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CCUS: Indonesia’s Strategic Solution Toward a Low-Carbon Future

Infographic on Carbon Capture, Utilization, and Storage (CCUS) in Indonesia, showing national CO₂ emission trends, geological storage potential in saline aquifers and depleted oil & gas reservoirs, and key CCUS project sites supporting the country’s Net Zero 2060 target.

Indonesia is currently at a crucial stage in its journey toward a low-carbon energy future. As energy demand continues to rise and global pressure to reduce emissions intensifies, Carbon Capture, Utilization, and Storage (CCUS) technology emerges as one of the most strategic solutions to maintain the balance between energy security and environmental sustainability.

Indonesia’s CO₂ Emission Profile

As one of the most populous countries in the world, Indonesia contributes significantly to global carbon emissions. Recent data show that Indonesia’s carbon dioxide (CO₂) emissions have sharply increased from 35.8 million tons (Mt) in 1970 to approximately 729 million tons (Mt) in 2022. This surge is mainly driven by the dominance of fossil fuels—such as coal, oil, and natural gas—in the national energy mix.

Figure 1. CO₂ Emission Trends in Indonesia (1970–2022). Source: Ramadhan et al. (2024) based information from Ritchie & Roser (2023).

Rapid economic and population growth accelerate the increase in energy demand, while the use of renewable energy remains relatively low. This condition underlines the urgency for Indonesia to adopt emission reduction technologies such as CCUS to achieve the Net Zero Emission 2060 target.

The technology of CCUS offers a concrete solution: capturing carbon emissions directly from their sources (such as factories, refineries, or power plants) and safely storing them underground to prevent their return to the atmosphere.

Potential CO₂ Storage Sites in Indonesia

According to Ramadhan et al. (2024) in Energy Geoscience, Indonesia possesses gigaton-scale carbon storage capacity—one of the largest in Southeast Asia. This potential is distributed across several major geological formations:

  1. Depleted Oil & Gas Reservoirs
    Mature oil and gas fields offer great potential for Enhanced Oil/Gas Recovery (EOR/EGR) while serving as CO₂ storage sites. Total capacity: approximately 2,822 MtCO₂ (≈ 2.82 GtCO₂). Main locations: Sumatra and Java.
  2. Saline Aquifers
    Underground saline aquifer formations provide the largest storage capacity. Total capacity: 335,884 MtCO₂ (≈ 335.8 GtCO₂). Main locations: Sumatra, Java, and Kalimantan (Borneo).
  3. Geological Storage Zones
    Areas with porous rock layers, such as sandstone and limestone, also have potential for long-term, safe, and stable carbon storage. Total capacity: 13,863 MtCO₂ (≈ 13.86 GtCO₂). Most located in Sumatra and Java.

With a total potential exceeding 350 GtCO₂, Indonesia holds a tremendous opportunity to become a carbon storage hub in the Asian region.

Figure 2. Carbon (CO₂) Storage Potential in Indonesia by Geological Formation Type. Source: Ramadhan et al. (2024) based information from Zhang & Lau (2022); Bokka & Lau (2023)..

Map of CCUS Project Development in Indonesia

Currently, various CCUS projects have been developed and are being implemented across Indonesia, including:

  • Tangguh CCUS (West Papua) – Target operation 2026
  • Sakakemang CCS (South Sumatra) – Target operation 2028
  • Central Sumatra Basin CCUS Hub – Target operation 2028
  • Kutai Basin and Sunda Asri CCUS Hubs (Kalimantan & Java) – Target operation 2029
  • Ramba EOR (South Sumatra) – Target operation 2030

These initiatives demonstrate Indonesia’s strong commitment to integrating research, technology, and industry in reducing national carbon emissions.

Figure 3. Map of CCUS in Indonesia. Source: Ramadhan et al. (2024) based information from Sidemen (2023).

Why CCUS Matters for Indonesia

Climate change has become a real global challenge, and Indonesia stands at the forefront of efforts to reduce carbon emissions without compromising economic growth. Amid the growing energy demand and dependence on fossil fuels, Carbon Capture, Utilization, and Storage (CCUS) technology serves as a strategic solution that bridges the transition toward clean and sustainable energy.

Through the implementation of CCUS, Indonesia can gain several key benefits that directly impact the energy, industrial, and environmental sectors, including:

  • Significantly reducing carbon emissions from heavy industry and energy sectors.
  • Maintaining national industrial competitiveness amid global carbon policies and regulations.
  • Extending the lifespan of national oil and gas assets through CO₂-based Enhanced Oil Recovery (EOR) projects.
  • Attracting investment and technology transfer in clean energy and low-carbon innovation.
  • Supporting the Net Zero Emission 2060target while opening new opportunities for a green economy.

With its rich geology and technical expertise in the energy sector, Indonesia has a strong foundation to lead CCUS implementation in Asia—becoming a bridge between academic research, technology, and real-world industrial application.

Conclusion

The technology of Carbon Capture, Utilization, and Storage (CCUS) is not merely a concept of the future but a real solution that has already begun implementation in various regions across Indonesia. The deployment of CCUS will be the key to transitioning toward a low-carbon economy, while strengthening Indonesia’s position as a leader in sustainable energy in Southeast Asia.

To achieve this, cross-sector collaboration—among government, industry, and research institutions such as OGRINDO ITB—will be a critical success factor.

📩 Let’s Collaborate!
For research collaboration, industrial partnership, or further information about CCUS innovation, contact us via email: info@ogrindoitb.com

📚 References:

  • Ramadhan, R., Mon, M. T., Tangparitkul, S., Tansuchat, R., & Agustin, D. A. (2024). Carbon Capture, Utilization, and Storage in Indonesia: An Update on Storage Capacity, Current Status, Economic Viability, and Policy. Energy Geoscience, Vol. 5, 100335.
  • Ritchie, H., & Roser, M. (2023). CO₂ and Greenhouse Gas Emissions. Our World in Data.
  • Zhang, L., & Lau, H. (2022). Carbon Storage Assessment in Southeast Asia. Energy Reports, 8, 1250–1265.
  • Bokka, S., & Lau, H. (2023). Economic Feasibility of Carbon Capture, Utilization, and Storage (CCUS) in Developing Economies. International Journal of Greenhouse Gas Control, 127, 103765.
  • Sidemen. (2023). Current Landscape of CCUS Development in Indonesia.
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News Article

CCUS in Action: Global Success Stories and Lessons for Indonesia’s Low-Carbon Future

CCUS in Action global success stories Sleipner CarbFix and lessons for Indonesia’s low carbon future with OGRINDO ITB research on carbon capture utilization and storage.

In facing the challenge of climate change, Carbon Capture, Utilization, and Storage (CCUS) technology has become one of the proven, real-world solutions globally. From offshore CO₂ storage to natural mineralization into rock, flagship projects in Norway and Iceland have demonstrated that carbon emissions can not only be controlled but also utilized to create new economic value. With a scientifically verified track record of implementation, CCUS has now become a vital pillar in the transition toward a cleaner and more sustainable energy future.

Toward a Low-Carbon Future Through the Implementation of Scientifically Verified CCUS Technology

Amid the urgency of the global energy transition, Carbon Capture, Utilization, and Storage (CCUS) technology has become one of the main pillars in efforts to reduce carbon emissions. Through implementation in various countries, CCUS has proven effective not only in reducing greenhouse gas emissions but also in enhancing economic efficiency and energy industry sustainability.
The following two global success stories show that low-carbon solutions are not merely concepts — they are already a reality.

Sleipner (Norway): A Pioneer in Offshore CO₂ Storage

Launched in 1996 by Equinor (formerly Statoil), the Sleipner Project is located in Sleipner West gas field, approximately 250 km southwest of Stavanger, Norway, in the Central North Sea. This project is the world’s first commercial CCS project, injecting CO₂ separated from natural gas into the Utsira Formation situated about 800–1000 meters below sea level. To date, more than 16 million tons of CO₂ have been safely stored in the Utsira Formation. The success of Sleipner is supported by rigorous 3D seismic and gravimetric monitoring systems, ensuring no CO₂ leakage from the storage layer. With efficient storage costs, the project proves that CCS can operate safely and economically while complying with Europe’s strict environmental regulations.

Diagram and platform of the Sleipner Project in the North Sea, Norway — the world’s first commercial CCS project, which has safely stored more than 16 million tons of CO₂ since 1996. Source: Solomon (2007), Bellona Foundation; Equinor.

CarbFix (Iceland): Turning CO₂ into Stone

Beneath Iceland’s basaltic subsurface, the CarbFix Project transforms the concept of CCS into something more permanent — natural mineralization. By dissolving CO₂ into water and injecting it into reactive basalt rocks, more than 95% of the CO₂ is converted into carbonate minerals.
The advantage of this method lies in long-term storage security: carbon is converted into solid minerals, eliminating the risk of leakage. To date, CarbFix has stored more than 100,000 tons of CO₂ beneath Iceland. The rapid mineralization method developed by the project is now being adapted in various countries — including Norway, the United States, and India — through research initiatives applying similar principles to permanently store carbon in basaltic rocks.

Process schematic and location of the CarbFix Project at the Hellisheidi Geothermal Power Plant near Reykjavík, Iceland. The project permanently converts CO₂ into carbonate rock beneath the basaltic subsurface. Source: Matter & Kelemen (2021), Nature Reviews Earth & Environment; Reuters.

What Indonesia Can Learn

Indonesia has a carbon storage potential of approximately 400 gigatons of CO₂ across various geological formations — including oil and gas reservoirs, deep sandstones, and saline aquifer distributed in Sumatra, Kalimantan, and Java. This potential places Indonesia among the countries with the largest carbon storage capacity in Southeast Asia.
However, experiences from Sleipner (Norway) and CarbFix (Iceland) show that the sustainability of Carbon Capture, Utilization, and Storage (CCUS) implementation depends not only on technology but also on a robust supporting ecosystem: regulation, collaboration, and public trust.

Map of CCS/CCUS projects currently under development in Indonesia. The illustration highlights potential carbon storage locations in key strategic regions. Source: Wibisono, N. (2024), “CCS in Indonesia,” Energy Geoscience.

1️⃣ Strong and Adaptive Regulatory Framework
An important step has begun with Presidential Regulation No. 14 of 2024 concerning the Implementation of Carbon Capture and Storage (CCS) Activities, which serves as Indonesia’s first national legal framework comprehensively regulating CCS implementation. This regulation defines key terms, licensing mechanisms, and business and technical schemes for CCS. It provides clarity on CO₂ storage rights, responsibilities, and post-closure monitoring mechanisms.

In addition, the Ministry of Energy and Mineral Resources (ESDM) has issued a Technical Guideline for CCS/CCUS Implementation, serving as a reference for industries and research institutions in conducting feasibility studies, injection design, and field monitoring.

2️⃣ Cross-Sector Collaboration
In line with global practices, the successful implementation of CCS/CCUS in Indonesia requires synergy among the government, the energy industry, academia, and research institutions. This is where the role of the Bandung Institute of Technology (ITB) and OGRINDO ITB becomes crucial — bridging laboratory research, reservoir modeling, and field testing with industry needs.
Collaboration with national oil and gas companies such as Pertamina Subholding Upstream and international partners also opens vast opportunities for CCS/CCUS pilot project , particularly in mature oil fields.

3️⃣ Scientific Monitoring and Data Transparency
From the experiences of Sleipner and CarbFix, it has been proven that science-based monitoring and data transparency are key factors in maintaining public trust and long-term project sustainability. Sleipner, for instance, has conducted 4D seismic monitoring and gravimetric surveys for over 20 years to ensure CO₂ storage safety, while CarbFix makes its research data publicly available to promote innovation and global collaboration.

A similar approach can be applied in Indonesia — by establishing open monitoring and reporting systems accessible to government, academia, and the public, thereby strengthening trust in CCUS implementation.

Through this integrated approach, Indonesia has a great opportunity to replicate global success and realize its first commercial CCS/CCUS project by 2026, as outlined in the National Energy Transition Roadmap. Currently, several national energy companies have initiated CCS/CCUS feasibility studies at multiple oil and gas fields, including the Gundih Field (Central Java) and the Tangguh Field (West Papua), both targeted as pilot projects before 2026. These early implementations will lay the foundation for a long-term carbon storage ecosystem in Indonesia. The success of these pilot projects will mark a crucial milestone in achieving the Net Zero Emission 2060 target. Net Zero Emission 2060.

🌱 From Research to Action

CCUS technology is not merely a future solution — it is a strategic investment to ensure national energy sustainability and industrial competitiveness in the green transition era. Through collaborative research, technological innovation, and knowledge transfer, OGRINDO ITB is committed to supporting the development of CCS/CCUS from laboratory stages to field-scale implementation.

With clear policies, multi-sector collaboration, and strong scientific foundations, Indonesia is ready to move from research to real-world implementation — turning carbon from a burden into an opportunity to build a clean, globally competitive energy future.

📩 Interested in collaborating on CCS/CCUS research?
📩 Contact us: info@ogrindoitb.com

Let’s accelerate the journey toward Net Zero Emission 2060 and build a resilient, clean, and globally competitive Indonesian energy future.

📚 References

  • Furre, A.-K., Eiken, O., Alnes, H., Vevatne, J. N., & Kiær, A. F. (2017). 20 years of monitoring CO₂-injection at Sleipner. Energy Procedia, 114, 3916–3926.
  • Snæbjörnsdóttir, S. Ó. et al. (2020). Carbon dioxide storage through mineral carbonation. Nature Reviews Earth & Environment, 1, 90–102.
  • Ramadhan, R. et al. (2024). Carbon capture, utilization, and storage in Indonesia. Energy Geoscience, 5, 100335.
  • CarbFix Official Website

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