Direct laser patterning of glass mask for micro display using GHz bursts-Reference-Cited by-同舟云学术

Direct laser patterning of glass mask for micro display using GHz bursts

Published:2024-05 Issue:5 Volume:32 Page:426-434
ISSN:1071-0922
Container-title:Journal of the Society for Information Display
language:en
Short-container-title:J Soc Info Display

Author:

Jung Woohyun¹^ORCID,Kim Hyungsik¹^ORCID,Mishchik Konstantin¹,Lee Kisang¹,Ryu Jekil¹,Lee Seung Joo¹,Jeong Seong Ho²,Roh Cheol Lae³

Affiliation:

1. Equipment Core Technology Development Team Samsung Display Youngin‐si Gyeonggi‐do South Korea

2. FAB Equipment Development Team Samsung Display Youngin‐si Gyeonggi‐do South Korea

3. Mechatronics Technology Research Center Samsung Display Youngin‐si Gyeonggi‐do South Korea

Abstract

AbstractDevelopment of high‐precision RGB patterning process is needed to implement high‐resolution micro display (OLEDoS) for next‐generation VR/AR products. In general, specially designed and manufactured masks are required to realize above 3000‐ppi high‐resolution display in structured OLED material deposition. In this study, we developed direct laser patterning IR‐fs optical system operating in MHz and GHz burst modes and evaluated its capability for precise micro‐drilling of aluminoborosilicate glass materials. The fine hole‐shaped pattern is produced at a minimum of 5 μm pitch level for about 0.6 in. area without sacrificing the glass strength. It is expected to contribute to the high precise manufacture of ultra fine mask (UFM) using thin glass platform corresponding to micro displays in the future.

Publisher

Wiley

Reference19 articles.

1. 17‐5: Enhancement of Luminance Efficiency of 3,000ppi OLED Micro‐display using RGB Direct Patterning

2. 85‐1: Ultrahigh‐Resolution Corrugated Silicon Nitride Masks for Direct Patterning of OLED Microdisplays

3. High-Pixel-Density Fine Metal Mask Fabricated by Electroforming of Fe-Ni Alloy onto UV-nanoimprinted Resin Pattern on Si Substrate

4. 76‐2: Fine Glass Masks (FGMs) for OLED Manufacturing Made by Laser Induced Deep Etching (LIDE)

5. Computer generation of optimal holograms for optical trap arrays