Cementing the First Australian Offshore Carbon Capture and Storage Appraisal Well
Abstract: Analysis has consistently shown that carbon capture and storage (CCS) has an important role in meeting emission-reduction targets (IPCC, 2018). CCS wells require special design considerations to ensure long-term zonal isolation when exposed to carbon dioxide (CO2) because a complex set of chemical reactions leads to carbonation and dissolution of conventional cement sheaths. Several studies conducted into the long-term stability of different cement systems when exposed to wet supercritical CO2 a… Show more
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Cited by 4 publications
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First Application of a Novel Self-Healing and CO2-Resistant Cement on a Deepwater Cementing Operation
Harbour Energy began offshore exploration in the Andaman Sea in North Sumatra, Indonesia with the Timpan-1 well. During the planning phase, reservoir sections of the well were identified that contained circa 5-15% of CO2 levels as per the offset well data, which are corrosive environments and can cause cement sheath degradation. This paper presents the decision process used in selecting a suitable system for the CO2-rich environment and the first-time application of pumping novel self-healing and CO2-resistant cementing system with its capability to self-heal upon contact with CO2. Conventional Portland cement degrades in CO2-corrosive environments and combined with cement sheath damage by downhole stresses, long-term well integrity will be compromised. The auto repair capabilities provided by the novel cement system when in contact with CO2 leaking-fluids ensure long-term well integrity. Although self-healing-to-hydrocarbons cements have been widely used in the industry, use of this newly developed novel self-healing CO2-resistant cement was implemented for the first time in a primary casing job. To ensure blend consistency of the novel self-healing CO2-resistant cement, a number of quality control processes were developed with extensive laboratory testing and implemented for the complete blend lifecycle management. Implementation of this novel self-healing CO2-resistant cement in a deep-water primary casing job requires validation of crucial factors meet the requirements of achieving the long term well integrity. During the preparation phase, this cementing system was exposed to a high-CO2 corrosive environment over an extended period to analyze the robustness. The results showed superior properties compared with a conventional Portland system. The self-healing properties, analyzed with the use of an actual crack in the set cement and observed to the point where the crack closed, demonstrated continued cement integrity. Slurry stability tests produced excellent results. Blend flowability and robustness tests were performed at a regional laboratory using specialized equipment and determined the blend to be suitable for offshore operations. In implementation phase, by adhering to the project management process developed, the primary casing cement job was successfully performed without incident using conventional cementing equipment and practices. Good cement bond was obtained across the main zone, and the rig was able to continue its operations to perforate and well test the well. The 2001 Greenhouse Gas (GHG) Protocol's guidelines categorized business GHGs as scope 1 emissions, scope 2 emissions, and scope 3 emissions. The aim of this emission classification system was to help organizations measure and manage their carbon footprint (www.greenbusinessbureau.com 2022). Scope 1 emissions are GHGs released directly from a business. Scope 2 emissions are indirect GHGs released from the energy purchased by an organization. Scope 3 emissions are also indirect GHG emissions, accounting for upstream and downstream emissions from a product or service, and emissions across a business's supply chain. The novel self-healing CO2-resistant cement produces 63% less CO2 compared with a conventional Portland cement system. Implementing the novel slurry system will significantly reduce Scope 3 of CO2 emission that is embedded during the manufacturing of the materials used. In addition to that, due to its self-healing capability, the novel CO2-resistant cement will contribute on Scope 1 CO2 emission reduction by eliminating the need to perform remedial work in case of a well leak. The solution meets the long-term well integrity requirement and is in line with the global commitment to reduce the carbon emission footprint.
First Application of a Novel Self-Healing and CO2-Resistant Cement on a Deepwater Cementing Operation
Harbour Energy began offshore exploration in the Andaman Sea in North Sumatra, Indonesia with the Timpan-1 well. During the planning phase, reservoir sections of the well were identified that contained circa 5-15% of CO2 levels as per the offset well data, which are corrosive environments and can cause cement sheath degradation. This paper presents the decision process used in selecting a suitable system for the CO2-rich environment and the first-time application of pumping novel self-healing and CO2-resistant cementing system with its capability to self-heal upon contact with CO2. Conventional Portland cement degrades in CO2-corrosive environments and combined with cement sheath damage by downhole stresses, long-term well integrity will be compromised. The auto repair capabilities provided by the novel cement system when in contact with CO2 leaking-fluids ensure long-term well integrity. Although self-healing-to-hydrocarbons cements have been widely used in the industry, use of this newly developed novel self-healing CO2-resistant cement was implemented for the first time in a primary casing job. To ensure blend consistency of the novel self-healing CO2-resistant cement, a number of quality control processes were developed with extensive laboratory testing and implemented for the complete blend lifecycle management. Implementation of this novel self-healing CO2-resistant cement in a deep-water primary casing job requires validation of crucial factors meet the requirements of achieving the long term well integrity. During the preparation phase, this cementing system was exposed to a high-CO2 corrosive environment over an extended period to analyze the robustness. The results showed superior properties compared with a conventional Portland system. The self-healing properties, analyzed with the use of an actual crack in the set cement and observed to the point where the crack closed, demonstrated continued cement integrity. Slurry stability tests produced excellent results. Blend flowability and robustness tests were performed at a regional laboratory using specialized equipment and determined the blend to be suitable for offshore operations. In implementation phase, by adhering to the project management process developed, the primary casing cement job was successfully performed without incident using conventional cementing equipment and practices. Good cement bond was obtained across the main zone, and the rig was able to continue its operations to perforate and well test the well. The 2001 Greenhouse Gas (GHG) Protocol's guidelines categorized business GHGs as scope 1 emissions, scope 2 emissions, and scope 3 emissions. The aim of this emission classification system was to help organizations measure and manage their carbon footprint (www.greenbusinessbureau.com 2022). Scope 1 emissions are GHGs released directly from a business. Scope 2 emissions are indirect GHGs released from the energy purchased by an organization. Scope 3 emissions are also indirect GHG emissions, accounting for upstream and downstream emissions from a product or service, and emissions across a business's supply chain. The novel self-healing CO2-resistant cement produces 63% less CO2 compared with a conventional Portland cement system. Implementing the novel slurry system will significantly reduce Scope 3 of CO2 emission that is embedded during the manufacturing of the materials used. In addition to that, due to its self-healing capability, the novel CO2-resistant cement will contribute on Scope 1 CO2 emission reduction by eliminating the need to perform remedial work in case of a well leak. The solution meets the long-term well integrity requirement and is in line with the global commitment to reduce the carbon emission footprint.
Deployment of Self-Healing CO2 Resistant Cement for Carbon Capture and Storage Wells in Eastern Australia
Carbon capture and storage (CCS) is a vital technology in the fight against climate change. Eastern Australia is an important site for CCS activities where one of the operators is starting a CCS project with target to store 1.7 million metric tons (MMT) of CO2 per year, ensuring enhanced safety and permanence in the same reservoirs that have securely held oil and gas for millions of years. This paper explores the benefits of deploying novel cementing technology in CCS wells in Eastern Australia. CO2 injection leads to a corrosive environment, which can cause cement sheath degradation. This paper presents the decision-making process used in selecting a suitable cementing system for the CO2-rich environment post-injection, and the first-time application of a self-healing and CO2-resistant cementing system in Australia. The operator is committed to safer operations throughout the life of the well by providing long-term well integrity for the CCS wells. The failure of cement sheaths due to the degradation of conventional Portland cement in a CO2 corrosive environment can lead to significant environmental risks. The newly developed, self-healing CO2-resistant cement can withstand the effects of carbonation, making it superior compared to conventional cement systems in a CO2 environment. The deployment of this self-healing CO2-resistant cement system technology for the CCS wells in Eastern Australia has the potential to significantly improve wellbore integrity. This technology offers several benefits, including improved resistance to mechanical stresses and vibrations, resistance to chemical attack, and low permeability. In case of loss of the integrity, when the cement sheath is exposed to CO2 leaking fluids, it has the capability to self-heal and restore the long-term well integrity. Several crucial challenges were addressed for successful delivery, including the remoteness of Eastern Australia, limited accessibility to the location, job frequency, and handling at the third-party uniquely equipped blending facility. All challenges were addressed through rigorous quality control processes developed from extensive laboratory testing and comprehensive blend lifecycle management. Post-job result analysis included running wireline logs to confirm the annular barrier. Cement evaluation logs outcomes were excellent and exceeded expectations. Overall, the deployment of novel self-healing CO2-resistant cement system technology for the CCS wells in Eastern Australia ensures safer, more environmentally responsible CCS operations.
Establishing Best Practices for Well Abandonment in CCS
In CO2 storage sites, wells located within the predicted area of review, and that penetrate the confining zone, may become a leakage pathway out of the injection zone if not properly abandoned. Prior to injection, the abandonment focus is on existing (legacy) wells. After injection has concluded, the focus will expand to include storage development wells, e.g., injector and monitoring wells. Unlike oil and gas developments, where formation fluids are produced, Carbon Capture and Sequestration (CCS) projects inject CO2 into downhole formations, creating a plume that must be contained within the target reservoirs for periods of time that are longer than oil and gas wells’ life span. These differences make it necessary to develop CCS-specific well abandonment practices. The authors have analyzed industry-accepted well abandonment standards, abandonment recommendations and requirements from regulators for CCS projects, and several case studies and laboratory experiments on well integrity to develop an understanding of the challenges and probable solutions for CCS well abandonment. Then, a recommended practice for well abandonment in CO2 storage sites that addresses isolation of the confining and reservoir zones, the effects of a CO2-rich environment on well materials, and corrective action for legacy wells will be presented. Most of the existing regulations and standards on CCS establish expectations and objectives for well abandonment without providing detailed guidelines that can be consistently applied across projects. Without consistent rules for CCS well abandonment, project teams will conduct design or planning exercises that will have varying outcomes as they adapt conventional well abandonment guidelines to CO2 storage site requirements. This may result in under- or over-designing the well abandonment; which could translate into compromised well integrity, impact on project value; and an ever-changing technical standpoint. The aim of a recommended practice is to establish simple high-level principles with which to approach well abandonment in CO2 storage sites to facilitate the work of project teams and to have an acceptable level of consistency on abandonment plans. This paper will demonstrate a comprehensive abandonment strategy for CCS and legacy wells. The strategy addresses CCS-related containment concerns and local applicable abandonment regulations for all other sources of inflow not related to CCS. It discusses how the ability of a confining zone to stop the flux of CO2 through it, that depends on its permeability, thickness and capillary pressure; is relevant for establishing CCS abandonment principles.
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