Quantum Optical Tomography Using a Time-Resolved and Mode-Selective Frequency-Up-Conversion Detector

Oceans Pub Date : 2023-06-26 DOI:10.1109/CLEO/Europe-EQEC57999.2023.10231363

N. Namekata, Nobuaki Kobayashi, Kenya Nomura, Tokuei Sako, Norio Takata, S. Inoue

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Abstract

Optical coherence tomography (OCT) is a well-established non-contact and non-invasive method for three-dimensional structural imaging of complex samples [1]. This technique is actively used for various biomedical applications, such as medical diagnosis. However, the relatively shallow penetration depth is considered a serious limitation for many applications. Optical time-of-flight (TOF) measurements provide an alternative way to acquire three-dimensional structural images. A temporal resolution of 150 femtoseconds corresponding to the axial resolution comparable to OCT has been reported [2]. The penetration depth would be enhanced by using the wavelength in the spectral window of 1550 - 1800 nm, because the scattering and absorption losses can be reduced. Besides them, the phenomenon of multiple scattering also makes it difficult to achieve meaningful structural information at deeper penetration depths. To enhance image contrast at larger penetration depths, multiply scattered photons must be removed. Although they overlap in both spectral and time domain with the singly reflected signal photons, they would be removed by the mode-selective up-conversion single-photon detector (UCSPD) [3], [4]. We report on the optical TOF measurement system using the time-resolved and mode-selective UCSPD and its application to the tomographic image acquisition of a mouse brain.

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使用时间分辨和模式选择频率上转换检测器的量子光学层析成像

光学相干层析成像(Optical coherence tomography, OCT)是一种成熟的非接触、非侵入性的复杂样品三维结构成像方法[1]。该技术被积极用于各种生物医学应用，如医学诊断。然而，相对较浅的穿透深度被认为是许多应用的严重限制。光学飞行时间(TOF)测量提供了另一种获取三维结构图像的方法。据报道，与OCT相当的轴向分辨率对应的时间分辨率为150飞秒[2]。利用光谱窗口1550 ~ 1800 nm的波长可以减小散射和吸收损失，从而提高穿透深度。除此之外，多重散射现象也使得在更深的穿透深度下难以获得有意义的结构信息。为了提高在较大穿透深度下的图像对比度，必须去除多重散射光子。虽然它们在光谱和时域上都与单反射信号光子重叠，但它们会被模式选择上转换单光子探测器(UCSPD)去除[3]，[4]。本文报道了采用时间分辨和模式选择的UCSPD光学TOF测量系统及其在小鼠脑层析成像中的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Oceans

CiteScore

3.10

自引率

0.00%

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