How generative AI will reshape the global energy landscape | SLB
Generative AI

Generative AI is poised to reshape the global energy landscape

Shashi Menon
by  Shashi Menon

While the energy industry has been leveraging traditional AI and machine learning for several years now, generative AI promises to be a significant transformation in and of itself. Better modeling, optimized production, higher operational efficiency—the potential benefits are many. Given the vast amount of data available, energy companies are well-positioned to capitalize on this opportunity. The challenges? Data integration, security, and (of course) ethics.

5 min read
Global

In the next decade, generative AI will weave itself into the fabric of our lives in ways we can only begin to imagine. Consider the modern car. Equipped with features like blind spot monitoring and adaptive cruise control, vehicles are already considered intelligent machines, even though they often react to situations rather than anticipating them. Generative AI will shift this paradigm, transforming cars into proactive advisors that remain attuned to our needs and environments.

Imagine a busy professional with an important 8 a.m. meeting across town. With access to the driver's calendar, a generative AI-powered car could suggest leaving home at 6:45 a.m. to avoid anticipated traffic congestion. As departure time approaches, the car could pre-cool the cabin on a hot day. When the driver enters, it might suggest a relevant podcast or news channel for the commute. This is just a glimpse of how generative AI will revolutionize transportation. 

The energy industry is on the brink of a similar transformation. While traditional AI has been a valuable tool for years, generative AI holds the potential to reshape how we discover, access, and produce energy from a wide range of sources. Just as our cars are becoming more intelligent and advisory, so too will our energy systems.

The current role of generative AI in the energy industry 

Like other industries, the energy industry has been using traditional forms of AI and machine learning for years to enhance our processes and operations. Generative AI will bring a new dimension of capability.

Traditional AI excels at tasks like forecasting, optimization, and automation. It can analyze vast datasets to identify patterns and make predictions. In the energy sector, for example, traditional AI is used to predict energy demand, optimize wellsite operations, and detect anomalies in production equipment. 

Generative AI, on the other hand, focuses on creation and innovation. It can generate new ideas, code, and content, and even understand and respond to complex queries in a human-like manner. Beyond forecasting, generative AI can potentially design new energy systems, optimize complex energy models, or generate creative solutions to industry challenges. 

The foundation for generative AI lies in two key components:

  • Access to massive datasets
  • The computational power of GPUs to train large language models (LLMs). 
 

With our wealth of data on production, consumption, and infrastructure, the energy industry is well-positioned to benefit from generative AI.

While AI applications have matured across various segments of the energy industry, the integration of generative AI is still in its infancy. Many companies are experimenting with generative AI-driven solutions, but widespread adoption and tangible business impacts are still emerging. 

The good news is traditional AI applications like predictive maintenance, production forecasting, and asset optimization have laid the groundwork for more advanced AI capabilities. The energy sector is data-rich, providing fertile ground for AI development. That said, the potential of generative AI to revolutionize the industry is yet to be fully realized.

Where is the energy industry headed with generative AI? 

The energy industry stands at the precipice of a new paradigm, driven by the potential of generative AI. This technology promises to reshape the industry in profound ways, from exploration and production to distribution and consumption. 

Potential industry-altering applications of generative AI include the following: 

  • Data discovery and analysis—Analyze vast amounts of geospatial data to identify promising exploration areas, thereby optimizing exploration efforts and reducing costs.
  • Subsurface modeling—Generate multiple geological structures to enhance the interpretation of seismic data and improve the accuracy of identifying potential hydrocarbon reservoirs. 
  • Reservoir simulation—Create multiple reservoir simulation models to develop recovery strategies and allow for more accurate predictions of production performance.
  • Well performance optimization—Analyze production data to not only maximize hydrocarbon recovery and reduce costs but also suggest optimal well operating conditions. 
  • Facility optimization—Optimize the performance of production facilities by analyzing operational data to identify bottlenecks or inefficiencies. 
  • Digital twins—Create virtual representations of physical assets (from sensors and tools to equipment and facilities) to enable predictive maintenance, optimize operations, and accelerate decision making. 
  • Decarbonization—Accelerate the development of clean energy technologies, such as advanced batteries, hydrogen production, and carbon capture and storage
  • Energy efficiency—Analyze energy consumption patterns to identify optimization opportunities, thereby reducing energy costs and waste of wellsite and facility operations. 

These are just a few examples of the potential impact of generative AI on the energy industry—we'll see even more groundbreaking applications emerge as the tech continues to evolve. While our industry continues to make significant strides in AI adoption, challenges such as data quality, integration, and cybersecurity must be addressed to fully realize the potential of generative AI. Not to mention that the industry must also consider AI’s ethical implications, including its impact on jobs and the environment.

What that looks like―Achieving scale

Realizing the full potential of generative AI in the energy industry requires a concerted effort across multiple fronts. To achieve scale and widespread adoption, several key factors must be in place: 

  • Digital adoption—Embracing digital transformation is essential. This involves investing in robust data infrastructure, cloud computing capabilities, and advanced analytics platforms. Additionally, fostering a data-driven culture within organizations is crucial for successful AI implementation. 
  • Partnerships and collaborations—The complexity of energy systems necessitates collaboration among industry players, academia, and government. Partnerships can accelerate innovation, share knowledge, and reduce development costs. 
  • Open and extensible platforms—Developing open and interoperable platforms can facilitate the integration of different AI tools and data sources. This will foster a vibrant ecosystem of AI solutions and accelerate the pace of innovation. 

By addressing these areas, the energy industry can create an environment conducive to the widespread adoption and scaling of generative AI technologies. 

A visionary future for generative AI in the energy sector

Generative AI is poised to fundamentally reshape the energy industry, ushering in a new era of efficiency, sustainability, and innovation. By harnessing the power of data and computation, we can unlock unprecedented opportunities to optimize energy systems, accelerate the energy transition, and create a more resilient and sustainable energy future. 

The convergence of AI and energy will redefine how we produce, distribute, and consume energy. From the exploration of new energy resources to the design of smarter facilities and the development of cleaner technologies, generative AI will be a catalyst for progress. 

As we embark on this journey, it’s essential to foster collaboration, invest in research and development, and address the ethical implications of AI. By working together, we can harness the full potential of generative AI to build a more sustainable and prosperous energy future for generations to come.

 

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Shashi Menon

Vice President, Digital Technologies

Shashi leads a global team responsible for defining, developing, and deploying enterprise-grade digital platforms for the transformation of the energy industry. Prior to his current role, he led the overall product management for subsurface processing and interpretation digital technologies. In his more than 25 years at SLB, Shashi has had extensive product development experience in leveraging big data, high performance computing, AI, and machine learning to accelerate the digital transformation of customer workflows.

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