8 September 2018 | NewScientist | 21
an electric car’s battery. You can
also go further on a full tank of
hydrogen – about 500 kilometres,
compared with 300 kilometres
for a standard fully charged
battery (see table, below).
But although hydrogen reacts
cleanly – the only thing coming
out of the exhaust pipe is water –
hydrogen vehicles are more
energy-intensive than electric
ones if you factor in fuel
production and transport, says
Jake Whitehead at the University
of Queensland, Australia.
At the moment, most hydrogen
is extracted from natural gas –
a fossil fuel. “Green” hydrogen
can be made by splitting water
using solar or wind power,
but this involves multiple steps,
each using energy along the way.
In contrast, a single energy step
is required to directly recharge
a car battery at home.
Clean fuel?
If you account for this complete
energy cycle, Whitehead’s
modelling shows that hydrogen
vehicles require between 80 and
100 kilowatt-hours of electricity
to travel 100 kilometres, compared
with about 20 kilowatt-hours to
travel the same distance in a
battery vehicle. This is the main
charge levelled by Musk at
hydrogen cars. “[The efficiency is]
terrible, so why would you do
that? It make no sense,” he told
reporters at the Automotive News
World Congress in Detroit in 2015.
Hydrogen fuel is also more
expensive than petrol. Hydrogen
cars currently cost about 13 cents
per kilometre to run, compared
with 8 cents per kilometre for
petrol cars. However, some
projections suggest that the costs
will become equivalent by 2025
as the technology to produce
hydrogen becomes cheaper.
At the moment, there are only
about 6000 hydrogen vehicles
on the road globally, compared
with 2 million electric vehicles.
But Ogden says that hydrogen
vehicles may end up becoming
more popular among certain
drivers. “If you’re only using your
car for short commutes or to get
around the city, battery cars can
handle all your needs,” she says.
“But if you want a big car that
you can take on long drives in the
mountains on a whim, a hydrogen
fuel cell car might be better.”
The shorter refuelling time
and longer range of hydrogen
fuel cells also make them
appealing for taxis, buses and
long-haul trucks, says Dolan.
“These vehicles can’t afford to
be stopping for hours at a time
to recharge,” he says.
Hydrogen fuel cells are already
finding applications in these
heavy-use vehicles. Japan will
showcase 100 hydrogen buses
at the 2020 Tokyo Olympics, and
South Korea plans to introduce
1000 hydrogen buses by 2022.
A fleet of 180 hydrogen taxis,
private-hire and police cars
is being trialled in London,
Paris and Brussels, and retailer
Amazon has recently invested in
hydrogen-powered forklifts for
its warehouses. US manufacturer
Nikola Motors, meanwhile, says
it has received 11,000 pre-orders
for its hydrogen fuel cell truck.
Japan and South Korea are
leading this push because they
want to embrace zero-emissions
technology, but their combination
of small land masses and large
populations means they don’t
have enough solar, wind or other
renewable energy to support large
numbers of battery electric
vehicles, says Dolan.
They can’t import renewable
energy itself, but they can import
hydrogen made from renewable
energy in other countries.
Australia, for example, could use
its abundant solar energy to split
water and export hydrogen to
these countries, says Dolan.
“You can see hydrogen basically
as a carrier for renewable energy.”
Many people feel jittery
about hydrogen because of its
connection with hydrogen bombs
and the 1937 Hindenburg disaster,
in which a hydrogen-filled airship
spectacularly caught fire, killing
36 people. But the hydrogen tanks
used in modern fuel cell vehicles
are made from multiple layers of
resin, carbon fibre and fibreglass
that keep the flammable gas
safely contained. Tests show they
can even survive being shot
at or set on fire. New ways of
transporting hydrogen – like
in the form of ammonia – will
also make its deployment safer,
says Macleod.
The most probable future
scenario is that we will have a
mix of vehicles run by batteries,
hydrogen and petrol, each
performing different roles, says
Ogden. “There are proponents of
the different technologies saying
it’s all going to be all hydrogen
or all batteries, but auto-makers
are putting their money on both,”
she says. According to the KPMG
survey, car-makers are predicting
an even four-way split between
electric, hydrogen, petrol and
hybrid vehicles by 2040.
The final mix will depend on
the willingness of governments
and industry to invest in
hydrogen infrastructure – for
example, by building refuelling
stations and introducing
hydrogen buses – as well as
consumer enthusiasm for
hydrogen cars. But whether it
ends up being hydrogen or battery
power that wins the bigger share,
any dent in the dominance of
petrol vehicles is likely to be a
good thing. With less emitted
carbon warming our globe, less
toxic exhaust fumes choking our
lungs and less smog staining our
skylines, we will all be better off. ■
“There are only about 6000
hydrogen vehicles on the
road globally, versus
2 million electric vehicles”
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A chemical reaction between oxygen and hydrogen generates electricity, which is fed to the car’s
battery and motor. Water is the only by-product, leading to clean emission
generationPower Battery
Motor
High-pressure
hydrogen tank
O 2 H^2
Fuel cell stack
Water out
Air in (oxygen)
Hydrogen in
SOURCE: TOYOTA
Car type Petrol Battery Hydrogen
electric fuel cell
Emissions Carbon dioxide, None Water
carbon monoxide,
NOx gases etc.
Typical refuel/ 3-5 minutes 8 hours 3-5 minutes
recharge time
Typical range 400 kilometres 300 kilometres 500 kilometres
Typical 8 cents/ 3 cents/ 13 cents/
running cost kilometre kilometre kilometre