Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper

Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper

We characterize an affordable method of producing stencils for submillimeter physical vapor deposition (PVD) by using paper and a benchtop laser cutter. Patterning electrodes or similar features on top of organic or biological substrates is generally not possible using standard photolithography. Sha...

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Bibliographic Details
Main Authors: Farzad Elhami Nik, Isabelle Matthiesen, Anna Herland, Thomas E. Winkler
Format: Article
Language:English
Published: MDPI AG 2020-07-01
Series:Micromachines
Subjects:
shadow mask
stencil lithography
CO<sub>2</sub> laser
paper
metal deposition
Online Access:https://www.mdpi.com/2072-666X/11/7/676
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spelling doaj-26bf77e1754044368265d2233ed593d72020-11-25T03:42:14ZengMDPI AGMicromachines2072-666X2020-07-011167667610.3390/mi11070676Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut PaperFarzad Elhami Nik0Isabelle Matthiesen1Anna Herland2Thomas E. Winkler3Division of Micro- and Nanosystems, KTH Royal Institute of Technology, 11428 Stockholm, SwedenDivision of Micro- and Nanosystems, KTH Royal Institute of Technology, 11428 Stockholm, SwedenDivision of Micro- and Nanosystems, KTH Royal Institute of Technology, 11428 Stockholm, SwedenDivision of Micro- and Nanosystems, KTH Royal Institute of Technology, 11428 Stockholm, SwedenWe characterize an affordable method of producing stencils for submillimeter physical vapor deposition (PVD) by using paper and a benchtop laser cutter. Patterning electrodes or similar features on top of organic or biological substrates is generally not possible using standard photolithography. Shadow masks, traditionally made of silicon-based membranes, circumvent the need for aggressive solvents but suffer from high costs. Here, we evaluate shadow masks fabricated by CO<sub>2</sub> laser processing from quantitative filter papers. Such papers are stiff and dimensionally stable, resilient in handling, and cut without melting or redeposition. Using two exemplary interdigitated electrode designs, we quantify the line resolution achievable with both high-quality and standard lenses, as well as the positional accuracy across multiple length scales. Additionally, we assess the gap between such laser-cut paper masks and a substrate, and quantify feature reproduction onto polycarbonate membranes. We find that ~100 µm line widths are achievable independent of lens type and that average positional accuracy is better than ±100 µm at 4”-wafer scale. Although this falls well short of the micron-size features achievable with typical shadow masks, resolution in the tenths to tens of millimeters is entirely sufficient for applications from contact pads to electrochemical cells, allowing new functionalities on fragile materials.https://www.mdpi.com/2072-666X/11/7/676shadow maskstencil lithographyCO<sub>2</sub> laserpapermetal deposition
collection DOAJ
language English
format Article
sources DOAJ
author Farzad Elhami Nik
Isabelle Matthiesen
Anna Herland
Thomas E. Winkler
spellingShingle Farzad Elhami Nik
Isabelle Matthiesen
Anna Herland
Thomas E. Winkler
Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
Micromachines
shadow mask
stencil lithography
CO<sub>2</sub> laser
paper
metal deposition
author_facet Farzad Elhami Nik
Isabelle Matthiesen
Anna Herland
Thomas E. Winkler
author_sort Farzad Elhami Nik
title Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
title_short Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
title_full Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
title_fullStr Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
title_full_unstemmed Low-Cost PVD Shadow Masks with Submillimeter Resolution from Laser-Cut Paper
title_sort low-cost pvd shadow masks with submillimeter resolution from laser-cut paper
publisher MDPI AG
series Micromachines
issn 2072-666X
publishDate 2020-07-01
description We characterize an affordable method of producing stencils for submillimeter physical vapor deposition (PVD) by using paper and a benchtop laser cutter. Patterning electrodes or similar features on top of organic or biological substrates is generally not possible using standard photolithography. Shadow masks, traditionally made of silicon-based membranes, circumvent the need for aggressive solvents but suffer from high costs. Here, we evaluate shadow masks fabricated by CO<sub>2</sub> laser processing from quantitative filter papers. Such papers are stiff and dimensionally stable, resilient in handling, and cut without melting or redeposition. Using two exemplary interdigitated electrode designs, we quantify the line resolution achievable with both high-quality and standard lenses, as well as the positional accuracy across multiple length scales. Additionally, we assess the gap between such laser-cut paper masks and a substrate, and quantify feature reproduction onto polycarbonate membranes. We find that ~100 µm line widths are achievable independent of lens type and that average positional accuracy is better than ±100 µm at 4”-wafer scale. Although this falls well short of the micron-size features achievable with typical shadow masks, resolution in the tenths to tens of millimeters is entirely sufficient for applications from contact pads to electrochemical cells, allowing new functionalities on fragile materials.
topic shadow mask
stencil lithography
CO<sub>2</sub> laser
paper
metal deposition
url https://www.mdpi.com/2072-666X/11/7/676
work_keys_str_mv AT farzadelhaminik lowcostpvdshadowmaskswithsubmillimeterresolutionfromlasercutpaper
AT isabellematthiesen lowcostpvdshadowmaskswithsubmillimeterresolutionfromlasercutpaper
AT annaherland lowcostpvdshadowmaskswithsubmillimeterresolutionfromlasercutpaper
AT thomasewinkler lowcostpvdshadowmaskswithsubmillimeterresolutionfromlasercutpaper
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