South Korea is Studying Marine Carbon Capture: What is this Technology and What are its Applications?
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South Korea has outfitted the 2,200 TEU vessel HMM Mongla, with advanced onboard carbon capture systems. This pioneering project is a collaboration among major industry players, including Samsung Heavy Industries, Hyundai Marine Solutions, Panasia, and Korea Register.
With this initiative, the Korean government plans to?reduce greenhouse gas emissions by 4.8 million tons by 2030. Onboard carbon capture is an emerging field of research with immense potential as a key tool in the pursuit of carbon neutrality. These carbon capture technologies are estimated to reduce CO? emissions by between 82% to 90%.
In the case of South Korea, the aim is to explore the seas surrounding the Korean peninsula to assess the CO2 storage capacity. This plan forms part of the?First National Carbon Neutral and Green Growth Basic Plan?that aims to capture and store carbon to reduce?greenhouse gas emissions.
Goal: carbon neutrality by 2050
The aim of this project is to reduce greenhouse gas emissions by 4.8 million tons by 2030, and?reach carbon neutrality by 2050.?To achieve this, facilities need to be constructed with the capacity to capture one billion tons of CO2 below the seabed.
In 2021, Korea updated its 2030 national greenhouse gas emission goal, known as Nationally Determined Contribution (NDC), from 26.3% to 40%.
This year, the KNOC oil corporation and the Hyundai Heavy Industries Group began developing an offshore CO2 storage platform with the aim of storing around 400,000 tons of carbon dioxide per year. This is located 58 km from the Ulsan coast and it is set to be inaugurated next year and operate for 30 years.
Seven public and private organizations are taking part in this initiative with KNOC, including the Korean Energy Technology Evaluation and Planning Institute and various Korean universities and companies such as SK Earthon, which is also currently advancing CCS business development in the United States, Australia and Southeast Asia.
The South Korean project: pioneering carbon capture and eliminating emissions
The project has gained substantial? backing with DNV, the world’s leading classification society and maritime industry advisor, granting approval for the integrated design of the onboard carbon capture system on the HMM Mongla. Following rigorous testing, DNV has confirmed that this Korean carbon capture technology is both feasible and ready to meet new regulatory requirements. Moreover, this technology is adaptable for use across various types of vessels.
This technology uses a patented amine solvent to capture CO? from combustion gases. The captured CO? is then subjected to a heat-induced chemical reaction, which separates it from the solvent.
Subsequently, the released CO2 is liquefied using Babcock LGE’s ecoCO2? system and stored on board the ship in pressurized low-temperature storage for subsequent offloading. The process’s effectiveness is enhanced by the ability to reuse the solvent, establishing a sustainable regenerative cycle.
The next step will be to conduct operational-level testing of these capture systems. This paper explains that among the candidate sites are the depleted gas reservoirs in the Ulleung Basin (UB) and the saline aquifer in the Gunsan Basin (GB), located in the East Sea and Yellow Sea respectively.
Plans are under development to store approximately 1.2 MtCO2/year in the UB and 1 MtCO2/year in the GB. For the UB, the utilization of the existing 68 km natural gas pipeline has been suggested along with the proposal for new pipeline construction.
For the GB, because of the lack of existing onboard CCS infrastructure, the plan includes the construction of a new pipeline of approximately 175 km, including a terrestrial hub terminal.
Benefits and challenges of carbon capture
Carbon capture, use and storage (CCUS) is the process of capturing carbon dioxide emissions produced by fossil fuels and industrial processes to be stored deep underground. The captured CO2 is compressed into a liquid state and transported to a storage site. It is finally injected into the seafloor or in rock formations for permanent storage.
Advantages of CCUS
The captured carbon can also be reused to manufacture biofuels, construction materials, such as concrete, chemicals and plastics.
Carbon capture and storage is one of the most affordable ways of achieving net zero emissions. According to the International Energy Agency (AIE), it is one of the four key pillars of global energy transitions together with renewables-based electrification, bioenergy and hydrogen.
The main uses of carbon capture are:
In order to fulfil the Paris Agreement and the 2030 Agenda for Sustainable Development, countries must develop CO2 capture strategies.
Challenges of CCUS
However, like all clean technologies, carbon capture systems introduce new challenges.
Similar projects in other countries
Northern Lights onshore facility
There are 30 carbon capture projects in the world, 11 under construction and 153 in various stages of development, according to the Global CCS Institute. The CO2 capture capacity of all CCS facilities reached 244 million tons in 2022, a growth of 44%.
Most projects are in the United States, followed by Europe -mainly the United Kingdom, Holland and Norway-, Asia and the Middle East. These are some of the CO2 storage projects currently being developed in Europe under the seabed:
Korea’s initiative to extend its carbon storage projects under the seabed aims to gradually eliminate conventional resources and achieve carbon neutrality by 2050.