Scientists have created the tiniest electric car ever — although it won’t be coming to your local dealership
anytime soon. With four molecular wheels and a carbon-based frame, the mini-roadster is a step toward
devices that mimic the machinery of molecular life.
The researchers started with little motorized “wheels,” molecules inspired by the motors that some bacteria
use to propel themselves, and attached them to a frame. A carbon double bond serves as an axle between
two wheels; when the entire unit is zapped with electricity, the double bond becomes a single bond.
This contorts the axle, rotating the wheels and propelling the car forward,
researchers report
in the Nov. 10 Nature. In test drives on a copper surface the car went as far as 20 nanometers, says
organic chemist Ben Feringa — about 10 car lengths.
Designing a contraption that will do your bidding in the nanoworld is not so
easy, says Feringa, of the University of Groningen in the Netherlands. With
regular-sized cars, forces such as gravity dictate interactions with the road.
But a vehicle that’s nanometers long — about the width of a DNA molecule —
must contend with different forces.
“The interactions with the surface are very important,” Feringa says. “The key
is to not make it stick to the surface, because it will never move, but also it
cannot fly away.”
Another difficulty of working at the nanoscale is when molecules are
close together they interact, and not necessarily in the way that you
want, says Paul Weiss, director of the California NanoSystems Institute
at UCLA.
“The biggest thing here is these four motors operating together,”
says Weiss, who wrote a commentary accompanying the Naturearticle.
“It’s really terrific work.”
Nature is adept at making such minimachines. There are proteins that
transport cargo inside cells, others that help muscles move and
pumps that provide energy. Building similar molecules that cooperate
and carry out tasks could lead to all sorts of machines and uses, Weiss
says.
There are still kinks to iron out before these little cars can be mass-produced
efficiently. The molecular machines are made in a solution that’s then
poured on the copper surface, and only cars that land right-side-up are
drivable. But such production issues should be relatively easy to overcome,
says Weiss.
“We’re really learning the forces and the lay of the land at the nanoscale,”
he says.
The researchers would like to see whether they can propel the machines
with light rather than electricity, says Feringa, and also plan to add cargo
to see whether the vehicles can carry a load.
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