Categories
Project News

Achieving Milestones in CO2 Electrolysis: MS9 and MS10

In the progressive world of CO2 Electrolysis, milestones MS9 and MS10 mark significant advancements, albeit with unique challenges. The recent achievement in MS9 was notable, as the cell potential reached an impressive 300mA/cm2 at 2V per cell. This indicates a substantial improvement in efficiency and performance, albeit not fully meeting the set milestone.

Achieving Milestones in CO2 Electrolysis: MS9 and MS10

Turning to MS10, significant strides were made in material selection. The milestone involved the critical selection and freezing of Gas Diffusion Layers (GDLs) and catalysts for both anode and cathode sides. This decision is crucial as it lays the foundation for the future efficiency and reliability of the fuel cells.

However, these advancements didn’t come without their challenges. One of the primary issues encountered was the stability of the test in terms of operational hours. This was primarily due to the clogging of the flow field, a result of salt precipitation. This phenomenon poses a significant threat to the consistent operation and longevity of the fuel cells.

In response to these challenges, researchers and engineers are diligently studying new procedures to mitigate these issues. Developing strategies to avoid clogging and ensure uninterrupted operation is a top priority. Another obstacle that surfaced was related to the scaling up of the substrate and the supplying materials. This highlights the complexities involved in transitioning from laboratory-scale successes to large-scale, commercially viable solutions.

Despite these challenges, the progress made in milestones MS9 and MS10 is a testament to the ongoing innovation in CO2 Electrolysis. As solutions to these challenges are developed, we can expect further advancements in this promising field, paving the way for more sustainable and efficient energy solutions.

Source: CNR & DeNora

Categories
Related Topics

Carbon Under the Sea: A Promising Solution to Climate Change

The ocean covers about 71% of the Earth’s surface and contains about 50 times more water than the atmosphere. It is also a major sink for carbon dioxide, absorbing about 20% of the carbon dioxide that is released into the atmosphere each year.

Carbon Under the Sea: A Promising Solution to Climate Change
Carbon Under the Sea: A Promising Solution to Climate Change

The deep seabed is even more efficient at absorbing carbon dioxide than the upper layers of the ocean. This is because the deep seabed is cold and under high pressure, which makes it more difficult for carbon dioxide to escape.

The Benefits of Storing Carbon Dioxide in the Ocean

There are several potential benefits to storing carbon dioxide in the ocean. First, it is a large and relatively secure storage space. The ocean is vast and deep, and the deep seabed is covered by a layer of sediment that helps to protect the carbon dioxide from being released.

Second, storing carbon dioxide in the ocean could help to reduce ocean acidification. Ocean acidification occurs when the ocean absorbs carbon dioxide, which makes the water more acidic. This can harm marine life, such as coral reefs and shellfish.

Third, storing carbon dioxide in the ocean could help to mitigate climate change. By removing carbon dioxide from the atmosphere, it can help to slow the rate of global warming.

The Risks of Storing Carbon Dioxide in the Ocean

While there are several potential benefits to storing carbon dioxide in the ocean, there are also some potential risks. One risk is that the carbon dioxide could react with seawater and form harmful compounds. These compounds could potentially harm marine life or even humans.

Another risk is that the carbon dioxide could be released back into the atmosphere if the deep seabed is disturbed. This could happen if there is an earthquake or other natural disaster. It could also happen if humans accidentally disturb the seabed.

More Research Needed

More research is needed to assess the risks and benefits of storing carbon dioxide in the ocean. However, if the technology can be developed safely and effectively, it could offer a promising solution to climate change.

The Future of Carbon Dioxide Storage in the Ocean

The potential of storing carbon dioxide in the ocean is a promising area of research. If the technology can be developed safely and effectively, it could offer a significant contribution to the fight against climate change.

There are currently several projects underway to explore the feasibility of storing carbon dioxide in the ocean. One project, called the Northern Lights project, is being developed by a consortium of companies in Norway. The project would involve injecting carbon dioxide into the deep seabed off the coast of Norway.

Another project, called the Carbfix project, is being developed by a consortium of companies in Iceland. The project would involve injecting carbon dioxide into basalt rock, which would react with the carbon dioxide to form stable carbonate minerals.

These are just two examples of the many projects that are underway to explore the potential of storing carbon dioxide in the ocean. As the technology continues to develop, it is likely that we will see more projects of this nature in the future.

Conclusion

The potential of storing carbon dioxide in the ocean is a promising area of research. If the technology can be developed safely and effectively, it could offer a significant contribution to the fight against climate change.

Learn more about the potential of storing carbon dioxide in the ocean at: https://www.ciphernews.com/carbon-under-the-sea