Synopsis

Giving Weight to Antimatter

Physics 7, s36
A proposed matter-wave interferometer would enable the test of the gravitational properties of antimatter.
Chukman So

Does antimatter feel the same gravitational pull as ordinary matter? The standard model of particle physics assumes this is the case, but experimental evidence remains hard to gather: measurements are complicated by the fact that antimatter is rare and annihilates when brought into contact with matter. Still, researchers are eager to test this assumption, since the standard model cannot explain the gravitational behavior of 95% of the Universe’s matter nor the abundance of matter vs antimatter. As reported in Physical Review Letters, experts in antihydrogen and atom interferometry are working together to design an interferometer that could measure the free-fall acceleration of any species of atoms, in particular antihydrogen.

The research team, led by Holger Müller at the University of California, Berkeley, has theorized a scheme in which antihydrogen atoms are cooled by lasers and then moved with light into a vertical interferometer cell. Because of the wave nature of the ultracold atoms, antihydrogens behave as matter waves that travel upwards and downwards within the cell and interfere. By counting the number of atoms that leave the cell, the device measures the phase shift between the two interfering paths and thus gravity. Since antihydrogen atoms cannot be produced in large quantities, the setup employs a special trick: it “recycles” the atoms that do not annihilate, sending them multiple times through the interferometer. The scheme could be integrated into the ALPHA antihydrogen trap at CERN and, with current antihydrogen production rates, it would allow the measurement of the gravitational acceleration of antihydrogen with a precision of 1%. Further improvements could potentially drive the precision up to levels comparable to those attained in experiments on ordinary matter. – Matteo Rini


Subject Areas

Atomic and Molecular PhysicsParticles and FieldsGravitation

Related Articles

Signatures of Gravitational Atoms from Black Hole Mergers
Astrophysics

Signatures of Gravitational Atoms from Black Hole Mergers

Gravitational-wave signals from black hole mergers could reveal the presence of “gravitational atoms”—black holes surrounded by clouds of axions or other light bosons. Read More »

Dark Matter Search in Gravitational-Wave Data
Gravitation

Dark Matter Search in Gravitational-Wave Data

An analysis of gravitational data from the LIGO detector sets new limits on a wave-like form of dark matter called scalar-field dark matter. Read More »

Gamma-Ray Burst Tightens Constraints on Quantum Gravity
Particles and Fields

Gamma-Ray Burst Tightens Constraints on Quantum Gravity

An analysis of the brightest gamma-ray burst ever observed reveals no difference in the propagation speed of different frequencies of light—placing some of the tightest constraints on certain violations of general relativity. Read More »

More Articles