People: Simone Colombo

MIT
colombos@mit.edu
Vuletic
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Postdoctoral Fellow
Publications
  1. W. Xu, T. Sumarac, E. Qiu, M. Peters, S. Cantu, Z. Li, A. Menssen, M. Lukin, S. Colombo, V. Vuletic, Bose-Einstein condensation by polarization gradient laser cooling. Phys Rev Lett, 132(233401), June 2024.
  2. Z. Li, S. Colombo, C. Shu, G. Velez, S. Choi, M. Lukin, E. Pedrozo-Peñafiel, V. Vuletic, S. Pilatowsky-Cameo, and R. Schmied. Improving metrology with quantum scrambling. Science, 380(6652):1381-1384, June 2023.
  3. Z. Li, B. Braverman, S. Colombo, C. Shu, A. Kawasaki, A. Adiyatullin, E. Pedrozo-Peñafiel, E. Mendez, V. Vuletic, Collective Spin-Light and Light-Mediated Spin-Spin Interactions in an Optical Cavity. PRX Quantum, 3(020308), 2022.
  4. S. Colombo, E. Pedrozo-Peñafiel, A. Adiyatullin, Z. Li, E. Mendez, C. Shu, V. Vuletic, Time-reversal-based quantum metrology with many-body entangled states. Nature Physics, 1817(181), July 2022.
  5. E. Pedrozo-Peñafiel, S. Colombo, C. Shu, A. Adiyatullin, Z. Li, E. Mendez, B. Braverman, A. Kawasaki, V. Vuletic, D. Akamatsu, and Y. Xiao. Entanglement on an optical atomic-clock transition. Nature, 588:414–418, December 2020. View Abstract
  6. A. Kawasaki, B. Braverman, E. Pedrozo-Peñafiel, C. Shu, S. Colombo, Z. Li, V. Vuletic, Trapping 171Yb Atoms into a One-Dimensional Optical Lattice with Small Waist. Phys Rev A, 102(013114), 2020.
  7. A. Kawasaki, B. Braverman, E. Pedrozo-Peñafiel, C. Shu, S. Colombo, Z. Li, I. Ozel, W. Chen, D. Levonian, Y. Xiao, V. Vuletic, L. Salvi, A. Heinz, and D. Akamatsu. Geometrically asymmetric optical cavity for strong atom-photon coupling. Phys Rev A January 2019.
  8. B. Braverman, A. Kawasaki, E. Pedrozo-Peñafiel, S. Colombo, C. Shu, Z. Li, E. Mendez, Y. Xiao, V. Vuletic, M. Yamoah, L. Salvi, and D. Akamatsu. Near-Unitary Spin Squeezing in 171Yb. Phys. Rev. Lett., 122(223203), June 2019.
News
Thu February 3, 2022

Reversing time for quantum-enhanced metrology

The group of Prof. Vuletic, at MIT, demonstrated that reversing the time in an atomic sensor can lead to a strongly enhanced sensitivity. With this time-reversal protocol, sensors can be operated with highly-entangled states which carry large statistical information close to the fundamental Heisenberg Limit.  Due to their fragility, these “superior” quantum states are extremely...
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News type:
Research Highlights
Sun June 7, 2020

Entanglement-based Optical Atomic Clock beats the Standard Quantum Limit

Optical lattice clocks (OLC) are widely recognized as the next golden standard for timekeeping. Over the past decades, researchers around the world have made the second the best characterized among all seven of International System of Units (SI units), reaching an unprecedented fractional stability at few parts-of-ten-Quintillion (1019). Despite the tremendous effort of improving technology...
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News type:
Research Highlights
Thu May 9, 2019

Near Unitary Squeezing

A group at the MIT led by Prof. Vladan Vuletić has recently generated significant amount of spin squeezing-a type of quantum entanglement-in an ultracold vapor of ytterbium-171. Spin squeezed states (SSS) can be used to overcome the standard quantum limit (SQL) which bounds state-of-the-art atomic sensors like optical clocks. The latter deploy a dilute vapor...
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News type:
Research Highlights
Mon April 22, 2019

Direct Laser Cooling Rubidium Atoms

A group at MIT led by Vladan Vuletic has recently created a Bose-Einstein Condensate (BEC) of rubidium atoms with a new method, direct laser cooling. Many researchers have attempted this elusive goal in the past, but due to various complications resorted to reaching BEC through evaporation instead. Compared to cooling through evaporation, laser cooling is...
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News type:
Research Highlights
Past Events
Fri April 19, 2019 2:00 pm

CUA Cambridge Science Festival Workshop, 2019

Location:MIT 26-210 and 26-214
Benjamin L. Augenbraun
Simone Colombo
Joyce Kwan
Şukru Furkan Öztürk, Harvard
Martin W. Zwierlein
Edwin Pedrozo-Peñafiel
Event Website
Join CUA members to learn hands-on about some of the research that goes on in the CUA! Activities include a gum-drop model Ion Trap, a 6-foot Tornado Simulator, experiments with Liquid Nitrogen to see how ultracold temperatures change everyday objects, and a station to make your own holograms. The event will kick off with a...
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Event type:
Outreach Events
General Public
K through 12
Tue February 23, 2021 4:00 pm

CUA Virtual Seminar – Approaching the Heisenberg Limit with a time-reversal Hamiltonian

Location:Zoom
Simone Colombo

The creation of exotic quantum states that allow atomic sensors to operate beyond the Standard Quantum Limit (SQL) and near (or at) the Heisenberg Limit for many-particle systems has been a long-sought goal in Quantum Metrology. Gaussian Spin Squeezed States have been used to overcome the SQL in atomic sensors but offer limited quantum metrological advantages. To approach the Heisenberg Limit, Non-Gaussian Entangled States (NGES) with larger entanglement have to be engineered. However, the fragility of highly entangled states against decoherence and single-particle state resolution requirements have made difficult their experimental realization and application to atomic sensors with today’s technology.
We present here the implementation of a robust Signal Amplification through Time-reversal INteraction (SATIN) protocol, that allows for the generation of NGESs and the efficient use of their quantum resource. We demonstrate an angular resolution of 12.8 dB beyond the SQL for a system of 370 ytterbium-171 atoms (and 12.8 dB away from the Heisenberg limit), Heisenberg scaling with atom number, and a record-breaking phase-sensitive measurement of 11.8 dB beyond the SQL. We plan to transfer these NGESs to the optical-clock transition of ytterbium-171.

Event type:
CUA Seminar Series