Dr. Andreas Bodén, Senior Vice President and Chief Technology Officer of fuel cell systems developer PowerCell shares with Manifold Times the potential of hydrogen fuel cells with methanol reformer technology as a solution in maritime industry’s transition towards net-zero-emission: 

 As the maritime industry transitions towards net-zero emissions, renewable fuels have been at the forefront in advancing sustainable shipping. According to Hydrogen Europe’s “Long-term outlook on zero-emission mobility” survey, e-fuels hold the most promise for various ship types, including ferries, cruise ships, and container vessels. 

Among these e-fuel options, methanol reformer technology is emerging as a potential solution in this transition. This technology can convert methanol into hydrogen onboard through steam reforming, enabling proton-exchange membrane (PEM) fuel cells with 30% greater efficiency than internal combustion engines, paving the way for compact, high-power, and net-zero energy solutions without relying on pure hydrogen infrastructure.

Hydrogen, often dubbed the building block of the energy transition, emerges as a viable option for certain vessels with fixed or shorter routes, such as passenger ferries and service vessels. However, its practicality for wider-scale use in deep-sea shipping has significant challenges related to supply of green molecules and energy density, as well as storage, transport, and handling.

Methanol addresses these challenges by serving as an easy and efficient liquid hydrogen carrier. It is easy to handle, store, and transport at ambient temperature and pressure. By serving as a hydrogen carrier, methanol overcomes the logistical obstacles of hydrogen fuel while still enabling the use of high-efficiency fuel cells. This symbiosis positions methanol and fuel cells as key players in scaling renewable fuels for the maritime industry. 

Dr. Andreas Bodén, Senior Vice President and Chief Technology Officer of PowerCell

Efficient use of scarce resources

Green fuels like renewable methanol face significant hurdles, from scaling production to securing offtake agreements. Marine economist Dr. Martin Stopford warns that shipping might lag behind other sectors, such as road transport and chemicals, in accessing renewable fuels. At the same time, the Methanol Institute tracks nearly 90 green methanol projects aiming to produce 9 million tons annually by 2027, some of which will benefit the marine industry.

Despite the level of optimism, renewable methanol will be a scarce and a costly resource for the foreseeable future. Lloyd’s Register estimates its initial cost at around $1,000 per ton, which is significantly higher than conventional fuels. Shipowners must therefore maximise efficiency, reducing the volume of renewable fuel required and mitigating operating expenses.

Methanol’s energy density surpasses hydrogen and ammonia but falls short of hydrocarbon fuels. Lloyd’s Register highlights that ship operators would require two and a half times more methanol than traditional fuel oil for equivalent energy output. This disparity underscores the necessity of adopting more efficient propulsion systems.

Fuel cells: A pathway to efficiency

Fuel cells with methanol reformer technology offer a solution. These systems can convert methanol into hydrogen onboard through steam reforming, producing energy from methanol 30% more efficiently than internal combustion engines. PEM fuel cells which can use this technology stand out for their compact size, efficiency, and high-power density. These technologies enable net-zero energy generation without the need for pure hydrogen infrastructure.

For smaller vessels like ferries and towboats, fuel cells can serve as the primary propulsion system, reducing renewable methanol consumption by up to 30%. Larger ships, such as container vessels, can use fuel cells to power auxiliary engines, eliminating emissions from fossil-fuel generators during port operations. Renewable methanol further curbs nitrogen oxide (NOx) emissions by up to 80%, while eliminating sulphur oxide (SOx) and particulate matter (PM) emissions. These benefits can be enhanced when using an internal combustion engine (ICE) or a fuel cell with reformer technology specifically designed to reduce local pollutants. 

Beyond methanol, fuel cell reformer technology can be developed for ammonia. This adaptability offers a pathway to the efficient use of ammonia as a future zero-carbon solution. This flexibility also allows shipowners to adopt renewable methanol now and transition to other fuels as they become viable.

Balancing sustainability and efficiency

The IMO’s revised GHG strategy targets net-zero emissions for international shipping by 2050, with interim milestones for 2030 and 2040. Achieving these goals requires efficient use of renewable fuels and innovative propulsion systems. PowerCell’s Methanol to Power Solution, M2Power 250, exemplifies the potential to enhance fuel efficiency and reduce operational costs. 

As the maritime industry is responsible for 3% of global GHG emissions, fuel cells with methanol reformers represent a practical solution. Whether powering smaller vessels or auxiliary systems on deep-sea ships, this technology bridges the gap between the current fuel limitations and the future of sustainable shipping. 

The marine industry must embrace innovative solutions to achieve net-zero emissions. Fuel cell technology, with its unparalleled efficiency and fuel optionality, positions many shipowners best to navigate the challenges of the energy transition. 

Photo credit: PowerCell
Published: 6 February, 2025