and
Toyota FCHV, the world's first government-certified commercial fuel cell vehicles. This would require hydrogen to be produced cleanly, for use in sectors and applications where cheaper and more energy efficient mitigation alternatives are limited.
Rockets was the first to use liquid hydrogen Many large rockets use
liquid hydrogen as fuel, with
liquid oxygen as an oxidizer (LH2/LOX). An advantage of hydrogen rocket fuel is the high
effective exhaust velocity compared to
kerosene/
LOX or
UDMH/
NTO engines. According to the
Tsiolkovsky rocket equation, a rocket with higher exhaust velocity uses less propellant to accelerate. Also the
energy density of hydrogen is greater than any other fuel. LH2/LOX also yields the greatest efficiency in relation to the amount of propellant consumed, of any known rocket propellant. A disadvantage of LH2/LOX engines is the low density and low cryogenic temperature required to maintain of hydrogen as a liquid, which means bigger and insulated and thus heavier fuel tanks are needed compared to methane, although methane is more polluting. Another disadvantage is the poor storability of LH2/LOX-powered rockets: Due to the constant hydrogen boil-off, the rocket must be fueled shortly before launch, which makes cryogenic engines unsuitable for
ICBMs and other rocket applications with the need for short launch preparations. For first stages, dense fuelled rockets in studies may show a small advantage, due to the smaller vehicle size and lower air drag. LH2/LOX were also used in the
Space Shuttle to run the fuel cells that power the electrical systems. The byproduct of the fuel cell is water, which is used for drinking and other applications that require water in space.
Automobiles , there were two hydrogen cars publicly available in select markets: the
Toyota Mirai and the
Hyundai Nexo. The
Honda Clarity was produced from 2016 to 2021.
Hydrogen combustion cars are not commercially available. In the light road vehicle segment, by the end of 2022, 70,200 fuel cell electric vehicles had been sold worldwide, compared with 26 million plug-in electric vehicles. In 2023, 3,143 hydrogen cars were sold in the US compared with 380,000 battery electric vehicles. With the rapid rise of
electric vehicles and associated battery technology and infrastructure, the global scope for hydrogen's role in cars is shrinking relative to earlier expectations. John Max of
Hydrogen Fuel News believes that hydrogen may, however, be used directly, or as a feedstock for efuel, to keep classic cars on the road. The first road vehicle powered by a hydrogen fuel cell was the Chevrolet Electrovan, introduced by
General Motors in 1966. The
Toyota FCHV and
Honda FCX, which began leasing on December 2, 2002, became the world's first government-certified commercial hydrogen fuel cell vehicles, and the
Honda FCX Clarity, which began leasing in 2008, was the world's first hydrogen fuel cell vehicle designed for mass production rather than adapting an existing model. Honda established the world's first fuel cell vehicle dealer network in 2008, and at the time was the only company able to lease hydrogen fuel cell vehicles to private customers. The 2013
Hyundai Tucson FCEV, a modified Tucson, was introduced to the market as a lease-only vehicle, and
Hyundai Motors claimed it was the world's first mass-produced hydrogen fuel cell vehicle. However, due to high prices and a lack of charging infrastructure, sales fell far short of initial plans, with only 273 units sold by the end of May 2015.
Hyundai Nexo, which succeeded the Tucson in 2018, was selected as the "safest SUV" by the Euro NCAP in 2018, but In October 2024, Hyundai recalled all 1,600 Nexo vehicles sold in the US to that time due to a risk of fuel leaks and fire from a faulty "pressure relief device".
Toyota launched the world's first dedicated mass-produced fuel cell vehicle (FCV), the
Mirai, in Japan at the end of 2014 and began sales in California, mainly the
Los Angeles area and also in selected markets in Europe, the UK, Germany and Denmark later in 2015. The car has a range of and takes about five minutes to refill its hydrogen tank. The initial sale price in Japan was about 7 million yen ($69,000). Former European Parliament President
Pat Cox estimated that Toyota would initially lose about $100,000 on each Mirai sold. At the end of 2019, Toyota had sold over 10,000 Mirais, but in 2024 (through November), Toyota's worldwide sales fell to 1,702 hydrogen fuel cell vehicles. Many automobile companies introduced demonstration models in limited numbers (see
List of fuel cell vehicles and
List of hydrogen internal combustion engine vehicles). In 2013
BMW leased hydrogen technology from
Toyota, and a group formed by
Ford Motor Company,
Daimler AG, and
Nissan announced a collaboration on hydrogen technology development. In 2015, Toyota announced that it would offer all 5,680 patents related to hydrogen fuel cell vehicles and hydrogen fuel cell charging station technology, which it has been researching for over 20 years, to its competitors free of charge to stimulate the market for hydrogen-powered vehicles. By 2017, however, Daimler had abandoned hydrogen vehicle development, and most of the automobile companies developing hydrogen cars had switched their focus to battery electric vehicles. By 2020, all but three automobile companies had abandoned plans to manufacture hydrogen cars. The
Honda CR-V e:FCEV became available, for lease only, in very limited quantities in 2024. In 2024, Mirai owners filed a
class action lawsuit in California over the lack of availability of hydrogen available for fuel cell electric cars, alleging, among other things, fraudulent concealment and misrepresentation as well as violations of California’s false advertising law and breaches of implied warranty.
Heavy trucks The International Energy Agency's 2022 net-zero emissions scenario sees hydrogen meeting approximately 30% of heavy truck energy demand in 2050, mainly for long-distance heavy freight (with battery electric power accounting for around 60%).
United Parcel Service began testing of a hydrogen powered delivery vehicle in 2017. In 2020,
Hyundai began commercial production of its
Xcient fuel cell trucks and shipped ten of them to
Switzerland. In 2022 in Australia, five hydrogen fuel cell
class 8 trucks were placed into use to transport zinc from Sun Metals'
Townsville mine to the
Port of Townsville, Queensland, to be shipped around the world.
Aeroplanes Fuel Cell Demonstrator powered by a hydrogen fuel cell ,
Lange Aviation, and the
German Aerospace Center are pursuing hydrogen as fuel for crewed and uncrewed aeroplanes. In February 2008 Boeing tested a crewed flight of a small aircraft powered by a hydrogen fuel cell. Uncrewed hydrogen planes have also been tested. For large passenger aeroplanes,
The Times reported that "Boeing said that hydrogen fuel cells were unlikely to power the engines of large passenger jet aeroplanes but could be used as backup or auxiliary power units onboard." In July 2010, Boeing unveiled its hydrogen-powered
Phantom Eye UAV, powered by two Ford internal-combustion engines that have been converted to run on hydrogen.
Ships hydrogen fuel cells are not suitable for propulsion in large long-distance ships but are being considered as a range-extender for smaller, short-distance, low-speed electric vessels, such as ferries. Hydrogen in
ammonia is being considered as a long-distance fuel.
Buses Fuel-cell buses were
trialed in
Ursus Lublin in 2017.
Solaris Bus & Coach introduced its
Urbino 12 hydrogen electric buses in 2019. Several dozen were ordered. The first city in the U.S. to have a fleet of hydrogen powered buses was
Champaign, Illinois, when in 2021 the
Champaign–Urbana Mass Transit District ordered two New Flyer XHE60 articulated hydrogen fuel cell buses, with 10 more New Flyer XHE40 buses added in 2024. In 2022, the city of
Montpellier, France, cancelled a contract to procure 51 buses powered by hydrogen fuel cells, when it found that "the cost of operation for hydrogen [buses] is 6 times the cost of electricity". By 2025, most hydrogen bus programs in Europe had been cancelled or fuel cell bus purchases discontinued.
Fork trucks A
hydrogen internal combustion engine (or "HICE")
forklift or HICE lift truck is a hydrogen fueled,
internal combustion engine-powered industrial forklift truck used for lifting and
transporting materials. The first production HICE forklift truck based on the Linde X39 Diesel was presented at an exposition in
Hannover on May 27, 2008. It used a 2.0 litre, diesel internal combustion engine converted to use hydrogen as a fuel with the use of a compressor and
direct injection. In 2013 there were over 4,000
fuel cell forklifts used in
material handling in the US. As of 2024, approximately 50,000 hydrogen forklifts are in operation worldwide (the bulk of which are in the U.S.), as compared with 1.2 million battery electric forklifts that were purchased in 2021. Most companies in Europe and the US do not use petroleum powered forklifts, as these vehicles work indoors where emissions must be controlled and instead use electric forklifts. Fuel-cell-powered forklifts can be refueled in 3 minutes. They can be used in refrigerated warehouses, as their performance is not degraded by lower temperatures. The fuel cell units are often designed as drop-in replacements.
Trams and trains In the
International Energy Agency’s 2022 Net Zero Emissions Scenario, hydrogen is forecast to account for 2% of rail energy demand in 2050, while 90% of rail travel is expected to be electrified by then (up from 45% today). Hydrogen’s role in rail would likely be focused on lines that prove difficult or costly to electrify. In March 2015,
China South Rail Corporation (CSR) demonstrated a hydrogen fuel cell-powered tramcar at an assembly facility in Qingdao. Tracks for the new vehicle were built in seven Chinese cities. In northern Germany in 2018 fuel-cell powered
Coradia iLint trains were first placed into service; excess power is stored in
lithium-ion batteries. By 2025, hydrogen powered trains had also been introduced in France and Sweden; in India, a Hydrogen train with 1200 hp, capable of carrying 2,600 passengers, is set to run between Sonipat and Jind in Haryana. However, the same year there was bad news for some of Europe's hydrogen train companies: France's
Alstom announced that it is halting development of hydrogen trains and redeploying some research staff with the withdrawal of government funding, and in Germany, Rhine-Main Transport Authority withdrew its 18 hydrogen-powered trains after "repeated technical issues with the hydrogen fuel cells";
Siemens Mobility has also had problems with its hydrogen trains.
Bicycles and stand-up scooters hydrogen bicycle In 2007, Pearl Hydrogen Power Source Technology Co of
Shanghai, China, demonstrated a
PHB hydrogen bicycle. In 2014, Australian scientists from the
University of New South Wales presented their Hy-Cycle model. The same year,
Canyon Bicycles started to work on the Eco Speed concept bicycle. In 2017, Pragma Industries of France developed a bicycle that was able to travel 100 km on a single hydrogen cylinder. In 2019, Pragma announced that the product, "Alpha Bike", has been improved to offer an electrically assisted pedalling range of 150 km, and the first 200 of the bikes are to be provided to journalists covering the
45th G7 summit in
Biarritz, France. In 2020, Alles over Waterstof developed a 2-wheel hydrogen powered stand-up scooter. The stand-up scooter has a range of over 20 km on 15 grams of hydrogen. It uses a swappable 1 litre 200 bar hydrogen cylinder. In 2021 the company developed a hydrogen powered cargo-bike, using a static 3 litre 300 bar refillable hydrogen cylinder. The HydroCargo bike has a range of up to 100 km on 80 grams of hydrogen. Lloyd Alter of
TreeHugger responded to the announcement, asking "why … go through the trouble of using electricity to make hydrogen, only to turn it back into electricity to charge a battery to run the e-bike [or] pick a fuel that needs an expensive filling station that can only handle 35 bikes a day, when you can charge a battery powered bike anywhere. [If] you were a captive fleet operator, why [not] just swap out batteries to get the range and the fast turnover?"
Military vehicles General Motors' military division,
GM Defense, focuses on hydrogen fuel cell vehicles. Its SURUS (Silent Utility Rover Universal Superstructure) is a flexible fuel cell electric platform with autonomous capabilities. Since April 2017, the U.S. Army has been testing the commercial
Chevrolet Colorado ZH2 on its U.S. bases to determine the viability of hydrogen-powered vehicles in military mission tactical environments.
Motorcycles and scooters ENV develops electric motorcycles powered by a hydrogen fuel cell, including the
Crosscage and
Biplane. Other manufacturers as Vectrix are working on hydrogen scooters. Finally, hydrogen-fuel-cell-electric-hybrid scooters are being made such as the
Suzuki Burgman fuel-cell scooter and the
FHybrid. The Burgman received "whole vehicle type" approval in the EU. The Taiwanese company APFCT conducted a live street test with 80 fuel-cell scooters for Taiwan's Bureau of Energy.
Auto rickshaws Hydrogen
auto rickshaw concept vehicles have been built by Mahindra HyAlfa and Bajaj Auto.
Quads and tractors H-Due, made by
Autostudi S.r.l, is a hydrogen-powered quad capable of transporting 1-3 passengers. A concept for a hydrogen-powered tractor has been proposed.
Auto racing A record of was set by a prototype Ford Fusion Hydrogen 999 Fuel Cell Race Car at the Bonneville Salt Flats, in August 2007, using a large compressed oxygen tank to increase power. The land-speed record for a hydrogen-powered vehicle of was set by
Ohio State University's
Buckeye Bullet 2, which achieved a "flying-mile" speed of at the
Bonneville Salt Flats in August 2008. In 2007, the
Hydrogen Electric Racing Federation was formed as a racing organization for hydrogen fuel cell-powered vehicles. The organization sponsored the Hydrogen 500, a 500-mile race. ==Internal combustion vehicle== Hydrogen internal combustion engine cars are different from hydrogen fuel cell cars. The
hydrogen internal combustion car is a slightly modified version of the traditional gasoline
internal combustion engine car. These hydrogen engines burn fuel in the same manner that gasoline engines do; the main difference is the exhaust product. Gasoline combustion results in
emissions of mostly
carbon dioxide and water, plus trace amounts of
carbon monoxide, , particulates and unburned hydrocarbons, while the main exhaust product of hydrogen combustion is water vapor. In 1807
François Isaac de Rivaz designed
the first hydrogen-fueled internal combustion engine. In 1965, Roger E. Billings, then a high school student, converted a
Model A to run on hydrogen. In 1970 Paul Dieges patented a modification to internal combustion engines which allowed a gasoline-powered engine to run on hydrogen. Mazda has developed
Wankel engines burning hydrogen, which are used in the
Mazda RX-8 Hydrogen RE. The advantage of using an internal combustion engine, like Wankel and piston engines, is the lower cost of retooling for production. ==Fuel cell==