FAQs

Carbon capture and storage is an emissions reduction process designed to prevent large amounts of carbon dioxide from being released into the atmosphere. The technology involves capturing CO₂ produced by power generators and industrial plants, compressing it for transportation (typically by pipeline, or train) and then injecting it deep into carefully selected and evaluated underground rock formations where it is permanently stored.

Reaching our net-zero targets requires all the tools we have at our disposal.  CCS is one of the only proven solutions available today to reduce CO₂ emissions from crucial sectors of our economy including oil & gas, cement, steel, chemical and fertilizer production.

The International Energy Agency anticipates CCS will account for approximately 20 per cent of the GHG reductions necessary to reach the Paris Agreement goal of net-zero emissions by 2050. Canada’s federal emissions reduction plan calls for more than tripling Canada’s current CCS capacity, adding at least 15 million tonnes by 2030. According to the Canadian Energy Regulator, expanding Canada’s CCS capacity from today’s 7 million tonnes per year to 60-80 million tonnes per year is necessary to achieve net-zero emissions by 2050.

CCS has a proven track record of effectively capturing and securely storing CO₂ for decades. The technology was first implemented internationally in the 1970s, and Canada has been a leader in the development and deployment of CCS solutions since the early 2000s. CCS projects around the world, including those in Canada, have demonstrated the capability to safely and permanently store carbon dioxide in deep geological formations.

Canada is home to several pioneering CCS projects, including the world’s first large-scale CCS facility on a commercial power plant, and other significant projects in Alberta and Saskatchewan. These facilities have showcased the reliability and safety of CCS technology, providing valuable data and experience that help to continuously improve the processes involved.

Removing CO₂ from industrial exhaust involves complex chemical processes that require dedicated facilities which must be integrated with existing industrial operations – and space. Planning and constructing CO₂ capture facilities typically takes more than five years and costs approximately $1 billion for a facility capable of capturing 1 million tonnes of CO₂ per year. In addition to this, the CO₂ must be transported to an underground storage site, with long-term monitoring for permanent storage.Like any technology, CCS technology continues to evolve, and the first generation of CCS projects are now providing valuable insights and lessons that can help with lowering the cost and improving the performance of the next wave of projects. New CCS technologies are being developed using a variety of chemical and physical processes to capture CO₂ with a goal of reducing the size and cost of carbon capture facilities in the years ahead.

Industrial exhaust, also known as flue gas, contains a variety of chemicals based on the specific industrial processes taking place at a facility. Emissions are regulated to protect human safety and the environment, including acceptable limits for all components. Carbon dioxide is typically less than 15 percent of any flue gas. The CO₂ is pressurized and injected for permanent storage, and separated from other chemicals, water and impurities. The presence of other chemicals could impact the geologic formations used for CO₂ storage. As well, if the entire flue gas stream were to be stored, much more underground storage space would be needed.

Pipelines are the primary method of transporting captured CO₂ to storage sites. In the U.S, CO₂ has been transported via pipelines since 1972 and in Canada since 2000, with a high degree of safety measures in place. Transporting CO₂ via pipeline is similar to the pipelining of other commodities like oil and natural gas, except that CO₂ does not ignite during a leak. Pipelines are typically buried underground and are designed to withstand earthquakes, wildfires, and flooding. All pipelines are subject to strict safety and operating regulations set out by federal and provincial governments. Pipeline operators are required to have detailed emergency response plans in place, which are developed in collaboration with local first responders.

The process for storing CO₂ underground is well understood and has been safely used for decades in the oil and gas industry, as well as at existing CCS sites around the world. Underground CO₂ storage uses natural geologic processes to trap compressed CO₂ in porous rock formations approximately one kilometre below the surface. The CO₂ is contained below impermeable ‘cap rock’ formations – layers of impermeable rock to prevent the CO₂ from migrating up the formation – that help ensure it remains underground indefinitely. Over time, trapped CO₂ in saline aquifers returns to a mineralized state.

Carbon dioxide is in the air we breathe, the carbonated beverages we drink and even in some of the foods we eat. High quantities of CO₂ can be hazardous to people, however, which is why capturing, transporting and storing CO₂ is subject to strict regulation and oversight. Each storage site has a measurement, monitoring and verification plan in place, detecting the CO₂ movement beneath the surface, so operators can respond to any changes in behaviour quickly.

When a company finishes putting CO₂ safely underground, the site’s liability transitions from the operator to the Government of Alberta. This transition occurs after the site meets all regulatory closure criteria, including successful CO₂ injection and monitoring, sealing of injection wells, and implementation of post-closure monitoring plans that typically last at least 10 years. Once these requirements are met and regulatory approvals are obtained, the province assumes responsibility for the long-term liability of the site. CCS operators pay into the Post-Closure Stewardship Fund to offset costs associated with the long-term monitoring and maintenance of the site.

CCS projects are large-scale developments that create significant direct and indirect jobs, generate economic activity in communities, and keep important industries running over the long term. The world’s first CCS facility on a power plant located in southeast Saskatchewan employed a workforce of 1,700 people during peak construction and has been operational for nearly a decade. The facility employs process engineers, facility operators, technical and maintenance personnel, and more.