Related papers: Multifold enhancement of quantum SNR by using an EMCCD as a photon number resolving device

Multifold enhancement of quantum SNR by using an EMCCD as a photon number resolving device

URL: http://arxiv.org/abs/2312.04184v2
Date: Fri, 19 Apr 2024 09:37:26 GMT
Title: Multifold enhancement of quantum SNR by using an EMCCD as a photon number resolving device
Authors: Rounak Chatterjee, Vikas Bhat, Kiran Bajar, Sushil Mujumdar,
Abstract summary: We present a method to estimate the mean rate of photons per pixel per frame for arbitrary exposure time. This allows us to effectively utilize the EMCCD as a photon number resolving device.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The Electron Multiplying Charge Coupled Devices (EMCCD), owing to their high quantum efficiency and spatial resolution, are widely used to study typical quantum optical phenomena and related applications. Researchers have already developed a procedure that enables one to statistically determine whether a pixel detects a single photon, based on whether its output is higher or lower than the estimated noise level. However, these techniques are feasible at extremely low photon numbers (about 0.15 mean number of photons per pixel per exposure), allowing for at most one photon per pixel. This limitation necessitates a very large number of frames required for any study. In this work, we present a method to estimate the mean rate of photons per pixel per frame for arbitrary exposure time. Subsequently, we make a statistical estimate of the number of photons (greater than or equal to 1) incident on each pixel. This allows us to effectively utilize the EMCCD as a photon number resolving device. This immediately augments the acceptable light levels in the experiments, leading to significant reduction in the required experimentation time. As evidence of our approach, we quantify contrast in quantum correlation exhibited by a pair of spatially entangled photons generated by Spontaneous Parametric Down Conversion process. In comparison to conventional methods, our method realizes an enhancement in the signal to noise ratio by about a factor of 3 for half the data collection time. This SNR can be easily enhanced by minor modifications in experimental parameters such as exposure time etc.

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