Demonstration of stellar intensity interferometry with the four VERITAS telescopes

Abeysekara, A. U.; Benbow, W.; Brill, A.; Buckley, J. H.; Christiansen, J. L.; Chromey, Alisha; Daniel, M. K.; Davis, Jonathan; Falcone, A.; Feng, Q.; Finley, J. P.; Fortson, L.; Furniss, A.; Gent, A.; Giuri, C.; Gueta, O.; Hanna, D.; Hassan, Tarek; Hervet, O.; Holder, J.; Hughes, G.; Humensky, T. B.; Kaaret, Philip; Kertzman, M.; Kieda, D.; Krennrich, F.; Kumar, S.; LeBohec, Tugdual; Lin, T. T. Y.; Lundy, M.; Maier, G.; Matthews, Nolan; Moriarty, P.; Mukherjee, R.; Rosillo, M. Nievas; O’Brien, S.; Ong, R. A.; Otte, A. N.; Pfrang, K.; Pohl, Martin; Prado, R. R.; Pueschel, E.; Quinn, J.; Ragan, K.; Reynolds, P. T.; Ribeiro, D.; Richards, G.; Roache, E.; Ryan, J.; Santander, M.; Sembroski, G. H.; Wakely, S. P.; Weinstein, A.; Wilcox, P.; Williams, D. A.; Williamson, T. J.

doi:10.1038/s41550-020-1143-y

Cited by 47 publications

(34 citation statements)

References 38 publications

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“…The final visibility curve must be corrected for the presence of night sky background. After this correction, a suitable stellar diameter model is fitted to the visibility curve to extract a reliable measurement of the stellar diameter [7,8]. We will present a sampling of preliminary stellar diameter measurements for selected stars from the VSII survey at the conference.…”

Section: Data Analysis and Extraction Of Visibility Curvesmentioning

confidence: 99%

The VERITAS-Stellar Intensity Interferometry (VSII) survey of Stellar Diameters

Kieda¹,

Davis²,

LeBohec³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

451

691

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Section: Data Analysis and Extraction Of Visibility Curvesmentioning

confidence: 99%

The VERITAS-Stellar Intensity Interferometry (VSII) survey of Stellar Diameters

Kieda¹,

Davis²,

LeBohec³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

451

691

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“…Photon bunching was observationally shown for sunlight with a result of g (2) (τ ) = 1.45 ± 0.03 (Tan et al 2014), and g (2) (τ ) = 1.7; lower than the expected value of 2 due to noise. The same measurement was successfully performed with starlight (Tan & Kurtsiefer 2017) for stars such as P Cygni with a 1 m telescope, as well as β Canis Majoris and Orioni with the Veritas telescope (Abeysekara et al 2020). In all cases, a significant value for g (2) (τ ) > 1 was found.…”

Section: Bunching: Hanbury Brown and Twiss Effectmentioning

confidence: 66%

Searching for interstellar quantum communications

Hippke

2021

Preprint

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The modern search for extraterrestrial intelligence (SETI) began with the seminal publications of Cocconi & Morrison (1959) and Schwartz & Townes (1961), who proposed to search for narrow-band signals in the radio spectrum, and for optical laser pulses. Over the last six decades, more than one hundred dedicated search programs have targeted these wavelengths; all with null results. All of these campaigns searched for classical communications, that is, for a significant number of photons above a noise threshold; with the assumption of a pattern encoded in time and/or frequency space. I argue that future searches should also target quantum communications. They are preferred over classical communications with regards to security and information efficiency, and they would have escaped detection in all previous searches. The measurement of Fock state photons or squeezed light would indicate the artificiality of a signal. I show that quantum coherence is feasible over interstellar distances, and explain for the first time how astronomers can search for quantum transmissions sent by ETI to Earth, using commercially available telescopes and receiver equipment.

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“…From eq. 4 it is clear that intensity interferometry can be realized with large mirror sized telescopes equipped with fast and sensitive electronics, making Imaging Atmospheric Cherenkov Telescopes (IACTs), in particular the 17 meters diameter MAGIC ones, well suited platforms for the implementation of intensity interferometers and the measurement of the diameter of stars [3]. Given the typical distances between IACTs and the typical wavelength it can detect, eq.…”

Section: Pos(icrc2021)693mentioning

confidence: 99%

Intensity interferometry with the MAGIC telescopes

Delgado¹,

Acciari²,

Colombo³

et al. 2021

Proceedings of 37th International Cosmic Ray Conference — PoS(ICRC2021)

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Due to their large mirror size, fast response to single photons, sensitivity and telescope baselines in the order of 100 m, Imaging Atmospheric Cherenkov Telescopes are ideally suited to perform intensity interferometry observations. In 2019 a test readout setup was installed in the two 17-m diameter MAGIC telescopes to allow performing interferometry measurements with them. The first on-sky measurements were able to detect correlated intensity fluctuations consistent with the stellar diameters of three different stars: Adhara ( CMa), Benetnasch ( UMa) and Mirzam ( CMa). After the upgrade of the setup in 2021, MAGIC is now equipped with a high-duty-cycle intensity interferometer, already in operation. A technical description of the interferometer and first performance results obtained by measuring several known stellar diameter are presented.

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Demonstration of stellar intensity interferometry with the four VERITAS telescopes

Cited by 47 publications

References 38 publications

The VERITAS-Stellar Intensity Interferometry (VSII) survey of Stellar Diameters

The VERITAS-Stellar Intensity Interferometry (VSII) survey of Stellar Diameters

Searching for interstellar quantum communications

Intensity interferometry with the MAGIC telescopes

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