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4 Jan 2022

Hydrogen holds great promise as a future sustainable fuel for transportation. For now, it’s a work in progress.


Hydrogen (H2) is the most abundant element on the planet and a contender as a sustainable fuel for the automotive, aviation, rail, and maritime sectors. Hydrogen fuel cells can store large amounts of clean electricity, far more than electric batteries and capacitors. However, about 90% of H2 produced today uses CO2-emitting natural gas and legacy-vapor forming technologies, which have a high environmental cost. The sustainable alternative to this “grey” H2 is “green” H2 using wind and solar power, whose only byproduct is water. The future success of hydrogen as a viable power source depends on the rapid growth of this next-generation “green” H2.

Of course, there are other challenges. Hydrogen is hard to transport due to leakage as its molecules can pass through plastic and weaken metal. It dilutes quickly in the air, is highly flammable, and is not cost-competitive with alternative energy sources. What’s more, each sector – automotive, aviation, rail, and maritime –requires a customized H2 value chain to be viable.


The main argument in favor of hydrogen fuel cells in electric vehicles is their superior range and fast recharge time compared to electric batteries. Yet, some in the automotive industry are skeptical about H2-powered cars. Tesla, Volkswagen, and Mercedes have all questioned the viability of H2 and have placed their bets on the electric battery to power their vehicles into the future.

Hydrogen deployment is blocked by the high cost of technology and infrastructure, which significantly increases the cost of fuel-cell electric vehicles (FCEVs) compared to battery-powered electric vehicles (EVs). This criticism is even more prevalent in the trucking sector. Still, large diesel trucks represent 40% of the transport sector’s greenhouse gas emissions and 5% of the fossil-fuel CO2 emissions. So hydrogen may have a role to play in the automotive industry, essentially when dealing with captive fleets and intensive usage that is not relevant for personal cars.


The situation is more complicated for aviation, which faces significant technical and safety challenges to incorporate hydrogen systems. The only solution for aviation is liquid hydrogen (LH2). But even in that form requires three times the volume of storage space compared to gasoline or diesel fuel. Also, LH2 would need to be kept below -253°C to remain a liquid, introducing thermal management issues. In addition, the use of hydrogen would also affect the airframe design by eliminating the option of wing fuel tanks.

This is best exemplified by the theCryoplane concept funded under the 5th Framework Program of the European Commission in 2000[1], or the recent “Pod” patents by Airbus[2]. In these designs, LH2wouldbe stored in pressurized cylindrical cryogenic tanks integrated into the fuselage or embedded in a single propeller-engine block. This would limit H2to regional, short-to-medium range air travel either as an alternative to kerosene in a modified gas turbine or as an electric generator emitting nearly zero greenhouse gases to power the electric motors.


The rail sector is a bright spot for H2, as it does not require massive electrification investments at the vehicle level, unlike cars, buses, and trucks. From an engineering perspective, railway diesel engines are already electrical; the diesel engine powers a generator that powers the train’s electric motor. Additionally, rail covers large distances every day, and the weight and volume of hydrogen tanks would not be a concern. The safety impacts could also be minimized by placing the tanks on the roof along with fans to dilute H2 leakage into the surroundings.


The maritime sector is interested in hydrogen to power ferries, barges, and even yachts using existing fuel cells up to 500 KW and cargo or large ferries that would require the development of 20MW fuel cells. Another usage is to eliminate diesel engines and heavy fuel that today generate onboard electricity when docked.

Given the heightened interest in H2, it is not surprising that the Auvergne-Rhône-Alpes, Bourgogne-Franche-Comté, Grand Est and Occitanie regions of France have signed the very first order for dual-mode hydrogen electric-hydrogen trains[3]. Jean-Baptiste Djebbari, Minister Delegate for Transport, French Ministry of the Ecological Transition, committed €47 million to develop hydrogen trains, while cities from San Francisco to Paris to Singapore are experimenting with H2 powered electric boats.

H2 is not expected to replace other fuels. Instead, it will be used in tandem with other fuel sources to find the best mix of resources, production, and storage systems to transport goods and people safely and reduce pollution at a competitive cost.

Capgemini is committed to being part of the hydrogen future and has several projects in the works, including:

  • Developing a model to include fuel cells as auxiliary systems in the powertrain of electric/hybrid vehicles
  • Designing systems that integrate hydrogen storage by optimizing the performance of storage equipment
  • Reducing manufacturing and operating costs and ensuring reliability

This is just the beginning.

[1]Fact sheet, “Liquid hydrogen fueled aircraft – system analysis (CRYOPLANE),” European Commission
[2]These pods could provide a blueprint for future hydrogen aircraft”, Dec. 15, 2020, Airbus
[3]Press release, “First order of hydrogen trains in France – a historic step towards sustainable mobility,” Apr. 8, 2021, Alstom


Jean-Luc Chabaudie

Group Research & Innovation – Director, Business Development, Capgemini Engineering

Dr. Alan Jean-Marie

Scientific Expert in Chemical Engineering
Dr. Alan Jean-Marie is Scientific Expert in Chemical Engineering for Capgemini Engineering. He joined Altran in 2011 and coordinates research projects in smart industry and new energy, including hydrogen. Alan has published over 30 papers in international journals and conferences. He has filed one patent and is a co-inventor on nine others.