e-NG is electric natural gas derived from green hydrogen and CO2. TES H2 is a global green energy company leading the way in the production of e-NG. e-NG is easy to transport and store, which makes it a viable and scalable clean energy source. It is chemically identical to natural gas and blends easily into the existing fuel mix. This makes it a very simple and cost-effective solution for scaling up the green transition. By 2030, TES plans to produce around 15 TWh of e-NG annually, which is equivalent to 0.4 megatons of green hydrogen.
“We are excited to be working with TES on this innovative decarbonization project. By using recycled CO2 to deliver green energy to users, further CO2 emissions are being avoided, contributing to Germany’s goal to achieve Net-Zero greenhouse gas emissions by 2045. We aim to deliver our modular Just Catch 400 unit, which has gained high market interest since its recent launch”, said Jon Christopher Knudsen, Chief Commercial Officer at Aker Carbon Capture.
“We look forward to the collaboration with Aker Carbon Capture on our route towards net-zero. This evaluation of an industrial scale project will allow us to select the best of different available capture technologies based on real-life performance going forward in massive scale up”, said Jens Schmidt, Chief Technology Officer at TES.
CC in Germany
This is the third study awarded to Aker Carbon Capture in Germany, Europe’s largest economy and CO2 emitter. The country aims to cut its carbon dioxide emissions by 65% by 2030 compared with 1990 and to become carbon neutral by 2045. Carbon capture, utilization and storage (CCUS) has been identified as playing an important role in the country’s goal to achieve these targets. The German government is expected to publish its Carbon Management Strategy later this year.
The study awarded to Aker Carbon Capture will assess the optimal CO2 capture, conditioning, liquefaction and temporary storage facility. The captured CO2 will be the source material to produce e-NG, which is a sustainable alternative to fossil natural gas. It’s created by combining green hydrogen from renewable power with recycled CO2 from industrial emissions and biogenic CO2, to create “synthetic methane” or “green gas”. This conversion will take place in a region where green electricity and therefore green hydrogen is plentiful, making it highly cost effective.