Ethanolamine (MEA), a water-based solvent, has long been considered the “benchmark” solvent for post-combustion CO₂ capture. This is not because it is the best-performing solvent—it has relatively high energy requirements and is chemically unstable compared to newer alternatives.
Instead, MEA remains a reference point because there is an abundance of knowledge and public data about how it performs and how it degrades. Scientists have successfully identified more than 50 different by-products of MEA degradation and have accounted for all the nitrogen lost during this process. This means that the “mass and nitrogen balance” of MEA degradation is completely understood.
CESAR1: A Superior and Stable Alternative
While MEA is well studied, it is no longer the preferred choice for CO₂ capture. Newer solvents like CESAR1, a blend of piperazine (PZ) and 2-amino-2-methylpropan-1-ol (AMP), have replaced MEA because they are more stable and energy-efficient. CESAR1 was developed as part of the EU project CESAR (CO₂ Enhanced Separation and Recovery) between 2008 and 2011. This solvent has demonstrated excellent long-term stability and degrades much less than MEA, making it a more sustainable choice for industrial CO₂ capture.
The Need to Understand CESAR1’s Degradation
Although CESAR1 is highly stable, it is still important to understand how it breaks down when it does degrade. This is because degradation by-products can have negative impacts on the environment and plant operation. For example:
- Some degradation compounds, like carcinogenic nitrosamines, could be harmful to the environment and public health.
- Other compounds could interfere with plant operation by causing corrosion, accelerating further degradation, or creating unwanted issues like foaming.
To ensure the safe and smooth operation of CO₂ capture plants, researchers must fully identify and analyze all the possible degradation compounds CESAR1 can form. While it may not be necessary to track every single by-product continuously, it is crucial to identify all of them at least once. This will help pinpoint which compounds require regular monitoring to protect the environment and ensure efficient plant performance.
Understanding the degradation behavior of CESAR1 will provide the missing knowledge needed to operate CO₂ capture systems predictably and safely. This will not only ensure smooth industrial operation but also help minimize any environmental risks associated with solvent degradation.
Closing Knowledge Gaps – Density and Viscosity of Unloaded and CO2-loaded Aqueous AMP-PZ blends
AURORA’s latest scientific journal publication provides experimental density and viscosity data on different unloaded and CO2-loaded aqueous blends of 2-amino-2-methyl-1-propanol (AMP) and piperazine (PZ) used for absorption-based CO2 capture. The paper also provides correlations for density and viscosity suitable for various modelling works.In our previous review article, we identified knowledge…
Unlocking New Potential of CESAR1-based chemical absorption Technology: Available data and knowledge gaps of the CESAR1 solvent system
AURORA latest review paper, developed in collaboration with researchers from SINTEF and NTNU, provides a comprehensive analysis of the CESAR1 solvent system. It collects and evaluates existing experimental data, highlights knowledge gaps, and outlines the necessary next steps in research to optimize the use of CESAR1 for CO₂ capture.In the…
Conference publication – Optimal Control of Industrial Solvent-Based CO2 Capture Plants Conference publication
This publication, prepared by our project partners Cybernetica and SINTEF Industry, is a proceeding from the 34th European Symposium on Computer Aided Process Engineering and the 15th International Symposium on Process Systems Engineering (ESCAPE34/PSE24), held in Florence, Italy, from June 2-6, 2024.Researchers have developed and tested advanced methods to control…
Closing Knowledge Gaps – Density and Viscosity of Unloaded and CO2-loaded Aqueous AMP-PZ blends
AURORA’s latest scientific journal publication provides experimental density and viscosity data on different unloaded and CO2-loaded aqueous blends of 2-amino-2-methyl-1-propanol…
Unlocking New Potential of CESAR1-based chemical absorption Technology: Available data and knowledge gaps of the CESAR1 solvent system
AURORA latest review paper, developed in collaboration with researchers from SINTEF and NTNU, provides a comprehensive analysis of the CESAR1…
Conference publication – Optimal Control of Industrial Solvent-Based CO2 Capture Plants Conference publication
This publication, prepared by our project partners Cybernetica and SINTEF Industry, is a proceeding from the 34th European Symposium on…