Digital holography as metrology tool at micro-nanoscale for soft matter

光:先进制造(英文) Pub Date : 2022-01-01 DOI:10.37188/lam.2022.010

Zhe Wang, L. Miccio, S. Coppola, V. Bianco, P. Memmolo, V. Tkachenko, V. Ferraro, E. Maio, P. Maffettone, P. Ferraro

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引用次数: 17

Abstract

The appearance of the first laser approximately 12 years after the invention of holography by Gabor (1948) revolutionized the field of optical metrology. In fact, the invention of holographic interferometry enabled the exploitation of interferometry on non-mirror surfaces and full-scale objects. The holography-based measurement methods has been implemented to several industrial systems or in support of R&D with the aim of improving new products in many fields (automotive, aerospace, electronics, etc.). To date, holography has been considered an important measurement tool for non-destructive inspection (NDI), strain-stress measurement, and vibration analysis at various engineering sites. Recently, the new paradigm of Industry4.0 has seen the introduction of new technologies and methods of processing materials as well as the development of manufacturing approaches for the realization of innovative products. For example, direct printing, additive, and bottom-up manufacturing processes are expected to involve new ways of making products in future, and most innovative fabrication processes will be based on the manipulation of soft matter (e.g., starting from the liquid phase) that will be shaped at the nanoscale. The inherent characteristics of digital holography (DH) make it a powerful and accurate tool for the visualization and testing of final products, as well as for in situ and real-time monitoring and quantitative characterization of the processes involved during the fabrication cycle. This review aims to report on the most useful applications of soft matter, where the capabilities offered by DH, such as three-dimensional (3D) imaging, extended focus, 3D tracking, full-field analysis, high sensitivity, and a wide range of measurements from nanometers to centimeters, permit completely non-invasive characterizations on a full-scale. Several holographic experimental results of typical samples are reported and discussed where DH plays a primary role as a tool gauge for soft matter. ACCEPTED ARTICLE PREVIEW

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数字全息术作为软物质微纳米尺度的测量工具

在Gabor(1948)发明全息术大约12年后，第一台激光器的出现彻底改变了光学计量学领域。事实上，全息干涉术的发明使干涉术在非镜面和全尺寸物体上的应用成为可能。基于全息术的测量方法已经实施到几个工业系统或支持研发，目的是改进许多领域(汽车，航空航天，电子等)的新产品。迄今为止，全息技术已被认为是无损检测(NDI)、应变-应力测量和各种工程现场振动分析的重要测量工具。最近，工业4.0的新范式已经引入了新的材料加工技术和方法，以及实现创新产品的制造方法的发展。例如，直接印刷、添加剂和自下而上的制造工艺预计将涉及未来制造产品的新方法，大多数创新的制造工艺将基于对软物质的操纵(例如，从液相开始)，这些软物质将在纳米尺度上成形。数字全息术(DH)的固有特性使其成为最终产品可视化和测试的强大而准确的工具，以及在制造周期中所涉及的过程的现场和实时监控和定量表征。本综述旨在报告软物质最有用的应用，其中DH提供的功能，如三维(3D)成像，扩展聚焦，3D跟踪，全视野分析，高灵敏度，从纳米到厘米的广泛测量范围，允许在全尺寸上进行完全无创的表征。本文报道并讨论了几个典型样品的全息实验结果，其中DH作为软物质的测量工具发挥了主要作用。接受文章预览

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

光:先进制造(英文)

CiteScore

10.90

自引率

0.00%

发文量