Abstract The energy industry is grappling with a critical trilemma: balancing energy security, affordability, and sustainability amid increasing complexity. To meet these demands, modern petroleum engineers must master the full pore-to-process spectrum—linking subsurface understanding to surface facility design and operations. This integrated capability is essential to maximize hydrocarbon recovery, minimize costs, and reduce environmental impact throughout the production lifecycle. Traditional training programs comprising pre-school, e-learning pathways, instructor-led schools, and extensive on-the-job training modules have historically been effective (Lozada, O., 2014). However, the rapid pace of industry evolution demands a more dynamic and future-ready approach. This paper introduces a transformative enhancement to the traditional training program in 2023. The program focuses on developing deep petroleum engineering expertise, including geological understanding, petrophysical interpretation, rock physics analysis, fluids analysis, reservoir modelling with simulation,well performance, network optimization, flow assuranceand process engineering. It integrates classroom theories with practical, hands-on exposure in industry-grade workshops and laboratories, covering downhole data acquisition hardware operations, rock and fluid analysis to well and surface facilities equipment. Furthermore, knowledge delivery is made more effective by leveraging no-code and low-code solutions for petroleum engineering modelling, simulation, and AI-based problem-solving, enabling participants to rapidly prototype and apply advanced tools without extensive programming knowledge. Additionally, the framework emphasizes modularization and maintaining the lineage between training modules, ensuring cohesive, adaptive, and efficient learning pathways. Agile material development is leveraged alongside advanced technologies such as machine learning and embedded AI for petroleum engineering applications. These advancements enable engineers to deepen their core expertise in petroleum engineering while broadening their knowledge laterally across domains, including subsurface, production engineering, data analytics, and AI. This comprehensive and integrated approach fosters adaptive learning, collaboration, and alignment with emerging industry tools and challenges. Global implementation of this enhanced program has yielded significant results, with key performance indicators validating the program's success with net promoter score (NPS) reaching 73.49% in 2024, far surpassing the industry average of 49%. The program has also proven effective in igniting participants’ learning interest by enabling them to deliver impactful solutions to real-world industry problems. By fostering continuous development at their own pace, it empowers individuals to build confidence and stay engaged in their learning journey. Additionally, it has accelerated the deployment of skilled petroleum engineers, enabling them to effectively deliver complex field development and storage planning projects worldwide. By integrating proven methodologies with cutting-edge innovations, this framework offers a scalable and forward-looking solution to produce the next generation of petroleum engineers for the demands of today's energy sector. This initiative introduces a paradigm shift by embedding interdisciplinary collaboration, modular learning pathways, and rapid adoption of emerging technologies, setting a new benchmark for petroleum engineering education in addressing the challenges of the energy transition.
Yew et al. (Tue,) studied this question.
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