Fabrication method of quartz aspheric microlens array for turning mask

Similar documents
Lecture 22 Optical MEMS (4)

All-Glass Gray Scale PhotoMasks Enable New Technologies. Che-Kuang (Chuck) Wu Canyon Materials, Inc.

Pulsed Laser Ablation of Polymers for Display Applications

Fabrication of plastic microlens array using gas-assisted micro-hot-embossing with a silicon mold

Lithography. 3 rd. lecture: introduction. Prof. Yosi Shacham-Diamand. Fall 2004

Part 5-1: Lithography

Fabrication of micro structures on curve surface by X-ray lithography

ICMIEE Generation of Various Micropattern Using Microlens Projection Photolithography

Low aberration monolithic diffraction gratings for high performance optical spectrometers

Maskless Lithography Based on Digital Micro-Mirror Device (DMD) with Double Sided Microlens and Spatial Filter Array

Fabrication of micro DOE using micro tools shaped with focused ion beam

Design of athermal arrayed waveguide grating using silica/polymer hybrid materials

UV EXCIMER LASER BEAM HOMOGENIZATION FOR MICROMACHINING APPLICATIONS

EUVL Activities in China. Xiangzhao Wang Shanghai Inst. Of Opt. and Fine Mech. Of CAS. (SIOM) Shanghai, China.

Sapphire-Based Dammann Gratings for UV Beam Splitting

Profile Measurement of Resist Surface Using Multi-Array-Probe System

Microlens formation using heavily dyed photoresist in a single step

Fabrication Techniques of Optical ICs

CHAPTER 2 Principle and Design

Research of photolithography technology based on surface plasmon

Proceeding The Alignment Method for Linear Scale Projection Lithography Based on CCD Image Analysis

Virtual input device with diffractive optical element

A BASIC EXPERIMENTAL STUDY OF CAST FILM EXTRUSION PROCESS FOR FABRICATION OF PLASTIC MICROLENS ARRAY DEVICE

Development of Orderly Micro Asperity on Polishing Pad Surface for Chemical Mechanical Polishing (CMP) Process using Anisotropic Etching

99. Sun sensor design and test of a micro satellite

Soft Electronics Enabled Ergonomic Human-Computer Interaction for Swallowing Training

Fiber-optic Michelson Interferometer Sensor Fabricated by Femtosecond Lasers

NANOFABRICATION, THE NEW GENERATION OF LITHOGRAPHY. Cheng-Sheng Huang & Alvin Chang ABSTRACT

Fabrication of suspended micro-structures using diffsuser lithography on negative photoresist

Supporting Information: Experimental. Demonstration of Demagnifying Hyperlens

Facile and flexible fabrication of gapless microlens arrays using a femtosecond laser microfabrication and replication process

3-5μm F-P Tunable Filter Array based on MEMS technology

Nanoimprinting of micro-optical components fabricated using stamps made with Proton Beam Writing

A NEW INNOVATIVE METHOD FOR THE FABRICATION OF SMALL LENS ARRAY MOLD INSERTS

Parameter Optimization by Taguchi Methods for Polishing LiTaO3 Substrate. Using Force-induced Rheological Polishing Method

Supporting Information Content

2D silicon-based surface-normal vertical cavity photonic crystal waveguide array for high-density optical interconnects

Micro-Nanofabrication

Two step process for the fabrication of diffraction limited concave microlens arrays

Analysis and optimization on single-zone binary flat-top beam shaper

Correlation Demodulation of Output Spectrum of Fabry-Perot Cavity

Linewidth control by overexposure in laser lithography

Optimization of Process Parameters to Achieve Nano Level Surface Quality on Polycarbonate

Innovative Mask Aligner Lithography for MEMS and Packaging

Feature-level Compensation & Control

Fabrication of PDMS (polydimethylsiloxane) microlens and diffuser using replica molding

Multi-Spectra Artificial Compound Eyes, Design, Fabrication and Applications

Directional Growth of Ultra-long CsPbBr 3 Perovskite. Nanowires for High Performance Photodetectors

A New Profile Measurement Method for Thin Film Surface

Single Nanoparticle Plasmonic Electro-Optic Modulator Based on MoS 2 Monolayers

Multi-aperture camera module with 720presolution

Measurement of channel depth by using a general microscope based on depth of focus

MEMS for RF, Micro Optics and Scanning Probe Nanotechnology Applications

IMAGING SILICON NANOWIRES

Section 2: Lithography. Jaeger Chapter 2. EE143 Ali Javey Slide 5-1

Novel optical Measurement System for Laser Transmittance. and Reflectance of Materials*

Femtosecond Pulsed Laser Direct Writing System for Photomask Fabrication

Vertical Nanowall Array Covered Silicon Solar Cells

MICROMACHINED INTERFEROMETER FOR MEMS METROLOGY

DESIGN OF TRI-BAND PRINTED MONOPOLE ANTENNA FOR WLAN AND WIMAX APPLICATIONS

Optical MEMS pressure sensor based on a mesa-diaphragm structure

The Department of Advanced Materials Engineering. Materials and Processes in Polymeric Microelectronics

Realization of Polarization-Insensitive Optical Polymer Waveguide Devices

Ultra-thin Die Characterization for Stack-die Packaging

Guided resonance reflective phase shifters

Fabricating micro-structured surface by using single-crystalline diamond endmill

Design and fabrication of indium phosphide air-bridge waveguides with MEMS functionality

Project Staff: Timothy A. Savas, Michael E. Walsh, Thomas B. O'Reilly, Dr. Mark L. Schattenburg, and Professor Henry I. Smith

OPTI510R: Photonics. Khanh Kieu College of Optical Sciences, University of Arizona Meinel building R.626

Fabrication of Silicon Master Using Dry and Wet Etching for Optical Waveguide by Thermal Embossing Technique

Rapid fabrication of ultraviolet-cured polymer microlens arrays by soft roller stamping process

Study on Optical Property of Fabricating Free-form Micro-optical Element by Varying Dose Exposure Method

RCS Reduction of Patch Array Antenna by Complementary Split-Ring Resonators Structure

Micromachining of packaging materials for MEMS using lasers

Copyright 2000 by the Society of Photo-Optical Instrumentation Engineers.

A study on the fabrication method of middle size LGP using continuous micro-lenses made by LIGA reflow

Polymer Optical Waveguide Fabrication Using Laser Ablation

Sidewall lithography of micron-sized features in high-aspect-ratio meso-scale channels using a three-dimensional assembled mask

Design of Temperature Sensitive Structure for Micromechanical Silicon Resonant Accelerometer

Compact Triple-Band Monopole Antenna with Inverted-L Slots and SRR for WLAN/WiMAX Applications

A Novel Multiband MIMO Antenna for TD-LTE and WLAN Applications

Laser patterning and projection lithography

Supporting Information. A Tough and High-Performance Transparent Electrode from a. Scalable Transfer-Free Method

Backplane Considerations for an RGB 3D Display Device

Miniature Mid-Infrared Thermooptic Switch with Photonic Crystal Waveguide Based Silicon-on-Sapphire Mach Zehnder Interferometers

Nanofabrication technologies: high-throughput for tomorrow s metadevices

Application of Single Point Diamond Turning in Infrared Optics

Snapshot Mask-less fabrication of embedded monolithic SU-8 microstructures with arbitrary topologies

EE143 Fall 2016 Microfabrication Technologies. Lecture 3: Lithography Reading: Jaeger, Chap. 2

Switchable Fresnel lens using polymer-stabilized liquid crystals

Supplementary information for Stretchable photonic crystal cavity with

The Beam Characteristics of High Power Diode Laser Stack

This writeup is adapted from Fall 2002, final project report for by Robert Winsor.

Introduction of ADVANTEST EB Lithography System

High Performance Silicon-Based Inductors for RF Integrated Passive Devices

Hybrid Integration Technology of Silicon Optical Waveguide and Electronic Circuit

Optical Requirements

Figure 7 Dynamic range expansion of Shack- Hartmann sensor using a spatial-light modulator

Optical planar multimode 1x2Y splitters

Nanostencil Lithography and Nanoelectronic Applications

Transcription:

Opto-Electronic Engineering Article 018 45 4 1 1300 400714 Reactive ion etching Single point diamond turning Photoresist Glass substrate 5 mm 5 mm 1.155 nm 0.47% O439 A. [J]. 018 45(4): 170671 Fabrication method of quartz aspheric microlens array for turning mask 1 School of Opto-Engineering, Changchun University of Science and Technology, Changchun, Jilin 1300, China; Micro-Nano Manufacturing and System Integration Center, Chongqing Institute of Green and Intelligent Technology, Chinese Academy of Sciences, Chongqing 400714, China Abstract: In order to solve the two difficult problems of the poor processing controllability and the low surface accuracy of quartz aspheric microlens array processing, a fabrication method of quartz aspheric microlens array for turning mask is proposed. This method mainly uses single point diamond turning technology and reactive ion etching technology, studies the turning and etching properties of the mask material, and optimizes the mask material by experiment. Finally, the fabrication of an aspherical glass microlens array with an area of 5 mm 5 mm was carried out. The experimental results are compared with the expected parameters. The analysis shows that the error root mean square of the quartz glass component is 1.155 nm, and the surface accuracy error is 0.47%. Keywords: mask; quartz glass; aspheric microlens array; SPDT; RIE Citation: Wang H, Dong L H, Zhu G D, et al. Fabrication method of quartz aspheric microlens array for turning mask [J]. Opto-Electronic Engineering, 018, 45(4): 170671 017 1 09 018 01 05 (199-) E-mail: 41653961@qq.com (1953-) E-mail custdong@16.com (1983-) E-mail zwg@cigit.ac.cn 170671-1

1 [1] Zhang 157 nm(f ) 48 nm(krf) [] [3] 4.5 nm [4] Langridge 4 nm [5] (single point diamond turning, SPDT) (reactive ion etching, RIE) [6] SPDT [7-1] SPDT [13-14] SPDT RIE [15-17] [18-1] 1 1(a) 1(b) 1(c) RIE 3 (a) (b) Single point diamond turning (c) Reactive ion etching Photoresist Glass substrate 1 Fig. 1 Fabrication method of aspheric microlens array based on turning mask 170671-

1) ) 3) (PMMA) PMMA PMMA PMMA PMMA PMMA AZ50XT 10% PMMA AZ50XT PMMA Ra Ra/nm 6 4 0 1:1 :1 3:1 4:1 5:1 6:1 7:1 PMMA: AZ50XT Fig. Surface roughness curves of masking materials with different parameters after etching 3 PMMA PMMA 75% 3:1 PMMA AZ50XT O 0 sccm SF 6 1 sccm 100 W 9:1 1/9 Ra/nm 15 10 5 0 4 1:1 :1 3:1 4:1 5:1 PMMA: AZ50XT 3 Fig. 3 Surface roughness curves of masking materials with different parameters after turning 0 mm 10 min 140 0 min 1 s 1500 r/min 0 70 60 min 17 μm SPDT Nanotech 350 FG 80 μm. μm ZYGO NewView 7100 4(a) 4(b) 4(c) 3D 170671-3

(a) (b) (c) 4 Fig. 4 Test results of aspheric microlens array (a) (b) (c) ME-3A O 0 sccm SF 6 1 sccm 100 W 5 5 5(a) 5(b) 5(c) 3D 4 5 80 μm. μm 0.43 μm 9:1 6 y (0, 1) y (0, ) y (0, 3) y (0, n) y (1, 1) y (1, ) y (1, 3) y (1,n) n 1100 RMS [( y y ) ( y y ) (1,1) (0,1) (1,) (0,) 1/ ( y(1, n) y(0, n) ) ] (1) (y (1, m) y (0, m) )(1 m n) 6 RMS=1.155 nm 0.47% 6 5 Fig. 5 Test results of quartz glass elements 170671-4 ±0 nm ±40 nm [] Height/nm 0-100 -00-300 Y 6 Position/mm 0.1 0. 0.3 0.4 0.5 0.6 [1] Yang G S, Chen T, Chen H. Crack-free silica glass surface X After processing Design Error 6 Fig. 6 Comparison of the expected cross section of micromirror and the cross section of the micromirror after processing

micro-grooves etched by 48 nm excimer lasers[j]. Chinese Journal of Lasers, 017, 44(9): 090004.,,. 48 nm [J]., 017, 44(9): 090004. [] Zhang J, Sugioka K, Takahashi T, et al. Dual-beam ablation of fused silica by multiwavelength excitation process using KrF excimer and F lasers[j]. Applied Physics A, 000, 71(1): 3 6. [3] Cui Z. Micro-nanofabrication Technologies and Applications[M]. 3rd ed. Beijing: Higher Education Press, 013: 4 3.. [M]. 3. :, 013: 4 3. [4] Zhang J, Dai L, Wang F, et al. Restraint of mid-spatial-frequency error aspheric surface by small-tool adaptive polishing[j]. Acta Optica Sinica, 013, 33(8): 0800.,,,. [J]., 013, 33(8): 0800. [5] Ridge M T, Cox D C, Webb R P, et al. The fabrication of aspherical microlenses using focused ion-beam techniques[j]. Micron, 014, 57: 56 66. [6] Yuan W, Chan C Y, Li L H, et al. Investigation of the surface profile along the cutting trajectory and its correlation with cutting forces in single point diamond turning[j]. The International Journal of Advanced Manufacturing Technology, 017, 89(5 8): 137 1338. [7] Wang Y, Yu J C. Compensation for error of diamond tool s cutting edge in single diamond turning[j]. Opto-Electronic Engineering, 011, 38(1): 98 10.,. [J]., 011, 38(1): 98 10. [8] Gong L B, Cheung C F. Modeling and characterization of surface generation in fast tool servo machining of microlens arrays[j]. Computers & Industrial Engineering, 01, 63(4): 957 970. [9] Dunkel J, Wippermann F, Brückner A, et al. Fabrication of refractive freeform array masters for artificial compound eye cameras[j]. Proceedings of SPIE, 014, 9130: 91300P. [10] Mukaida M, Yan J W. Ductile machining of single-crystal silicon for microlens arrays by ultraprecision diamond turning using a slow tool servo[j]. International Journal of Machine Tools and Manufacture, 017, 115: 14. [11] Chen Y L, Cai Y D, Tohyama K, et al. Auto-tracking single point diamond cutting on non-planar brittle material substrates by a high-rigidity force controlled fast tool servo[j]. Precision Engineering, 017, 49: 53 61. [1] Yan F, Fan D, Zhang B Z, et al. Manufacturing and testing of a SiC unrotational-symmetric aspherical optics[j]. Opto-Electronic Engineering, 009, 36(3): 135 139.,,,. SiC [J]., 009, 36(3): 135 139. [13] Zhu H F, Jia C P, Fang Z L. Design method and optical performance of aspherical IOL[J]. Opto-Electronic Engineering, 009, 36(4): 56 59.,,. [J]., 009, 36(4): 56 59. [14] En D, Xu K X, Chen C H, et al. Development of integrated optical aplanatic double-convex aspherical waveguide lens[j]. Opto-Electronic Engineering, 008, 35(10): 98 101, 115.,,,. [J]., 008, 35(10): 98 101, 115. [15] Zhang S F, Liu Z T, Li Y P, et al. Preparation and characterization of nanoimprint template on quartz by reactive ion etching[j]. Mechanical Science and Technology for Aerospace Engineering, 01, 31(11): 1786 1789.,,,. [J]., 01, 31(11): 1786 1789. [16] Chiromawa N L, Ibrahim K. Fabrication of micro-array of Fresnel rings on Si by electron beam lithography and reactive ion etching[j]. Applied Physics A, 016, 1(): 19. [17] Xie Y P, Wu P, Yang Z, et al. Continuous microstructure etching process polyimide based moving mask exposure[j]. Acta Photonica Sinica, 015, 44(9): 09004.,,,. [J]., 015, 44(9): 09004. [18] Yu E, Kim S C, Lee H J, et al. Extreme wettability of nanostructured glass fabricated by non-lithographic, anisotropic etching[j]. Scientific Reports, 015, 5: 936. [19] Mahoney S A, Rufford T E, Rudolph V, et al. Creation of microchannels in Bowen Basin coals using UV laser and reactive ion etching[j]. International Journal of Coal Geology, 015, 144 145: 48 57. [0] Lu Z Y, Hu G H, Yun B F, et al. RIE technological study of polymer optical waveguide[j]. Microfabrication Technology, 008(3): 5 9.,,,. [J]., 008(3): 5 9. [1] Zhang C C, Yang C S, Ding G F, et al. Deep reactive ion etching of polymethylmethacrylate[j]. Vacuum Science and Technology, 004, 4(): 157 160.,,,. PMMA [J]., 004, 4(): 157 60. [] Shi L F, Du C L, Dong X C, et al. Effective formation method for an aspherical microlens array based on an aperiodic moving mask during exposure[j]. Applied Optics, 007, 46(34): 8346 8350. 170671-5

Fabrication method of quartz aspheric microlens array for turning mask 1 School of Opto-Engineering, Changchun University of Science and Technology, Changchun, Jilin 1300, China; Micro-Nano Manufacturing and System Integration Center, Chongqing Institute of Green and Intelligent Technology, Chinese Academy of Sciences, Chongqing 400714, China (a) (b) Single point diamond turning (c) Reactive ion etching Photoresist Glass substrate Fabrication method of aspheric microlens array based on turning mask Overview: In the existing mature processing methods, the processing of micro optical structure can be divided into two major categories: microstructural lithography and single point diamond turning. Microstructural lithography can be used to process inorganic materials, such as quartz, silicon and so on. However, microstructural lithography has not been able to solve the problem of micro and nano structure shape control. The single point diamond turning technology can achieve precise control of the surface shape, but it is difficult to process the inorganic and brittle materials. In order to solve the two difficult problems of quartz aspheric microlens array processing, such as poor controllability and low surface accuracy, a method of making quartz glass based on turning mask and etching is proposed. The single point diamond turning technology and micro photomask technology is innovatively combined. The mask layer pattern is made by single point diamond turning, and then the mask pattern is transferred by reactive ion etching. Finally the fabrication of quartz glass aspheric microlens array element is completed. We mainly make the selection of the mask material and study the etching performance and turning performance of PMMA and AZ50XT photoresist. We find that the addition of AZ50XT photoresist in PMMA can effectively improve the anti etching performance, not only meet the requirements of single point diamond turning, and after reactive ion etching after the mask pattern can be maintained by the original still. By analyzing the surface roughness of mask after single point diamond turning and the surface roughness of mask after reactive ion etching, we get the most suitable mask material for this processing method. Finally, the new material is used to make the mask. The pattern is made on the mask surface by single point diamond turning, and the mask pattern is transferred to the quartz substrate by reactive ion etching technology. The aspheric microlens array with area of 5 mm 5 mm is obtained. The experimental results are compared with the expected parameters. The analysis shows that the root mean square error of the quartz glass element manufactured by this method is 1.155 nm and the accuracy of face shape error is 0.47%. The experimental results show that this method possesses not only the advantages of single point diamond turning technology, such as high surface accuracy, high processing stability and mature technology, but good anisotropy of reactive ion etching technology. This method has great potential for development, and it also provides a strong support for the wider application of quartz glass materials. Citation: Wang H, Dong L H, Zhu G D, et al. Fabrication method of quartz aspheric microlens array for turning mask[j]. Opto-Electronic Engineering, 018, 45(4): 170671 * E-mail: custdong@16.com; zwg@cigit.ac.cn 170671-6

2024 © hobbydocbox.com Privacy Policy | Terms of Service | Feedback