In early November 2024, ICorr Aberdeen was pleased to announce the very first Joint Webinar Week between ICorr and CSCP (Chinese Society for Corrosion and Protection) which consisted of five lunchtime presentations held over an eight-day period.
| No | Date | Speaker Name | Job Title | Organisation | Presentation Title |
| 1 | Monday 11th November 2024 | Dr Anqing Fu | Director of corrosion research team | CNPC Tubular Goods Research Institute | Corrosion research progress in oil and gas and new energy industry. |
| 2 | Tuesday 12th November 2024 | Professor Yong Xiang | Professor and doctoral supervisor | China University of Petroleum, Beijing | Spontaneous inhibition phenomena of corrosion in CCUS system and their mechanisms. |
| 3 | Thursday 21st November 2024 | Dr Di Wang | Associate professor of material science and engineering | Northeastern University, Shenyang | The mechanism and protection of microbial corrosion in oil and gas field. |
| 4 | Friday 22nd November 2024 | Dr Mindong Chen | Associate Research Fellow | SINOPEC Research Institute of Safety Engineering, Qingdao | Optimising corrosion resistance of low-alloy steel for the refining industry by corrosion big data methods. |
| 5 | Monday 25th November 2024 | Dr Xinpeng Lu | CEO | Corrosion X Technology Co., Ltd. | Progress in the application of generative artificial intelligence in the cathodic protection industry. |
Summaries of the webinars are shown in the table below, which included five individual presentations from members of CSCP. The CSCP/ICorr Webinar series was arranged by ICorr President-elect Dr Yunnan Gao and President Stephen Tate, after the signing of a Memorandum of Understanding (MoU) at the 22nd International Corrosion Congress held in Xi’an, China.
- The five sets slides have all now been uploaded to ICorr website with the link as https://www.icorr.org/aberdeen/ Refer to local technical programme.
- Meeting Recordings: All the five meeting recordings have also been uploaded to ICorr YouTube channel at ICorr YouTube Channel.
- Summary Post on LinkedIn: The summary of this event has been posted on linkedIn. The link to the post is LinkedIn Post for ICorr-CSCP Webinar Week.
Presentation 1 – Corrosion Research Progress in Oil & Gas and New Energy Industry by Dr Anqing Fu
Dr Anqing (Andy) Fu is the Director of Corrosion and Protection Research Center of CNPC TGRI (Tubular Goods Research Institute of China National Petroleum Corporation). Dr. Fu graduated from University of Calgary in 2010 and obtained PhD degree in energy and environment. Andy has more than 14 years of working experience in corrosion and protection of the oil & gas industry, and he specialises in electrochemical corrosion, stress corrosion cracking, corrosion failure analysis of OCTG, anti-corrosion techniques (inhibitor, organic/metallic coating, and clad pipe) R&D, and pipeline and wellbore integrity management.
Abstract: Corrosion is a great threat in the oil and gas industry, including upstream oil and gas fields, middle-stream transmission pipelines, and downstream refineries. Much more attention needs to be paid to corrosion not merely due to the economic issue in terms of oil and gas loss but also to safety and environmental considerations. Firstly, several typical case studies of downhole tubing and gathering pipeline corrosion collected from the field were analysed. Secondly, microbiologically influenced corrosion (MIC) in the shale gas production system was investigated. MIC is prevalent in the shale gas production system due to the bacteria generation in recycled fracture fluid. Thirdly, Carbon Capture, Utilisation, and Storage (CCUS) is a substantial measure to realise carbon neutrality, while CO2-induced corrosion is nonnegligible. Typical failures in terms of supercritical CO2 corrosion, sour impurity gas-induced stress corrosion cracking, and packer rubber sealing failure were analysed in CCUS-CO2 injection and production wells. Fourthly, hydrogen is regarded as the ultimate clean energy; pipelines are regarded as the most economical and effective means for transporting H2 in a gaseous state. The difference between gaseous hydrogen and ionic (cathodic) hydrogen-induced damage to pipelines was compared, and three typical facilities for gaseous hydrogen-mechanical interaction, gaseous hydrogen permeation, and content tests by TDS were introduced. Finally, corrosion protection technologies developed by CNPC TGRI, including inhibitors, organic coatings, and metallurgically clad pipes, were introduced; moreover, several challenges for corrosion and protection research in the oil and gas and new energy industries were summarised.
Presentation 2 – Spontaneous Inhibition Phenomena of Corrosion in CCUS System and Their Mechanisms by Professor Yong Xiang
Yong Xiang serves as a professor and doctoral supervisor at the College of Mechanical and Transportation Engineering, China University of Petroleum, Beijing. He is the director of the Laboratory for Low Carbon Energy Equipment and Materials Protection and the deputy dean of the Ocean Engineering Institute. He received both his bachelor’s and doctoral degrees from Tsinghua University, and he was also the post-doctoral researcher of Ohio University. Yong Xiang is an active member of several committees under the China Society for Corrosion and Protection, including the Corrosion Inhibitors and Water Treatment, Oil and Gas Field and Pipeline Corrosion and Safety, and Non-metallic Corrosion-Resistant Materials committees.
Abstract: Carbon capture, utilisation, and storage (CCUS) technology has been considered for reducing CO2 emissions and improving energy efficiency. However, during the capture process, impurities such as O2, SO2, and NO2 are present, which accelerate corrosion of transportation pipelines and wells. Nevertheless, research also found several interesting corrosion inhibition phenomena in the system. This study summarised the spontaneous corrosion inhibition phenomena during the capture and transportation process and outlined the corresponding inhibition mechanisms. These included the corrosion inhibition mechanisms of the degradation products of organic amines and the inhibition behaviour of SO2 on CO2 corrosion processes. Additionally, this study also proposed several corrosion inhibition methods in CCUS system. Understanding these corrosion inhibition mechanisms is considered crucial for corrosion control of CCUS facilities.
Presentation 3 – The Mechanism and Protection of Microbial Corrosion in Oil and Gas Field by Dr Di Wang.
Di Wang is an associate professor of material science and engineering at Northeastern University in Shenyang, China. He focuses on the mechanism and mitigation research of microbiologically influenced corrosion in the oil and gas industry. His research activities are aimed at deciphering the electron transfer mechanism of classic corrosive microbes of sulphate-reducing bacteria, investigating eco-friendly natural D-amino acids as green biocide enhancers combined with commercial biocides to kill the bacteria, and modifying the microbial sample methods in the oil and gas field.
Di Wang obtained his doctorate degree at Ohio University in Athens, United States, in 2022. From June 2022, he continued his research of MIC in the oil and gas industry at Northeastern University. He has published 27 peer-reviewed research papers, including 16 first-author papers. He also joined the working group—AMPP Standard 21495 of Laboratory Evaluation of the Effect of Biocides on Biofilms.
Abstract: Microbial corrosion of metal materials in the oil and gas field industry causes serious economic losses and threatens energy security. For the mechanism research of microbial corrosion, deciphering the electron transfer mechanism of microbes in a complicated oil and gas environment is a critical point to having a better understanding of microbial corrosion. Electron mediators like riboflavin and magnetite nanoparticles promote the indirect electron transfer and distinguish electron transfer microbial corrosion from other corrosion. Both could be useful tools in a microbial corrosion sensor to distinguish the corrosion mechanism. The indirect electron transfer mediated by hydrogenase genes plays a role in promoting sulphate-reducing bacteria corrosion, but it was not found to be a dominant role in the corrosion process, which denied the previous classical theory of Cathodic Depolarisation Theory coming out in 1934. For the protection research of microbial corrosion, physical methods like pigging and chemical treatments such as biocide dosing are used to mitigate microbial corrosion in the oil and gas industry, but they lead to problems like environmental concerns, high operational costs, and low efficacy in the same system after prolonged applications. Alternatively, eco-friendly natural D-amino acids as green biocide enhancers combined with commercial biocides to kill the bacteria can be used to block the electron transfer between bacteria and metal surfaces and disperse the sessile cells from the metal surfaces.
Presentation 4 – Optimising Corrosion Resistance of Low-Alloy Steel for the Refining Industry by Corrosion ‘Big Data’ Methods by Dr Mindong Chen
Dr Mindong Chen is an associate research fellow at the Department of Equipment Safety at the SINOPEC Research Institute of Safety Engineering, Qingdao, China. Mindong undertakes technical R&D in the field of equipment safety at the SINOPEC Research Institute of Safety Engineering and the National Institute of Hazardous Chemicals Safety (Qingdao). His primary research areas include material corrosion and protection, equipment condition monitoring, and equipmentintegrity management. He has published over twenty SCI papers, including two ESI Hot Papers, and holds more than thirty patents. Chen serves as a reviewer for multiple international journals and has led projects funded by the National Key R&D Program of China, SINOPEC Corporation, and the National Natural Science Foundation of China. His achievements include a First Prize in Science and Technology Progress from the Chinese Society for Corrosion and Protection, a Second Prize in Management and Technological Innovation from the China Association of Plant Engineering, a Third Prize in Technological Invention from SINOPEC Corporation, and a Second Prize in Management Innovation from the SINOPEC Corporation.
Abstract: The refining and chemical industry plays a crucial role in national economic development and is integral to national industry. Among materials used in this industry, steel is predominant, facing complex corrosive media and environmental loads. Mindong Chen has focused on the corrosion mechanisms within typical environments, aiming to improve the corrosion resistance of metal materials by leveraging corrosion big data and addressing the material requirements for crude oil refining equipment. Key areas of focus have included: Interface-diffusion behaviour in corrosion of low-alloy steel: Chen’s research has investigated the electrochemical corrosion behaviours of low-alloy steel under the kinetic and diffusion-controlled phases. Mechanisms and correlation rules of alloy elements in inhibiting corrosion diffusion: For long-term service materials, specific corrosion resistance indicators, such as corrosion product film thickness and FeO OH content, have been analysed. Chen has correlated these indicators with alloy composition using methods like Spearman and Pearson correlations, as well as non-linear mutual information, achieving high consistency with traditional theories. The optimisation theory of corrosion resistance for low-alloy steel in corrosive environments has been utilised: In complex, multi-factor environments, a complex relationship exists between alloy components and corrosion resistance. By applying neural networks, Chen has established quantitative relationships between environmental factors, alloy elements, and corrosion resistance indicators. Through high-throughput time-scale correlation, this work has provided an optimised alloy composition formula tailored for multi-factor coupled corrosion environments, based on microalloying strategies. His report presented in detail Chen’s work in advancing the theoretical and practical understanding of corrosion resistance in steel alloys within the refining and chemical industry.
Presentation 5 – Progress in the Application of Generative Artificial Intelligence in the Cathodic Protection Industry by Dr Xinpeng Lu.
Dr Xinpeng Lu is CEO of Corrosion X Technology Co., Ltd., based in Shenzhen, China. Dr. Lu has 18 years of experience in the field of corrosion and protection of oil and gas facilities, integrity management, and artificial intelligence. Dr. Lu is a Director of the Chinese Society of Corrosion and Protection (CSCP), a member of the specialised Society on Cathodic Protection Technology, and a member of the specialised Committee on Intelligent Diagnosis of Facility Health. Additionally: • A member of International Gas Union (IGU) Transmission and Distribution Committee. • An AMPP Cathodic Protection specialist (CP4), Integrity Management Technologist (PCIM). • A Manager-level member of British Gas Association (IGEM). • A Member of Standardisation Committee of China City Gas Association. Dr Lu has directed and implemented the cathodic protection gas and storage support project, which won the highest award for civil engineering in China, the Tien-yow Jeme Civil Engineering Prize, twice, in 2021 and 2022.
Abstract: This paper reviewed the application status and development trend of generative artificial intelligence technology in the cathodic protection industry. As an important technical means for metal corrosion protection, cathodic protection has particular problems such as complex data analysis and high experience dependence in its design, monitoring, and maintenance. With the rapid development of generative AI technologies such as large language models (LLM) and diffusion models, new ideas have been provided to solve these industry problems. This paper introduced the application of generative AI in cathodic protection design optimisation, including parameter configuration optimisation and protection potential distribution prediction; secondly, it analysed the application cases in cathodic protection system operation monitoring, such as anomaly detection and life prediction; and discussed the practice in the field of maintenance decision support, including fault diagnosis and maintenance suggestion generation. Studies have shown that generative AI technology can effectively improve the design efficiency and operational reliability of cathodic protection systems and has broad application prospects. However, in practical applications, it still faces challenges such as model accuracy, generalisation ability, and knowledge updating. In the future, it is considered necessary to further strengthen algorithm innovation, data accumulation, and industrial practice to promote the in-depth application of generative AI technology in the field of cathodic protection.
The Aberdeen branch was very proud to be asked to host these prestigious presentations for which there were extensive question and answer sessions, documented in the five meeting recordings uploaded to the ICorr YouTube Channel at ICorr YouTube Channel Feedback to date has been extremely favourable, and a further series of ICorr-CSCP joint webinars will take place later in 2025. Please contact the Aberdeen Branch Chair meiling.cheah@gmail.com if you wish to present, or for any further information on upcoming events and check www.icorr.org/events/
Photo: Dr Anqing Fu.
Figure 1: Dr Anging Fu. in the Opening Presentation at the CSCP/ICorr Webinar Series.
Photo: Professor Yong Xiang.
Photo: Dr Di Wang.
Photo: Dr Mindong Chen.
Photo: Dr Xinpeng Lu.
