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12 results on '"Nardelli, Nicholas V."'

1. Cryogenic sapphire optical reference cavity with crystalline coatings at $\mathrm{ 1 \times 10^{-16}}$ fractional instability

Author

Valencia, Jose, Iskander, George, Nardelli, Nicholas V., Leibrandt, David R., and Hume, David B.

Subjects
Physics - Optics, Physics - Atomic Physics
Abstract

The frequency stability of a laser locked to an optical reference cavity is fundamentally limited by thermal noise in the cavity length. These fluctuations are linked to material dissipation, which depends both on the temperature of the optical components and the material properties. Here, the design and experimental characterization of a sapphire optical cavity operated at 10 K with crystalline coatings at 1069 nm is presented. Theoretical estimates of the thermo-mechanical noise indicate a thermal noise floor below $\mathrm{4.5\times10^{-18}}$. Major technical noise contributions including vibrations, temperature fluctuations, and residual amplitude modulation are characterized in detail. The short-term performance is measured via a three-cornered hat analysis with two other cavity-stabilized lasers, yielding a noise floor of $1\times10^{-16}$. The long-term performance is measured against an optical lattice clock, indicating cavity stability at the level of $2\times10^{-15}$ for averaging times up to 10,000 s.

Published
2024

2. Optical and microwave metrology at the 10-18 level with an Er/Yb:glass frequency comb

Author

Nardelli, Nicholas V., Leopardi, Holly, Schibli, Thomas R., and Fortier, Tara M.

Subjects
Physics - Optics, Physics - Instrumentation and Detectors
Abstract

Optical frequency combs are an essential tool for precision metrology experiments ranging in application from remote spectroscopic sensing of trace gases to the characterization and comparison of optical atomic clocks for precision time-keeping and searches for physics beyond the standard model. Here we describe the architecture and fully characterize a telecom-band, self-modelocking frequency comb based on a free-space laser with an Er/Yb co-doped glass gain medium. The laser provides a robust and cost-effective alternative to Er:fiber laser based frequency combs, while offering stability and noise performance similar to Ti:sapphire laser systems. Finally, we demonstrate the Er/Yb:glass frequency comb's utility in high-stability frequency synthesis using two ultra-stable optical references at 1157 nm and 1070 nm and in low-noise photonic microwave generation by dividing these references to the microwave domain.

Published
2022

3. 10 GHz Generation with Ultra-Low Phase Noise via the Transfer Oscillator Technique

Author

Nardelli, Nicholas V., Fortier, Tara M., Pomponio, Marco, Baumann, Esther, Nelson, Craig, Schibli, Thomas R., and Hati, Archita

Subjects
Physics - Optics, Physics - Instrumentation and Detectors
Abstract

Coherent frequency division of high-stability optical sources permits the extraction of microwave signals with ultra-low phase noise, enabling their application to systems with stringent timing precision. To date, the highest performance systems have required tight phase stabilization of laboratory grade optical frequency combs to Fabry-Perot optical reference cavities for faithful optical-to-microwave frequency division. This requirement limits the technology to highly-controlled laboratory environments. Here, we employ a transfer oscillator technique, which employs digital and RF analog electronics to coherently suppress additive optical frequency comb noise. This relaxes the stabilization requirements and allows for the extraction of multiple independent microwave outputs from a single comb, while at the same time, permitting low-noise microwave generation from combs with higher noise profiles. Using this method we transferred the phase stability of two high-Finesse optical sources at 1157 nm and 1070 nm to two independent 10 GHz signals using a single frequency comb. We demonstrated absolute phase noise below -106 dBc/Hz at 1-Hz from carrier with corresponding 1 second fractional frequency instability below $2\times10^{-15}$. Finally, the latter phase noise levels were attainable for comb linewidths broadened up to 2 MHz, demonstrating the potential for out-of lab use with low SWaP lasers.

Published
2021
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4. Optical coherence between atomic species at the second scale: improved clock comparisons via differential spectroscopy

Author

Kim, May E., McGrew, William F., Nardelli, Nicholas V., Clements, Ethan R., Hassan, Youssef S., Zhang, Xiaogang, Valencia, Jose L., Leopardi, Holly, Hume, David B., Fortier, Tara M., Ludlow, Andrw D., and Leibrandt, David R.

Subjects
Physics - Atomic Physics, Physics - Optics
Abstract

Comparisons of high-accuracy optical atomic clocks \cite{Ludlow2015} are essential for precision tests of fundamental physics \cite{Safronova2018}, relativistic geodesy \cite{McGrew2018, Grotti2018, Delva2019}, and the anticipated redefinition of the SI second \cite{Riehle2018}. The scientific reach of these applications is restricted by the statistical precision of interspecies comparison measurements. The instability of individual clocks is limited by the finite coherence time of the optical local oscillator (OLO), which bounds the maximum atomic interrogation time. In this letter, we experimentally demonstrate differential spectroscopy \cite{Hume2016}, a comparison protocol that enables interrogating beyond the OLO coherence time. By phase-coherently linking a zero-dead-time (ZDT) \cite{Schioppo2017} Yb optical lattice clock with an Al$^+$ single-ion clock via an optical frequency comb and performing synchronised Ramsey spectroscopy, we show an improvement in comparison instability relative to our previous result \cite{network2020frequency} of nearly an order of magnitude. To our knowledge, this result represents the most stable interspecies clock comparison to date.

Published
2021

8. Improved interspecies optical clock comparisons through differential spectroscopy

Author

Kim, May E., primary, McGrew, William F., additional, Nardelli, Nicholas V., additional, Clements, Ethan R., additional, Hassan, Youssef S., additional, Zhang, Xiaogang, additional, Valencia, Jose L., additional, Leopardi, Holly, additional, Hume, David B., additional, Fortier, Tara M., additional, Ludlow, Andrew D., additional, and Leibrandt, David R., additional

Published
2022
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9. Optical and Microwave Metrology at the 10-18 Level with an Er/Yb:glass Frequency Comb.

Author

Nardelli, Nicholas V., Leopardi, Holly, Schibli, Thomas R., and Fortier, Tara M.

Subjects
*YTTERBIUM, *ACTIVE medium, *MICROWAVE generation, *ATOMIC clocks, *METROLOGY, *FIBER lasers, *TRACE gases, *MICROWAVES
Abstract

Optical frequency combs are essential tools for precision metrology experiments ranging in application from remote spectroscopic sensing of trace gases to the characterization and comparison of optical atomic clocks for precision time-keeping and searches for physics beyond the standard model. Presented here is a description of the architecture and a full characterization of a telecom-band, self-modelocking frequency comb based on a free-space laser with an Er/Yb co-doped glass gain medium. The laser provides a robust and cost-effective alternative to Er:fibre laser based frequency combs, while offering stability and noise performance similar to Ti:sapphire laser systems. Finally, the utility of the Er/Yb:glass frequency comb is demonstrated in high-stability frequency synthesis using two ultra-stable optical references at 1157 nm and 1070 nm and in low-noise photonic microwave generation by dividing these references to the microwave domain. [ABSTRACT FROM AUTHOR]

Published
2023
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12. Cryogenic sapphire optical reference cavity with crystalline coatings at 1 × 10-16 fractional frequency instability.

Author

Valencia J, Iskander G, Nardelli NV, Leibrandt DR, and Hume DB

Abstract

The frequency stability of a laser locked to an optical reference cavity is fundamentally limited by thermal noise in the cavity length. These fluctuations are linked to material dissipation, which depends on both the temperature of the optical components and the material properties. Here, the design and experimental characterization of a sapphire optical cavity operated at 10 K with crystalline coatings at 1069 nm is presented. Theoretical estimates of the thermo-mechanical noise indicate a thermal noise floor below 4.5 × 10-18. Major technical noise contributions including vibrations, temperature fluctuations, and residual amplitude modulation are characterized in detail. The short-term performance is measured via a three-cornered hat analysis with two other cavity-stabilized lasers, yielding a noise floor of 1 × 10-16. The long-term performance is measured against an optical lattice clock, indicating cavity stability at the level of 2 × 10-15 for averaging times up to 10 000 s., (© 2024 Author(s). Published under an exclusive license by AIP Publishing.)

Published
2024
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