Hydrogen has long been heralded as a cornerstone of the clean energy future, offering a pathway to drastically reduce our reliance on fossil fuels and mitigate the devastating impacts of climate change. However, despite its immense promise, hydrogen’s practical deployment is hampered by significant hurdles in its storage and transportation. Conventional methods typically rely on either compressing hydrogen gas at extremely high pressures or liquefying it at cryogenic temperatures. Both techniques are costly and technically demanding, posing major challenges for scaling hydrogen infrastructure on a global level.
In a revolutionary approach, researchers at King Abdullah University of Science and Technology (KAUST) have explored the potential of Liquid Organic Hydrogen Carriers (LOHCs) as a practical, safe, and scalable alternative for hydrogen storage. LOHCs are carbon-based molecules capable of chemically bonding with hydrogen, transforming into stable hydrogen-rich liquids that can be handled far more easily than hydrogen gas. This technology promises to leverage existing petrochemical infrastructure, sidestepping the need for expensive and complex new facilities.
The KAUST team pushed the boundaries of LOHC application by investigating whether these compounds could be stored underground in depleted oil fields—a novel idea that marries energy storage with enhanced oil recovery. Their simulations focused on sandstone reservoirs typical of Saudi Arabia’s oil-producing regions, exploring the interplay between LOHC characteristics and subsurface conditions at depths around 2,200 meters. The findings suggest that certain LOHCs can not only store large quantities of hydrogen securely but also coax residual oil from these aging reservoirs, providing a dual economic and environmental benefit.
Central to this study was the evaluation of two distinct LOHC systems. The first employed toluene, a well-known petrochemical, which chemically bonds with hydrogen to form methylcyclohexane. Both molecules boast stability and availability, with toluene storing roughly 6.2 percent of its weight in hydrogen. Methylcyclohexane’s low viscosity allows it to flow smoothly underground, making it especially suitable for injection and recovery in porous rock formations.
Simulations revealed a promising operational cycle where methylcyclohexane was injected into the depleted reservoir over a five-month period, followed by a two-month rest phase, and then extracted over another five months. Repeating this yearlong injection-extraction cycle 15 times demonstrated that roughly 75 percent of the methylcyclohexane could be recovered each cycle. Remarkably, the process also enhanced oil recovery by more than 50 percent over the simulation period. This synergy implies that the value generated by extracting additional oil could offset the costs of hydrogen storage, with total net benefits estimated at around $70 million.
In sharp contrast, the second LOHC system examined, despite having a higher hydrogen capacity per molecule, stumbled due to its elevated viscosity. The thicker liquid faced greater resistance during underground injection and extraction, reducing efficiency and recovery. This highlights the critical balance between hydrogen storage density and flow properties that must be optimized for successful field deployment.
While the enhanced oil recovery aspect might seem contradictory to climate goals, leading to some downstream carbon dioxide emissions, experts argue these are minimal compared to the climate advantages achieved through widespread hydrogen utilization. Using LOHCs for hydrogen storage in depleted fields provides a viable stepping stone to decarbonization by leveraging existing fossil infrastructure during a transitional energy phase.
Moreover, the chemical nature of LOHCs secures hydrogen effectively, enabling storage under mild conditions without the need for high-pressure or cryogenic technologies. This feature drastically reduces technical risks and lowers barriers for integration into current fuel distribution networks, including pipelines, tankers, and large storage facilities, facilitating faster adoption.
The KAUST researchers now aim to expand their models to more complex multi-well reservoir systems, reflecting more realistic oil field infrastructures where multiple injection and production wells operate simultaneously. Such scenarios could reveal additional dynamics in the interaction between LOHCs, hydrogen, and subsurface geology, potentially optimizing storage and recovery processes on a commercial scale.
This innovative approach offers a hopeful avenue for reconciling the urgent need for hydrogen-based clean energy with practical and economic feasibility. By transforming depleted oil fields into dual-purpose hydrogen storage and oil recovery sites, LOHC technology could accelerate the transition to a low-carbon energy system while leveraging and repurposing existing infrastructure.
Importantly, this research underscores the value of interdisciplinary strategies—blending chemistry, petroleum engineering, and environmental science—to tackle complex energy challenges. As the world presses forward in its quest to reduce carbon emissions, innovations like LOHC-based underground hydrogen storage highlight how existing resources and emerging technologies can be aligned to create sustainable energy solutions.
In conclusion, the deployment of LOHCs as subterranean hydrogen carriers not only addresses technical and economic obstacles but also introduces a pragmatic blueprint for integrating renewable hydrogen within the fossil fuel landscape. If successfully scaled, this approach could play a pivotal role in shaping the global energy transition, making clean hydrogen more accessible and commercially viable while contributing to incremental oil recovery that financially supports the venture.
Subject of Research: Liquid Organic Hydrogen Carriers for underground hydrogen storage and enhanced oil recovery
Article Title: Techno-economic assessment of field-scale storage for liquid organic hydrogen carriers: dual benefits of energy storage & incremental oil recovery
News Publication Date: 15-Apr-2026
Web References: https://doi.org/10.1016/j.fuel.2025.137906
References: Tariq, Z., AlSubhia, M., Alia, M., Kumara, N., Alissab, F., Ghamdi, A., & Hoteit, H. Fuel 410, 137906 (2026).
Keywords
Liquid Organic Hydrogen Carriers, LOHC, Hydrogen Storage, Enhanced Oil Recovery, Residual Oil, Sustainable Energy, Carbon Emissions, Subsurface Storage, Methylcyclohexane, Toluene, Fossil Fuel Transition, Energy Infrastructure
Tags: carbon-based hydrogen carriersclean energy storage innovationscost-effective hydrogen storage alternativesenhanced oil recovery with hydrogenhydrogen storage in depleted oil fieldshydrogen storage in sandstone reservoirshydrogen transportation challengesliquid organic hydrogen carriers technologypetrochemical infrastructure for hydrogensafe hydrogen storage methodsscalable hydrogen infrastructure solutionsunderground hydrogen storage techniques
