What exactly is CCS?
CCS is an abbreviation of Carbon Capture and Storage. The carbon referred to here is the greenhouse gas carbon dioxide (CO2), which is emitted when we, for example, burn oil, coal or gas and when we manufacture cement and other industrial products.
So, CCS is technology that can capture and transport this CO2 and store it safely under the earth’s surface. Many have therefore begun to refer to CCS as carbon recycling, since the plan is to return the CO2 to where it came from, underground, for example in old, stable oil reservoirs that can be sealed.
- In 2017, Trondheim became the CCS capital of Europe when the European Carbon Dioxide Capture and Storage Laboratory Infrastructure (ECCSEL) was established as a permanent infrastructure entity called ERIC (European Research Infrastructure Consortium). This was the first time that a country outside the EU was awarded a project as part of ERIC.
- The project involves 50 laboratories in five countries being coordinated from NTNU and SINTEF in Trondheim.
- NTNU and SINTEF are working closely together in the field of CCS research, including as part of the Norwegian research centre NCCS. NCCS is a so-called Centre for Environmentally-friendly Energy Research (CEER). The centre will run for eight years and is funded by its industrial partners and the Research Council of Norway.
- NCCS projects include research into how Norway will achieve operation of a full-scale CCS project. This project will involve the establishment of Europe's first industrial CCS plant. Currently, the companies Hedelberg Cement in Brevik and Fortum Varme in Oslo are looking into how it is possible to capture CO2 from cement production and waste, respectively.
- Equinor, Shell and Total will be investigating the possibility of developing an open access infrastructure for the transport and storage of the CO2.
- This summer, the NCCS Centre arranged an international research conference called TCCS-10 together with NTNU and SINTEF.
Why is so-called CCS – capture and underground storage of CO2 – so important?
The reason is that all serious scenarios for the future depend on us being able to meet this challenge if the two-degree goal is to be achieved in practice. In other words, we have no choice! The reason is that we will be dependent on oil and gas for several years to come. Turning off the world’s oil supplies is a far more unrealistic solution.
The International Energy Agency (IEA) and the UN Climate Panel clearly state that it is “extremely probable” that climate change is connected with our CO2 emissions. Hence, by 2050 the world must reduce emissions of CO2 by 5 gigatons per year. This is equivalent to the total CO2 emissions from about ten thousand factories and power stations. CCS can contribute to eliminating fully 14-17 per cent of these emissions. (Based on figures from 2015.)
Without this method it will be impossible to achieve the so-called two-degree goal, which in the opinion of an increasing number of scientists ought to be adjusted to 1.5 degrees. To be on the safe side (i.e. aiming for 1.5 degrees) we should actually reduce emissions even further, at the same time as we implement capture and storage of CO2.
To sum up: Such initiatives as the increased use of nuclear power and renewable energy, and changes involving the electrification of the transport industry will not be enough. We cannot manage without CCS. The world must therefore undergo change on a scale we have never seen before, and this is urgent.
Why has it come to this?
First of all: The world’s climate researchers agree that CO2 is a greenhouse gas that inhibits heat radiation and therefore causes the Earth’s temperature to rise. When the amount of CO2 in the atmosphere increases, the insulating effect of the atmosphere also increases – in other words, CO2 contributes to the greenhouse effect. Natural emissions of CO2 are handled by the planet itself, since trees and plants absorb CO2 in connection with photosynthesis, resulting in the so-called “carbon cycle”. However, since the industrial revolution our demand for energy has increased, and this demand has been satisfied by using coal, oil and gas, which without human interference would have remained untouched, as a natural underground carbon store. By burning coal and gas, and by establishing industry that also emits CO2, we have released more CO2 than nature is capable of absorbing alone, for example through the process of photosynthesis.
All the available figures and scientific measurements show that greenhouse gas emissions have increased steadily since 1890, and the emissions up to the present time have resulted in a total rise of one degree in the mean temperature at the Earth’s surface.
We are already seeing the impact both on nature and on infrastructure. A further increase in temperature will lead to a rise in sea level as the polar ice melts, to even more extreme weather, and to more acidic seawater which in turn will cause organisms such as corals and algae to die out. Species that at present form food for animals and humans will disappear. Rising temperature and drought will dramatically reduce yields of cereals, fruit and vegetables. This will cause an increase in the number of refugees.
Is it technically possible to capture CO2?
Yes. Norwegian research scientists have been working on this since the 1980s. In those days CO2 had already been injected for some time (since the 1970s) into American oil fields to increase oil production. Almost the same technology is used in CO2 capture today. Since CCS commenced in 1996, more than 23 million tonnes of CO2 have been safely stored at the Sleipner field and we have been storing CO2 at the Snøhvit field since 2008. The storage takes place in brine-filled pores in sandstone formations (so-called salt-water aquifers). Such CO2 accumulations are sealed by a natural geological caprock, such as shale or clay.
Norway also has the world’s largest test facility for CO2 capture technology at Mongstad. Here, large and small technology providers can present their innovative concepts for improving CO2 capture technology and test them on an industrial scale under carefully controlled conditions.
Is it expensive?
All technology costs money, but the costs that climate change will impose on us will be far higher.
SINTEF’s estimates show that the cost of large-scale (i.e. millions of tonnes per year) capture, transport and storage of CO2 from coal-fired power plants will be approximately USD 93 per tonne (NOK 830). (See the key facts box). This cost varies according to the country, source, transport distance and type of disposal site. Capturing CO2 from cement factories, steelworks and incineration of waste will cost less than capturing CO2 from power plants.
Key facts/total costs of CCS:
SINTEF's CCS calculations are based on the following assumptions:
- 600 coal-fired power plants with CCS is deployed each year during 10 years, and the CO2 is continuously stored in the underground
- Each capture facility has a capacity of 1 million tonnes CO2/year
- Total costs – capture, transport and storage: 93 USD/tonne CO2
- Investment costs: 332 million USD per unit
- Capital costs: 7 % of investment costs
- Operation and maintenance cost: 5 % of investment costs
- Transport and storage cost: 25 USD/tonne CO2
- Lost energy production cost: 31 USD/tonne CO2
However, CCS is getting cheaper all the time: As is the case with other technology that is initially expensive, CO2 capture has become more efficient and therefore cheaper. Research scientists expect the price to sink further, in step with the implementation of the technology. Spreading of this technology is also seen as representing major potential for industrial development.
- Read more: Carbon capture is cheaper than ever
How does CCS work in practice?
Essentially, there are two categories of CCS:
The first is to capture and store CO₂ found in power generation and other industries, such as the cement, steel and waste industries, as well as power generation from natural gas and coal. These are sources with high CO₂ emissions.
This is done using various chemical processes.
This absorbtion technology (among these, amine technology) uses chemicals that bind to the CO₂ contained in the industrial flue gases before it reaches the chimney. This means that industries such as the steel industry, fertilizer producers and cement factories can reduce their CO₂ emissions to zero.
This is extremely important as these industries produce goods the world needs, but are also set to produce CO₂ as a by-product of their activity well into the future. CCS is the only solution there is that can deliver zero emissions for these industries.
To capture the CO₂, the first step is the use of chemicals to bind to the CO₂. Then the CO₂ must be separated from the chemicals to get pure CO₂. To achieve this, the mixture is heated to release the CO₂. This process leaves two products: pure CO₂ that is easy to handle and chemicals that can be reused.
The process of separating the CO₂ from the chemicals is costly, because it requires a lot of energy. Such CO₂ purification is therefore most profitable in industrial processes that generate waste heat, because the energy from this excess heat can be used for the purification process. Norwegian researchers and Aker Solutions have developed a mobile test facility for this in the Solvit project.
The mobile test facility has verified capture from gas- and coal-fired power stations, refineries, waste incineration facilities and cement factories. Researchers held tests in six pilot plants in Germany, Scotland, the USA and Norway and evaluated 90 different chemical mixtures to find the best one.
The chemical purification method can also be used when creating hydrogen from natural gas. Using this method, the hydrogen becomes completely emission-free.
The second method is called BIO-CCS. In practice this means extracting CO₂ from the atmosphere.
The principle is to capture and store CO₂ from sources that are initially considered climate neutral, such as biological waste, wood chips or manure. What is captured is the CO₂ found in the earth’s natural cycle – and not CO₂ from carbon sources such as coal, oil and gas. This way we reduce the amount of greenhouse gas that already exists in the atmosphere, because it comes from the natural, biological CO₂ cycle.
- Read more: Removing CO2 from the atmosphere
BIO-CCS can also be done by capturing and storing CO₂ from biological sources through biocarbon (charcoal) production. Biocarbon is a good soil improver and also binds to CO₂, as long as the coal is not burned and remains in the soil. The method of producing biocarbon is called pyrolysis, and is so simple that it can be done in your own garden with garden waste, for example. However, a pyrolysis furnace is needed.
In the oven, the biomass is heated to between 500 and 700 degrees with a minimal air supply in no more than 20 minutes. Biocarbon contains twice as much carbon as other organic matter. The method is smart because we only need soil or cultivated land for CO₂ storage, which makes the transport and storage of CO₂ less complicated than from industry. Of course, the method is most effective when used on a large scale in horticulture or agriculture.
According to figures from the Norwegian Institute of Bioeconomy Research (NIBIO), emissions from the Norwegian agricultural sector can be halved if 4,000 Norwegian farms produce and mix biocarbon into the soil. NIBIO is a partner in the CAPTURE+ project and are the ones that have researched biocarbon for the longest in Norway.
How do we know that transporting CO₂ in pipelines is safe?
Today CO₂ is transported in pipelines that extend over thousands of kilometres of land in North America. In Norway, there is 150 kilometres of CO₂ pipeline on the seabed from the Snøhvit field to Melkøya in Hammerfest.
Consequently, transporting CO₂ is completely safe if all the pipelines are specifically designed just for CO₂ transport. To find out what is needed, SINTEF has developed an advanced simulation model that can predict whether a crack or other damage to a CO₂ transport pipe can be developed into a continuous breach. The tool shows how the pipes themselves can prevent cracks from growing without the need to make the pipe walls unnecessarily thick or for other costly risk-reducing measures.
Attempting to over-dimension the pipelines to control fractures by increasing the wall thickness is a costly strategy. For a 500-kilometre-long pipeline with a 36-inch diameter, increasing the wall thickness by just three millimetres will add NOK 250 million (GBP £22.25) to the total cost given today’s steel prices.
The Norwegian oil industry has many decades of experience in pipe design and safety assessments related to natural gas pipeline transport. But CO₂ has differing properties than natural gas. Unlike natural gas, CO₂ boils as pressure decreases. If there is a hole in a CO₂ pipeline, up to ten times more energy is released compared to a leak in a natural gas pipeline.
Recently, SINTEF has used the simulation model to prepare projections for the Northern Lights project. This project is managed by Equinor with Shell and Total as partners and covers the transport and storage part of Norway’s demonstration project for full-scale CO₂ handling.
How do we know that underground storage of CO₂ is safe?
To date, all research and experience suggests that storage of CO₂ can be done safely if appropriate storage areas are selected.
A good example is Equinor’s pilot project at Sleipner, where 1 million tonnes of CO₂ per year has been injected into the pourous sandstone under denser layers of clay almost 1,000 metres under the seabed since 1996. SINTEF researchers many topics related to safety, but also cost-effective, storage:
One example of ongoing research is the SINTEF-coordinated Pre-ACT project, which is funded by the EU, the Research Council of Norway, Equinor, Shell and Total, among others.
In the project, researchers have access to monitoring data from important CO₂ storage demonstration plants. The data will be used to calibrate and demonstrate the value of the developed methods and to develop a “protocol” or recommendations.
The recommendations are developed as tools for operational decisions based on information about the pore pressure in the storage reservoir. This will help the operators maximize both safety and the storage capacity in a cost-effective way. The system will also be used to monitor the reservoirs.
Pre-ACT uses a large field lab for CO₂ storage: Svelvik CO₂ Field Lab. The field is located in a sand pit near Drammen in Norway and is managed by SINTEF. The lab consists of one injection well and four monitoring wells, all with instruments to measure what is happening both in the wells themselves and in the areas between the wells. This gives researchers even more unique data.
In addition, this field lab provides researchers with unique opportunities for testing new methods and equipment, such as fibre-optic sensors for CO₂ monitoring.
Sources and contributors to this article: Nils A. Røkke, Executive Vice President Sustainability at SINTEF and Chair of EERA, European Energy Research Alliance – Svend Tollak Munkejord, Chief Scientist at SINTEF Energy Research – Peder Eliasson, Senior Research Scientist at SINTEF Industry – Ane Lothe, Senior Research Scientist at SINTEF Industry – Mona Jacobsen Mølnvik, Research Director at SINTEF Energy Research – Alv-Arne Grimstad, Senior Research Scientist at SINTEF Industry – Olav Bolland, Dean of the Faculty of Engineering at the Norwegian University of Science and Technology, NTNU – Erik Lindeberg, Former Chief Scientist at SINTEF Industry – Aslak Einbu, Senior Research Scientist at SINTEF Industry, Karl Anders Hoff, Senior Research Scientist, SINTEF Industry and Maria Kristina Kollberg Thomassen, Research Manager at SINTEF Community.