Chip-scale atomic clock
A chip scale atomic clock (CSAC) is a compact, low-power atomic clock fabricated using techniques of microelectromechanical systems (MEMS) and incorporating a low-power semiconductor laser as the light source. The first CSAC physics package was demonstrated at the National Institute of Standards and Technology (NIST) in 2003,[1] based on an invention made in 2001.[2] The work was funded by the US Department of Defense's Defense Advanced Research Projects Agency (DARPA) with the goal of developing a microchip-sized atomic clock for use in portable equipment. In military equipment it is expected to provide improved location and battlespace situational awareness for dismounted soldiers when the global positioning system is not available,[3] but many civilian applications are also envisioned. Commercial manufacturing of these atomic clocks began in 2011.[4] The CSAC, the world's smallest atomic clock, is 4 x 3.5 x 1 cm (1.5 x 1.4 x 0.4 inches) in size, weighs 35 grams, consumes only 115 mW of power, and can keep time to within 100 microseconds per day after several years of operation. A more stable design based on the vibration of rubidium atoms was demonstrated by NIST in 2019.[5]
How it works
Like other caesium atomic clocks, the clock keeps time by a precise 9.192631770 GHz microwave signal emitted by electron spin transitions between two hyperfine energy levels in atoms of caesium-133. A feedback mechanism keeps a quartz crystal oscillator on the chip locked to this frequency, which is divided down by digital counters to give 10 MHz and 1 Hz clock signals provided to output pins. On the chip, liquid metal caesium in a tiny 2 mm capsule, fabricated using silicon micromachining techniques, is heated to vaporize the alkali metal. A semiconductor laser shines a beam of infrared light modulated by the microwave oscillator through the capsule onto a photodetector. When the oscillator is at the precise frequency of the transition, the optical absorption of the caesium atoms is reduced, increasing the output of the photodetector. The output of the photodetector is used as feedback in a frequency locked loop circuit to keep the oscillator at the correct frequency.
Development
Conventional vapor cell atomic clocks are about the size of a deck of cards, consume about 10 W of electrical power and cost about $3,000. Shrinking these to the size of a semiconductor chip required extensive development and several breakthroughs.[6] An important part of development was designing the device so it could be manufactured using standard semiconductor fabrication techniques where possible, to keep its cost low enough that it could become a mass market device. Conventional caesium clocks use a glass tube containing caesium, which are challenging to make smaller than 1 cm. In the CSAC, MEMS techniques were used to create a caesium capsule only 2 cubic millimeters in size. The light source in conventional atomic clocks is a rubidium atomic-vapor discharge lamp, which was bulky and consumed large amounts of power. In the CSAC this was replaced by an infrared vertical cavity surface emitting laser (VCSEL) fabricated on the chip, with its beam radiating upward into the caesium capsule above it. Another advance was the elimination of the microwave cavity used in conventional clocks, whose size, equal to a wavelength of the microwave frequency, about 3 cm, formed the fundamental lower limit to the size of the clock.[6] The cavity was made unnecessary by the use of a quantum technique, coherent population trapping.
Commercialization
The CSAC program achieved a hundredfold size reduction while using 50 times less power than traditional atomic clocks, which led to extensive CSAC use in military and commercial applications.[7][8] According to an October 2023 report, the CSAC market is expected to grow at a "remarkable" compound annual growth rate (CAGR) from 2023 to 2030.[9] Major commercial players include Microsemi (Microchip Technology), Teledyne, Chengdu Spaceon Electronics, and AccuBeat.[9][10]
External links
References
- ^ Knappe, Svenja; Shah, Vishal; Schwindt, Peter D. D.; Hollberg, Leo; Kitching, John; Liew, Li-Anne; Moreland, John (2004-08-30). "A microfabricated atomic clock". Applied Physics Letters. 85 (9): 1460–1462. Bibcode:2004ApPhL..85.1460K. doi:10.1063/1.1787942. ISSN 0003-6951. S2CID 119968560.
- ^ Leo Hollberg and John Kitching, Miniature frequency standard based on all-optical excitation and a micro-machined containment vessel, US Patent 6,806,784 B2., retrieved 2018-10-10
- ^ "Miniaturized Atomic Clock to Support Soldiers In Absence of GPS". Defense-Aerospace.com. Archived from the original on 2018-10-11. Retrieved 2020-04-19.
- ^ Jones, Willie D. (March 16, 2011). "Chip-Scale Atomic Clock". IEEE Spectrum. Inst. of Electrical and Electronic Engineers. Retrieved February 2, 2017.
- ^ "NIST Team Demonstrates Heart of Next-Generation Chip-Scale Atomic Clock". NIST. 17 May 2019.
- ^ a b Kitching, John (2018). "Chip-scale atomic devices". Applied Physics Reviews. 5 (3): 031302. Bibcode:2018ApPRv...5c1302K. doi:10.1063/1.5026238. ISSN 1931-9401.
- ^ "Success Story: Chip-Scale Atomic Clock". NIST. 2020-12-02.
- ^ An Assessment of Four Divisions of the Physical Measurement Laboratory at the National Institute of Standards and Technology. National Academies Press. 2018. doi:10.17226/25281. ISBN 978-0-309-48545-6. Retrieved June 7, 2024.
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ignored (help) - ^ a b "Global Chip-Scale Atomic Clock (CSAC) Market By Type (Size : below 4.2 cm, Size : 4.2 cm-4.5 cm), By Application (Military, Commercial), By Geographic Scope And Forecast". verifiedmarketreports.com. October 2023. Retrieved June 5, 2024.
- ^ "Chip Scale Atomic Clock (CSAC) | Microsemi". www.microsemi.com. Retrieved 2018-10-08.