New study reveals how high temperatures alter shale’s strength and storage potential, with implications for energy, CO2 storage and environmental strategies
As demand grows for cleaner, more efficient energy sources, techniques like geothermal energy extraction and carbon capture and storage (CCS) are becoming increasingly important. Shale, a sedimentary rock rich in organic matter, is critical in each of these processes. However, despite the rock’s significance, there has been limited understanding of how its mechanical properties—its strength, elasticity, and resistance to deformation—change as it matures under high-temperature and high-pressure conditions. This gap in knowledge has significant implications: without understanding how shale behaves when heated, industries risk costly inefficiencies in gas extraction, potential failure in carbon storage, and instability in geothermal systems.
A team of researchers led by Khalifa University’s Dr. Muhammad Arif has revealed how shale transforms mechanically as it progresses from ‘mature’ to ‘over-mature’ stages. The research team used atomic force microscopy and nano-indentation, two advanced techniques that allow scientists to observe and measure strength at an atomic scale. Their findings clarify how shale’s structural properties evolve, offering insights that could improve the efficiency and safety of energy and environmental applications.
“Understanding shale’s thermal evolution gives us a blueprint for designing better energy extraction and storage systems, from fracking to carbon sequestration.”
— Dr. Muhammad Arif, Associate Professor, Chemical & Petroleum Engineering, Khalifa University
With researchers from China University of Petroleum, Dr. Arif published the results in the , a top 1% journal.
“Shale’s microstructural characteristics at different stages of maturity directly affect the design and success of gas extraction and storage processes,” Dr. Arif explained. “As shale heats up, does it become stronger or weaker? How do these changes affect its suitability for hydraulic fracturing or CO2 storage? For example, during hydraulic fracturing, water, sand and chemicals are injected into shale to release gas, which requires knowledge of how the rock will respond under intense pressure. Previous studies have provided only broad insights, lacking the nanoscale detail needed to truly understand shale’s behavior.”
Additionally, as the world seeks more effective methods to decarbonize the energy and industrial sectors, the need for secure, permanent CO₂ storage has become urgent within the framework of carbon capture, utilization and storage. Injecting CO₂ into shale deposits, where it must remain securely trapped for long periods, requires precise knowledge of how shale responds to long-term exposure to high temperatures and pressures. Rock mechanical properties also play a key role in geothermal energy applications, where it is important to predict whether the rock can retain stability under fluctuating temperatures and pressures.
By focusing on how temperature-induced changes affect shale’s ability to withstand pressure and resist fracturing, this study provides a foundation for designing safer, more efficient energy and environmental systems.
The research team subjected samples from the Longmaxi Formation—a well-known shale source in China’s Sichuan Basin—to pyrolysis, a controlled high-temperature process that simulates the rock’s natural evolution under geothermal conditions. The team noted changes in material stiffness as the shale was heated, as well as structural changes in the rock’s pore network.
“This densification has major implications for hydraulic fracturing, as a stiffer rock matrix with smaller pore spaces requires different fracturing strategies to release gas efficiently,” Dr. Arif said. “The denser structure also suggests an improved ability to trap gases such as CO₂, enhancing the rock’s suitability for carbon sequestration.”
In shedding light on shale’s mechanical evolution, this study lays the groundwork for more efficient and reliable strategies in natural gas extraction, carbon sequestration, and geothermal energy. As researchers continue to explore shale’s nanoscale properties, the energy industry stands to benefit from innovations that make energy extraction more productive and environmentally responsible. The insights from this study move us closer to unlocking shale’s full potential in a sustainable energy landscape.
Jade Sterling
Science Writer
