Quasicommon-path digital holographic microscopy with phase aberration compensation based on a long-working distance objective

Jianglei Di; Kaiqiang Wang; Jiwei Zhang; Chaojie Ma; Teli Xi; Ying Li; Kun Wei; Weijuan Qu; Jianlin Zhao

doi:10.1117/1.OE.57.2.024108

Quasicommon-path digital holographic microscopy with phase aberration compensation based on a long-working distance objective

Jianglei Di, Kaiqiang Wang, Jiwei Zhang, Chaojie Ma, Teli Xi, Ying Li, Kun Wei, Weijuan Qu, Jianlin Zhao

物理科学与技术学院

科研成果: 期刊稿件 › 文章 › 同行评审

2 引用（Scopus）

摘要

We present a quasicommon-path digital holographic microscopy with phase aberration compensation, which is based on a long-working distance objective and can be used for the quantitative characterization of microstructure specimens. The quasicommon-path arrangement makes the holographic system very compact and stable. Meanwhile, the object and reference beams all travel along the same path, which can effectively eliminate the system aberration, and the mirror in the reference arm can be adjusted precisely for the phase tilt compensation. In the experiment, a wafer with orderly patterns and unified height of 180 nm is measured, and its three-dimensional surface topography is obtained. A long-term system stability of 1.39 nm is achieved in measurement with the proposed method.

源语言	英语
文章编号	024108
期刊	Optical Engineering
卷	57
期	2
DOI	https://doi.org/10.1117/1.OE.57.2.024108
出版状态	已出版 - 1 2月 2018

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title = "Quasicommon-path digital holographic microscopy with phase aberration compensation based on a long-working distance objective",

abstract = "We present a quasicommon-path digital holographic microscopy with phase aberration compensation, which is based on a long-working distance objective and can be used for the quantitative characterization of microstructure specimens. The quasicommon-path arrangement makes the holographic system very compact and stable. Meanwhile, the object and reference beams all travel along the same path, which can effectively eliminate the system aberration, and the mirror in the reference arm can be adjusted precisely for the phase tilt compensation. In the experiment, a wafer with orderly patterns and unified height of 180 nm is measured, and its three-dimensional surface topography is obtained. A long-term system stability of 1.39 nm is achieved in measurement with the proposed method.",

keywords = "aberration compensation, digital holographic microscopy, phase measurement, quasicommon-path configuration",

author = "Jianglei Di and Kaiqiang Wang and Jiwei Zhang and Chaojie Ma and Teli Xi and Ying Li and Kun Wei and Weijuan Qu and Jianlin Zhao",

note = "Publisher Copyright: {\textcopyright} 2018 Society of Photo-Optical Instrumentation Engineers (SPIE).",

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T1 - Quasicommon-path digital holographic microscopy with phase aberration compensation based on a long-working distance objective

AU - Di, Jianglei

AU - Wang, Kaiqiang

AU - Zhang, Jiwei

AU - Ma, Chaojie

AU - Xi, Teli

AU - Li, Ying

AU - Wei, Kun

AU - Qu, Weijuan

AU - Zhao, Jianlin

PY - 2018/2/1

Y1 - 2018/2/1

N2 - We present a quasicommon-path digital holographic microscopy with phase aberration compensation, which is based on a long-working distance objective and can be used for the quantitative characterization of microstructure specimens. The quasicommon-path arrangement makes the holographic system very compact and stable. Meanwhile, the object and reference beams all travel along the same path, which can effectively eliminate the system aberration, and the mirror in the reference arm can be adjusted precisely for the phase tilt compensation. In the experiment, a wafer with orderly patterns and unified height of 180 nm is measured, and its three-dimensional surface topography is obtained. A long-term system stability of 1.39 nm is achieved in measurement with the proposed method.

AB - We present a quasicommon-path digital holographic microscopy with phase aberration compensation, which is based on a long-working distance objective and can be used for the quantitative characterization of microstructure specimens. The quasicommon-path arrangement makes the holographic system very compact and stable. Meanwhile, the object and reference beams all travel along the same path, which can effectively eliminate the system aberration, and the mirror in the reference arm can be adjusted precisely for the phase tilt compensation. In the experiment, a wafer with orderly patterns and unified height of 180 nm is measured, and its three-dimensional surface topography is obtained. A long-term system stability of 1.39 nm is achieved in measurement with the proposed method.

KW - aberration compensation

KW - digital holographic microscopy

KW - phase measurement

KW - quasicommon-path configuration

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DO - 10.1117/1.OE.57.2.024108

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JO - Optical Engineering

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Quasicommon-path digital holographic microscopy with phase aberration compensation based on a long-working distance objective

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