, make the storage and transportation of raw vegetation problematic. A process was invented by the Energy Research Centre of the Netherlands (the TOP process) to transform vegetation biomass into a form that solves the logistical and useful energy production problems of raw plant material (Bergman 2005). The material is subsequently densified into biocoal pellets (Black Pellets) with properties that are favorable to their transportation and use for energy applications, namely: these pellets have a higher energy density than raw vegetation, a greater bulk density, homogeneous shapes and content, durability, water resistance, and resistance to microbial degradation
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