Many devices use light to probe the quantum states of atoms in a vapor confined in a small cell. Atoms can be highly sensitive to external conditions, and therefore make superb detectors. Devices based on light interactions with atomic vapors can measure quantities such as time, length, and magnetic fields, and have applications in navigation, communications, medicine, and other fields. Such devices generally must be assembled by hand.
A prototype chip was created on which laser light interacts with a tiny cloud of atoms to serve as a miniature toolkit for measuring important quantities such as length with quantum precision. The design could be mass-produced with existing technology. The chip generates infrared light at a wavelength of 780 nanometers, precisely enough to be used as a length reference for calibrating other instruments. The chip packs the atom cloud and structures for guiding light waves into less than 1 square centimeter, about one ten-thousandth of the volume of other compact devices offering similar measurement precision.
The new chip transports light from the external laser through a novel waveguide and grating structure to expand the beam diameter to probe about 100 million atoms until they switch from one energy level to another. To determine the laser light frequency or wavelength that the atoms will absorb to undergo this energy transition, the system uses a photodetector to identify the laser tuning at which only about half the light passes through the vapor cell.
The demonstration used a gas of rubidium atoms, but the chip could work with a wide range of atomic and molecular vapors to generate specific frequencies across the entire visible spectrum of light and some of the infrared band. Once the laser is properly tuned, some of the original laser light can be siphoned off as output to use as a reference standard.
The chip might be used, for example, to calibrate length measurement instruments. More importantly, the chip shows that lasers and atomic vapor cells could potentially be mass-produced together like semiconductors, using silicon materials and traditional chip-manufacturing techniques, instead of the current manual assembly of bulky optics and blown-glass vapor cells.
The chip is 14 millimeters (about 0.5”) long and 9 mm (about 0.35”) wide. The waveguides are made of silicon nitride, which can handle a wide range of light frequencies. The vapor cell is micromachined silicon with glass windows. The device measures frequency with a precision of 1 part error in 10 billion at 100 seconds.
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