Right again, Einstein! Study shows how antimatter responds to gravity
Send a link to a friend
 [September 28, 2023]
By Will Dunham
(Reuters) - In the world of "Star Trek," the starship Enterprise zips
through space using a warp drive that harnesses antimatter. Suffice it
to say, such technology remains in the realm of science fiction.
But scientists are making important strides toward better understanding
antimatter. Researchers said on Wednesday they have demonstrated for the
first time that antimatter responds to gravity the same way matter does
- by falling, as one might expect - in an experiment that once again
buttressed physicist Albert Einstein's bedrock theory of general
relativity.
All the stuff with which we are familiar - planets, stars, poodles and
lollipops - is made of ordinary matter.
Antimatter is the enigmatic twin of ordinary matter, possessing the same
mass but with an opposite electrical charge. Almost all subatomic
particles, such as electrons and protons, have an antimatter
counterpart. While electrons are negatively charged, antielectrons, also
called positrons, are positively charged. Likewise, while protons are
positively charged, antiprotons are negatively charged.
Under current theory, the Big Bang explosion that initiated the universe
should have produced equal amounts of matter and antimatter. This,
however, does not seem to be the case. There appears to be very little
antimatter - and on Earth almost none. What's more, matter and
antimatter are incompatible. If they touch, they blow up, a phenomenon
called annihilation.
The experiment was conducted at the European Center for Nuclear Research
(CERN) in Switzerland by researchers from the international Antihydrogen
Laser Physics Apparatus (ALPHA) collaboration. It involved the
antimatter counterpart of hydrogen, the lightest of the elements.
"On Earth, most antimatter that occurs naturally is produced from cosmic
rays - energetic particles from space - that collide with atoms in the
air and create antimatter-matter pairs," said physicist Jonathan Wurtele
of the University of California, Berkeley, co-author of the study
published in the journal Nature.
This newly created antimatter lasts only until it hits a normal matter
atom in the lower atmosphere. However, antimatter can be synthesized
under controlled conditions, as in the ALPHA experiment, which used
antihydrogen created at CERN.
The antihydrogen was contained within a cylindrical vacuum chamber and
trapped with magnetic fields at the top and bottom. The researchers
reduced the magnetic fields to set the antimatter free in order to
observe whether or not it would fall once the influence of gravity
became apparent. It did, behaving as hydrogen would in the same
conditions.
[to top of second column]
|
An artist's conceptual rendering of antihydrogen atoms falling out
the bottom of the magnetic trap of the ALPHA-g apparatus, a tall
cylindrical vacuum chamber used in an antimatter experiment by the
international Antihydrogen Laser Physics Apparatus (ALPHA)
collaboration at the European Center for Nuclear Research (CERN) in
Geneva, Switzerland as seen in this undated handout image. As the
antihydrogen atoms escape, they touch the chamber walls and
annihilate. Most of the annihilations occur beneath the chamber,
showing that gravity is pulling the antihydrogen down. Keyi "Onyx"
Li/U.S. National Science Foundation/Handout via REUTERS/File photo
"This result was predicted by theory, and indirect experiments that
relied on subtle phenomena. But no group had ever done a direct
experiment in which antimatter was simply dropped to see which way
it would fall," UC Berkeley physicist and study co-author Joel
Fajans said.
"Our experiment rules out other theories that require antimatter to
rise - 'anti-gravity' - in the Earth's gravitational field," Wurtele
added.
While Einstein devised his theory of general relativity - a
comprehensive explanation of gravity - before antimatter was
discovered in 1932, he treated all matter with equivalence, meaning
that antimatter would be expected to respond the same way to
gravitational forces as matter.
But what if antimatter had defied expectations?
"This would have been an enormous surprise, as it would be in
significant contradiction with many theories," said physicist and
study co-author William Bertsche of the University of Manchester in
England, who conducts experiments at CERN and serves as a deputy
spokesperson for the ALPHA collaboration.
"I think this is a testament to the strength of general relativity
and its equivalence principles," Bertsche added.
Scientists remain puzzled by antimatter's scarcity in the observable
universe. For instance, there is no indication of galaxies made of
antimatter.
"The nearly complete absence of naturally occurring antimatter is
one of the great questions facing physics," Wurtele said.
In showing that antimatter and matter are gravitationally attracted,
the experiment ruled out one possible explanation for antimatter's
scarcity - that it was gravitationally repelled by matter during the
Big Bang.
"No matter how pretty the theory, physics is an experimental
science," Fajans said.
(Reporting by Will Dunham in Washington, Editing by Rosalba O'Brien)
[© 2023 Thomson Reuters. All rights
reserved.]This material
may not be published, broadcast, rewritten or redistributed.
Thompson Reuters is solely responsible for this content.
 |
