A quantum clock is a type of

atomic clock An atomic clock is a clock that measures time by monitoring the resonant frequency of atoms. It is based on atoms having different energy levels. Electron states in an atom are associated with different energy levels, and in transitions betwee ...

with laser cooled single ions confined together in an electromagnetic ion trap. Developed in 2010 by physicists at the U.S.

National Institute of Standards and Technology The National Institute of Standards and Technology (NIST) is an agency of the United States Department of Commerce whose mission is to promote American innovation and industrial competitiveness. NIST's activities are organized into Outline of p ...

, the clock was 37 times more precise than the then-existing international standard. The quantum logic clock is based on an Al spectroscopy ion with a logic atom. Both the Al-based quantum clock and the Hg-based optical

track time by the ion vibration at an optical frequency using a UV laser, that is 100,000 times higher than the microwave frequencies used in NIST-F1 and other similar time standards around the world. Quantum clocks like this are able to be far more precise than microwave standards.

Accuracy

A NIST 2010 quantum logic clock based on a single aluminum ion The NIST team are not able to measure clock ticks per second because the definition of a second is based on the standard NIST-F1, which cannot measure a machine more precise than itself. However, the aluminum ion clock's measured frequency to the current standard is . NIST have attributed the clock's accuracy to the fact that it is insensitive to background magnetic and electric fields, and unaffected by temperature. In March 2008, physicists at

NIST The National Institute of Standards and Technology (NIST) is an agency of the United States Department of Commerce whose mission is to promote American innovation and industrial competitiveness. NIST's activities are organized into physical s ...

described an experimental quantum logic clock based on individual ions of

beryllium Beryllium is a chemical element; it has Symbol (chemistry), symbol Be and atomic number 4. It is a steel-gray, hard, strong, lightweight and brittle alkaline earth metal. It is a divalent element that occurs naturally only in combination with ...

and

aluminum Aluminium (or aluminum in North American English) is a chemical element; it has chemical symbol, symbol Al and atomic number 13. It has a density lower than that of other common metals, about one-third that of steel. Aluminium has ...

. This clock was compared to NIST's mercury ion clock. These were the most accurate clocks that had been constructed, with neither clock gaining nor losing time at a rate that would exceed a second in over a billion years. In February 2010, NIST physicists described a second, enhanced version of the quantum logic clock based on individual ions of

magnesium Magnesium is a chemical element; it has Symbol (chemistry), symbol Mg and atomic number 12. It is a shiny gray metal having a low density, low melting point and high chemical reactivity. Like the other alkaline earth metals (group 2 ...

and

aluminium Aluminium (or aluminum in North American English) is a chemical element; it has chemical symbol, symbol Al and atomic number 13. It has a density lower than that of other common metals, about one-third that of steel. Aluminium has ...

. Considered the world's most precise clock in 2010 with a fractional frequency inaccuracy of , it offers more than twice the precision of the original. In terms of

standard deviation In statistics, the standard deviation is a measure of the amount of variation of the values of a variable about its Expected value, mean. A low standard Deviation (statistics), deviation indicates that the values tend to be close to the mean ( ...

, the quantum logic clock deviates one second every 3.68 billion years, while the then current international standard NIST-F1 Caesium fountain atomic clock uncertainty was about 3.1 × 10⁻¹⁶ expected to neither gain nor lose a second in more than 100 million years. In July 2019, NIST scientists demonstrated such a clock with total uncertainty of (deviates one second every 33.7 billion years), which is the first demonstration of a clock with uncertainty below .

Quantum time dilation

In a 2020 paper scientists illustrated that and how quantum clocks could experience a possibly experimentally testable superposition of proper times via time dilation of the theory of relativity by which time passes slower for one object in relation to another object when the former moves at a higher velocity. In "quantum time dilation" one of the two clocks moves in a superposition of two localized momentum wave packets, resulting in a change to the classical time dilation. Available unde
CC BY 4.0
(some content of it has been used here).

Other accurate experimental clocks

The accuracy of quantum-logic clocks was briefly superseded by optical lattice clocks based on strontium-87 and ytterbium-171 until 2019. An experimental optical lattice clock was described in a 2014 Nature paper. In 2015 JILA evaluated the absolute frequency uncertainty of their latest strontium-87 429 THz () optical lattice clock at , which corresponds to a measurable gravitational time dilation for an elevation change of on planet Earth that according to JILA/NIST Fellow Jun Ye is "getting really close to being useful for relativistic geodesy". At this frequency uncertainty, this JILA optical lattice optical clock is expected to neither gain nor lose a second in more than 15 billion years.

References

{{Quantum mechanics topics Atomic clocks Philosophy of physics Philosophy of time Quantum information science Quantum measurement Space science

Accuracy

Quantum time dilation

Other accurate experimental clocks

See also

References