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(Reference retrieved automatically from Web of Science through information on FAPESP grant and its corresponding number as mentioned in the publication by the authors.)

Hot embossing of aspherical Fresnel microlenses: design, process, and characterization

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Author(s):
Colafemina, Joao Paulo [1] ; Militao Dib, Marcel Henrique [2] ; Jasinevicius, Renato Goulart [3]
Total Authors: 3
Affiliation:
[1] Fed Inst Educ Sci & Technol Sao Paulo, Sertaozinho, SP - Brazil
[2] Fed Inst Educ Sci & Technol Sao Paulo, Araraquara, SP - Brazil
[3] Univ Sao Paulo, Engn Sch Sao Carlos, Dept Mech Engn, Precis Engn Lab, Sao Carlos, SP - Brazil
Total Affiliations: 3
Document type: Journal article
Source: INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY; v. 113, n. 3-4, p. 935-953, MAR 2021.
Web of Science Citations: 0
Abstract

Hot embossing is a technique used to fabricate high-precision and high-quality polymeric components that combines low costs with high aspect ratio fidelity replication. In this study, we manufactured two aspherical Fresnel molds employing the single-point diamond turning process on an electrolytic copper workpiece, one with 10 mu m constant height 30 zones and the other with 250 mu m constant width 40 zones. The micromachined mold reproduced PMMA convex-plane lens optical quality replicas through the micro hot embossing technique. We used a scanning electron microscope (SEM), spectrophotometry, and non-contact optical profilometer to evaluate the replication fidelity qualitatively: the lens mold and the fine three-dimensional microstructures on the PMMA substrate surfaces. The results of the surface finish of the diamond machined mold sample are in the range of 4.92 nm (areal average surface roughness Sa) and 6.04 nm (areal root-mean-squared roughness Sq), respectively, and the values for the replicas being 4.73 nm and 5.94 nm, respectively. The results demonstrated that the geometry form accuracy obtained of the microfeatures was at the submicron level with little viscoelastic recovery. The surface roughness in the nanometer level got successfully replicated. (AU)