Peng Kian Tan scite author profile

Light from thermal black body radiators such as stars exhibits photon bunching behaviour at sufficiently short time-scales. However, with available detector bandwidths, this bunching signal is difficult to be directly used for intensity interferometry with sufficient statistics in astronomy. Here we present an experimental technique to increase the photon bunching signal in blackbody radiation via spectral filtering of the light source. Our measurements reveal strong temporal photon bunching in light from blackbody radiation, including the Sun. Such filtering techniques may revive the interest in intensity interferometry as a tool in astronomy.

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Optical intensity interferometry through atmospheric turbulence

Tan¹,

Chan²,

Kurtsiefer³

2016

Mon. Not. R. Astron. Soc.

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Conventional ground-based astronomical observations suffer from image distortion due to atmospheric turbulence. This can be minimized by choosing suitable geographic locations or adaptive optical techniques, and avoided altogether by using orbital platforms outside the atmosphere. One of the promises of optical intensity interferometry is its independence from atmospherically induced phase fluctuations. By performing narrowband spectral filtering on sunlight and conducting temporal intensity interferometry using actively quenched avalanche photon detectors (APDs), the Solar g (2) (τ ) signature was directly measured. We observe an averaged photon bunching signal of g (2) (τ ) = 1.693 ± 0.003 from the Sun, consistently throughout the day despite fluctuating weather conditions, cloud cover and elevation angle. This demonstrates the robustness of the intensity interferometry technique against atmospheric turbulence and opto-mechanical instabilities, and the feasibility to implement measurement schemes with both large baselines and long integration times.

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Temporal intensity interferometry for characterization of very narrow spectral lines

Tan

Kurtsiefer

2017

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Breakdown flash at telecom wavelengths in InGaAs avalanche photodiodes

Shi¹,

Lim²,

Poh³

et al. 2017

Opt. Express

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Quantum key distribution (QKD) at telecom wavelengths (1260 - 1625 nm) has the potential for fast deployment due to existing optical fibre infrastructure and mature telecom technologies. At these wavelengths, Indium Gallium Arsenide (InGaAs) avalanche photodiode (APD) based detectors are the preferred choice for photon detection. Similar to their Silicon counterparts used at shorter wavelengths, they exhibit fluorescence from recombination of electron-hole pairs generated in the avalanche breakdown process. This fluorescence may open side channels for attacks on QKD systems. Here, we characterize the breakdown fluorescence from two commercial InGaAs single photon counting modules, and find a spectral distribution between 1000 nm and 1600 nm. We also show that by spectral filtering, this side channel can be efficiently suppressed.

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Peng Kian Tan

Measuring Temporal Photon Bunching in Blackbody Radiation

Optical intensity interferometry through atmospheric turbulence

Temporal intensity interferometry for characterization of very narrow spectral lines

Breakdown flash at telecom wavelengths in InGaAs avalanche photodiodes

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