Demonstration of a timescale based on a stable optical carrier

William R. Milner; John M. Robinson; Colin J. Kennedy; Tobias Bothwell; Dhruv Kedar; Dan G. Matei; Thomas Legero; Uwe Sterr; Fritz Riehle; Holly Leopardi; Tara M. Fortier; Jeffrey A. Sherman; Judah Levine; Jian Yao; Jun Ye; Eric Oelker

doi:10.1103/PhysRevLett.123.173201

Demonstration of a timescale based on a stable optical carrier

William R. Milner
, John M. Robinson
, Colin J. Kennedy
, Tobias Bothwell
, Dhruv Kedar
, Dan G. Matei
, Thomas Legero
, Uwe Sterr
, Fritz Riehle
, Holly Leopardi
, Tara M. Fortier
, Jeffrey A. Sherman
, Judah Levine
, Jian Yao
, Jun Ye
, Eric Oelker

Research output: Contribution to journal › Article › peer-review

66 Scopus citations

Abstract

We report on the first timescale based entirely on optical technology. Existing timescales, including those incorporating optical frequency standards, rely exclusively on microwave local oscillators owing to the lack of an optical oscillator with the required frequency predictability and stability for reliable steering. We combine a cryogenic silicon cavity exhibiting improved long-term stability and an accurate Sr87 lattice clock to form a timescale that outperforms them all. Our timescale accumulates an estimated time error of only 48±94 ps over 34 days of operation. Our analysis indicates that this timescale is capable of reaching a stability below 1×10-17 after a few months of averaging, making timekeeping at the 10-18 level a realistic prospect.

Original language	English
Article number	173201
Journal	Physical Review Letters
Volume	123
Issue number	17
DOIs	https://doi.org/10.1103/PhysRevLett.123.173201
State	Published - Oct 21 2019
Externally published	Yes

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Milner, W. R., Robinson, J. M., Kennedy, C. J., Bothwell, T., Kedar, D., Matei, D. G., Legero, T., Sterr, U., Riehle, F., Leopardi, H., Fortier, T. M., Sherman, J. A., Levine, J., Yao, J., Ye, J., & Oelker, E. (2019). Demonstration of a timescale based on a stable optical carrier. Physical Review Letters, 123(17), Article 173201. https://doi.org/10.1103/PhysRevLett.123.173201

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title = "Demonstration of a timescale based on a stable optical carrier",

abstract = "We report on the first timescale based entirely on optical technology. Existing timescales, including those incorporating optical frequency standards, rely exclusively on microwave local oscillators owing to the lack of an optical oscillator with the required frequency predictability and stability for reliable steering. We combine a cryogenic silicon cavity exhibiting improved long-term stability and an accurate Sr87 lattice clock to form a timescale that outperforms them all. Our timescale accumulates an estimated time error of only 48±94 ps over 34 days of operation. Our analysis indicates that this timescale is capable of reaching a stability below 1×10-17 after a few months of averaging, making timekeeping at the 10-18 level a realistic prospect.",

author = "Milner, \{William R.\} and Robinson, \{John M.\} and Kennedy, \{Colin J.\} and Tobias Bothwell and Dhruv Kedar and Matei, \{Dan G.\} and Thomas Legero and Uwe Sterr and Fritz Riehle and Holly Leopardi and Fortier, \{Tara M.\} and Sherman, \{Jeffrey A.\} and Judah Levine and Jian Yao and Jun Ye and Eric Oelker",

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AU - Milner, William R.

AU - Robinson, John M.

AU - Kennedy, Colin J.

AU - Bothwell, Tobias

AU - Kedar, Dhruv

AU - Matei, Dan G.

AU - Legero, Thomas

AU - Sterr, Uwe

AU - Riehle, Fritz

AU - Leopardi, Holly

AU - Fortier, Tara M.

AU - Sherman, Jeffrey A.

AU - Levine, Judah

AU - Yao, Jian

AU - Ye, Jun

AU - Oelker, Eric

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AB - We report on the first timescale based entirely on optical technology. Existing timescales, including those incorporating optical frequency standards, rely exclusively on microwave local oscillators owing to the lack of an optical oscillator with the required frequency predictability and stability for reliable steering. We combine a cryogenic silicon cavity exhibiting improved long-term stability and an accurate Sr87 lattice clock to form a timescale that outperforms them all. Our timescale accumulates an estimated time error of only 48±94 ps over 34 days of operation. Our analysis indicates that this timescale is capable of reaching a stability below 1×10-17 after a few months of averaging, making timekeeping at the 10-18 level a realistic prospect.

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Demonstration of a timescale based on a stable optical carrier

Abstract

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