Scientists have developed a novel design for a highly compact, ultra-sensitive quantum device to measure subtle changes in gravity over very short time or distance scales.*
“The ability to measure gravity over fine time scales will help in finding oil fields and mineral deposits,” says coauthor and JQI Fellow Victor Galitski. “Imagine an aircraft flying over an unexplored area. If heavy element deposits are hidden underneath, the gravimeter will react promptly by showing strong fluctuations in the local gravity field.”
We propose a compact atom interferometry scheme for measuring weak, time-dependent accelerations. Our proposal uses an ensemble of dilute trapped bosons with two internal states that couple to a synthetic gauge field with opposite charges. The trapped gauge field couples spin to momentum to allow time dependent accelerations to be continuously imparted on the internal states. We generalize this system to reduce noise and estimate the sensitivity of such a system to be S =∼ 10^− 7 m/s2 Divided by the square root of the frequency.
This device appears to be about 100 times more sensitive than airborne gravimeters from 1999 discussed in security documents that talked about detecting underground facilities. The 10^-7 m/s^2 sensitivity was achievable for stationary devices.
Future atom optics-based sensors have been expected to outperform existing inertial sensors by a factor of one million.
The theoretical expectation was that atom interferometers could get to 10^-12 m/s^2 sensitivity
Limits of atom gravimeters are discussed here.
Conventional AIs exploit interference to measure gravity at a given location, typically by directing a stream of atoms into a beamsplitter, which divides the atoms’ wave functions into two branches. Inside the device, each branch is propelled on separate – but completely symmetrical, mirror-image – paths down a cylinder. The only difference between the paths is that one is higher than the other – and therefore responds just slightly differently to the force of gravity. So when the two atom branches are recombined, their matter waves will be out of phase; and the amount of phase difference will be proportional to the difference in gravitational force felt by each.
Although useful, that method does not provide a good way to measure how gravitational force changes over small time periods and short length scales. And it necessarily requires the atoms to travel a relatively large distance, typically tens of centimeters, in order to produce a sufficiently large phase difference.
The JQI/PFC design, by contrast, uses an atom trap only 50 micrometers in diameter – about half the thickness of a human hair – containing millions of atoms chilled to a fraction of a degree above absolute zero. The atoms sit in a weak, inhomogeneous magnetic field, and each has a slightly different spin state (a kind of angular momentum) depending on its position in the field. The atoms are irradiated by a continuous-wave laser that imparts momentum to each atom, the magnitude and direction of which depends on the atom’s spin state. This arrangement produces “synthetic” magnetism,** a condition which causes neutral atoms to behave as if they were charged particles in a real magnetic field.