Simulation of temporal second-order correlation function based on Monte Carlo algorithm

Yongsheng Hu; Tengfei Ma; Danqun Mao; Zhenyu Wang; Weihang Zhou; Hongxing Xu; Hongxing Dong; Wei Xie

doi:10.15302/frontphys.2025.034204

Simulation of temporal second-order correlation function based on Monte Carlo algorithm

Yongsheng Hu
, Tengfei Ma
, Danqun Mao
, Zhenyu Wang
, Weihang Zhou^*
, Hongxing Xu
, Hongxing Dong
, Wei Xie^*

^*此作品的通讯作者

精密光谱科学与技术高等研究院

East China Normal University
Huazhong University of Science and Technology
Wuhan University
Wuhan Institute of Quantum Technology
CAS - Shanghai Institute of Optics and Fine Mechanics

科研成果: 期刊稿件 › 文章 › 同行评审

1 引用（Scopus）

摘要

The second-order correlation function of photons is the primary means to quantitatively describe the second-order coherence of a light field. In contrast to the stationary second-order correlation function, the temporal second-order correlation function can be used to study the second-order coherence of a transient light field. Based on the Monte Carlo algorithm, we carried out theoretical simulation on the temporal second-order correlation function from the perspective of photon statistics. By introducing experimental factors into the simulation, such as intensity jitter of the light field and time resolution of the instruments, the effects of imperfect experimental conditions on the measurement of second-order correlation function have also been elucidated. Our results provide theoretical guidance and analysis methods for experimental measurements on the second-order coherence of light fields.

源语言	英语
文章编号	034204
期刊	Frontiers of Physics
卷	20
期	3
DOI	https://doi.org/10.15302/frontphys.2025.034204
出版状态	已出版 - 2025

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title = "Simulation of temporal second-order correlation function based on Monte Carlo algorithm",

abstract = "The second-order correlation function of photons is the primary means to quantitatively describe the second-order coherence of a light field. In contrast to the stationary second-order correlation function, the temporal second-order correlation function can be used to study the second-order coherence of a transient light field. Based on the Monte Carlo algorithm, we carried out theoretical simulation on the temporal second-order correlation function from the perspective of photon statistics. By introducing experimental factors into the simulation, such as intensity jitter of the light field and time resolution of the instruments, the effects of imperfect experimental conditions on the measurement of second-order correlation function have also been elucidated. Our results provide theoretical guidance and analysis methods for experimental measurements on the second-order coherence of light fields.",

keywords = "Monte Carlo algorithm, autocorrelation, cross-correlation, temporal second-order correlation function",

author = "Yongsheng Hu and Tengfei Ma and Danqun Mao and Zhenyu Wang and Weihang Zhou and Hongxing Xu and Hongxing Dong and Wei Xie",

note = "Publisher Copyright: {\textcopyright} Higher Education Press 2025.",

year = "2025",

doi = "10.15302/frontphys.2025.034204",

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T1 - Simulation of temporal second-order correlation function based on Monte Carlo algorithm

AU - Hu, Yongsheng

AU - Ma, Tengfei

AU - Mao, Danqun

AU - Wang, Zhenyu

AU - Zhou, Weihang

AU - Xu, Hongxing

AU - Dong, Hongxing

AU - Xie, Wei

N1 - Publisher Copyright: © Higher Education Press 2025.

PY - 2025

Y1 - 2025

N2 - The second-order correlation function of photons is the primary means to quantitatively describe the second-order coherence of a light field. In contrast to the stationary second-order correlation function, the temporal second-order correlation function can be used to study the second-order coherence of a transient light field. Based on the Monte Carlo algorithm, we carried out theoretical simulation on the temporal second-order correlation function from the perspective of photon statistics. By introducing experimental factors into the simulation, such as intensity jitter of the light field and time resolution of the instruments, the effects of imperfect experimental conditions on the measurement of second-order correlation function have also been elucidated. Our results provide theoretical guidance and analysis methods for experimental measurements on the second-order coherence of light fields.

AB - The second-order correlation function of photons is the primary means to quantitatively describe the second-order coherence of a light field. In contrast to the stationary second-order correlation function, the temporal second-order correlation function can be used to study the second-order coherence of a transient light field. Based on the Monte Carlo algorithm, we carried out theoretical simulation on the temporal second-order correlation function from the perspective of photon statistics. By introducing experimental factors into the simulation, such as intensity jitter of the light field and time resolution of the instruments, the effects of imperfect experimental conditions on the measurement of second-order correlation function have also been elucidated. Our results provide theoretical guidance and analysis methods for experimental measurements on the second-order coherence of light fields.

KW - Monte Carlo algorithm

KW - autocorrelation

KW - cross-correlation

KW - temporal second-order correlation function

UR - https://www.scopus.com/pages/publications/105000421571

U2 - 10.15302/frontphys.2025.034204

DO - 10.15302/frontphys.2025.034204

M3 - 文章

AN - SCOPUS:105000421571

SN - 2095-0462

VL - 20

JO - Frontiers of Physics

JF - Frontiers of Physics

IS - 3

M1 - 034204

ER -

Simulation of temporal second-order correlation function based on Monte Carlo algorithm

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