Market Snapshot: Canada’s Bioenergy Diversity and Potential
Release date: 2023-05-17
Canada has a well-established bioenergy sector, contributing to over 6%Footnote 1 of total primary energyDefinition* in 2021. Canada’s bioenergy sector has been steadily growing in the past two decades with significant expansions expected in the near future.Footnote 2Footnote 3 Considered a low carbon form of energy, bioenergy is expected to contribute to net-zero efforts both in Canada and globally.
Total primary energy available to Canada from biomass is around 1,800 petajoules (PJ) per year. When converted to end-use products, only some of that primary energy becomes end-use energyDefinition* (some energy is lost during processing). For simplicity, if it is assumed primary energy contained within all biomass feedstocks is converted to end-use energy with an efficiency of 35%, then the total national end-use energy from biomass feedstocks would be around 630 PJ per year. That represents enough energy, including heating and electricity, for over 7 million households in Canada.Footnote 4
Figure 1: Annual primary energy supply by different biomass feedstocks by province or territory
Sources and Description
Sources: Canada Energy Regulator Estimated Values.
- Biomass Inventory Mapping and Analysis Tool (BIMAT) - Agriculture and Agri-Food Canada
- Torchlight Bioresources, Renewable Natural Gas (Biomethane) Feedstock Potential in Canada
- Navius Research. Biofuels in Canada 2021,
- Statistics Canada, Table 32-10-0125-01 Cattle and calves, farm and meat production,
- Canada Forestry Services - Forest area harvested on private and Crown lands in Canada.
Description: The graph highlights each province's estimated annual maximum primary energy potential from currently available biomass feedstocks. The annual maximum primary energy potential is divided to six different feedstock types: purpose-grown energy crops, crop residue, forestry, forestry residue, urban waste, and livestock residue. Purpose-grown energy crops are estimated based on 3% prime landFootnote 5 use. Forestry is estimated based on a 5% wood supplyFootnote 6 use. The estimated values do not include animal fats, animal oils, and waste cooking oil.
Different kinds of bioenergy have different energy potentials
Each biomass feedstock has its own energy density. There are two ways to measure this. Primary energy is the energy contained within raw biomass before converting it to end-use products such as biofuels and electricity. End-use energy is the energy contained within the end-use products. Sometimes, the raw product is also the end-use product (such as firewood).
Not all feedstocks are suitable to produce all types of bioenergy. For example, firewood is preferred for electricity generation or heating, whereas municipal solid waste is mainly used to make biofuels like biogas and renewable natural gas.
Where does biomass for bioenergy come from?
Bioenergy is made primarily with biomass feedstocks.Definition* Biomass is organic material from plants or animals, which is either burned to create energy, or converted to different products before burning. Bioenergy can be in the form of biofuelsDefinition* like ethanol, biodiesel, biogas, and renewable natural gas; it is also used to generate electricity and produce hydrogen.
Bioenergy feedstocks are diverse, ranging from livestock manure to trees. These feedstocks can be purpose-grown, like plants and trees specifically grown to become bioenergy, or residueFootnote 7 from another activity. They are categorized below by origin:
- Urban waste: waste from residents, industries (like pulp and paper), institutions, commercial activities, and waste from landfills and sewage.
- Livestock residue: residue from livestock farming and processing, including animal manure, animal oils, and animal fats.
- Purpose-grown energy crops: crops grown for energy, including corn, wheat, willow, canola, switchgrass, miscanthus, hybrid poplar, and more.
- Crop residue: plant remains after crops are harvested and processed.
- Forestry: mainly wood produced as firewood and fuelwood,Footnote 8 and includes wood produced as a result of sustainable forestry practices, such as wildfire mitigation and pest control.
- Forestry residue: unused materials from trees after harvesting and processing for lumber or other non-energy uses. Includes treetops, tree branches, and forest product manufacturing residues such as sawdust from sawmills.
Figure 2: Different types of biomass feedstocks
Sources and Description
Description: The graph highlights the different types of biomass feedstocks by category. The graph includes six different feedstock categories. Urban waste includes waste cooking oil, municipal solid waste,Definition* pulp mill sludge, biosolids, source separated organics,Definition* and wastewater. Livestock residue includes animal manure, animal oils, and animal fats. Agricultural residue includes flaxseed residue, corn residue, canola residue, soybean residue, wheat residue, sugarcane pulp, and barley residue. Forestry residue includes wood mill residue and wood harvest residue. Forestry includes fuelwood and firewood. Purpose-grown energy crops include soybean, wheat, canola, switchgrass, miscanthus, hybrid-poplar, and willow. The feedstocks in the illustration are not an exhaustive list.
Bioenergy can be low carbon when managed properly
Plants capture and store carbon dioxide (CO2) during their lifespan, and when they die, they slowly release that CO2 back into the atmosphere. This sequence is part of the short carbon cycle.Footnote 9 Burning biomass, either directly or as biofuels, releases the CO2 originally captured and stored in plants that would otherwise naturally release and is considered carbon-neutral.Footnote 10 Bioenergy does release small amounts of other greenhouse gases (GHGs) like methane, but is still considered low-carbon when well-managed. When paired with carbon capture and storage technology, or Bioenergy Carbon Capture and Storage (BECCS), bioenergy can become a net-negative emitting renewable energy source.Footnote 11
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