Microlens array machining method based on projection lithography

Jianwen Gong; Jian Wang; Junbo Liu; Haifeng Sun; Song Hu

doi:10.12086/oee.2023.230281

Opto-Electronic Engineering, Volume. 50, Issue 12, 230281-1(2023)

Microlens array machining method based on projection lithography

Jianwen Gong1...2,3, Jian Wang1,3, Junbo Liu1,3, Haifeng Sun1,3, and Song Hu13,* |Show fewer author(s)

Author Affiliations

¹Institute of Optics and Electronics, Chinese Academy of Science, Chengdu, Sichuan 610209, China

²School of Optoelectronic Science and Engineering, University of Electronic Science and Technology of China, Chengdu, Sichuan 611731, China

³University of Chinese Academy of Sciences, Beijing 100049, China

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References(30)

[1] X C Dong, C L Du, C T Wang et al. Mask-shift filtering for forming microstructures with irregular profile. Appl Phys Lett, 89, 261105(2006).

[2] X C Dong, C L Du, S H Li et al. Control approach for form accuracy of microlenses with continuous relief. Opt Express, 13, 1353-1360(2005).

[3] W G Zhang, G D Zhu, X Q Zhu et al. Ultra-precision replication technology for fabricating spiral-structure metamaterial. Front Phys, 8, 267(2020).

[4] W G Zhang, L P Xia, M Y Gao et al. Laser beam homogenization with randomly distributed freeform cylindrical microlens. Opt Eng, 59, 065103(2020).

[5] S Y Zhang, L X Zhao, Y He. Lithography alignment method based on image rotation matching. J Phys Conf Ser, 1939, 012039(2021).

[6] Q H Yang, D P Chen, T C Ye et al. Development of mask for scattering with angular limitation projection electron-beam lithography. Opto-Electron Eng, 31, 13-16(2004).

[7] Y H Wang, J Y He, C T Wang et al. Method investigation of direct-writing nanolithography based on enhanced local surface Plasmon resonance. Opto-Electron Eng, 43, 71-76(2016).

[8] M Ekberg, F Nikolajeff, M Larsson et al. Proximity-compensated blazed transmission grating manufacture with direct-writing, electron-beam lithography. Appl Opt, 33, 103-107(1994).

[9] L P Lee, S A Berger, D Liepmann et al. High aspect ratio polymer microstructures and cantilevers for bioMEMS using low energy ion beam and photolithography. Sens Actuators A Phys, 71, 144-149(1998).

[10] Y Gonin, F Munnik, F Benninger et al. Creating sub-surface channels in PMMA with ion beam lithography in only one step. Appl Surf Sci, 217, 289-293(2003).

[11] S H Yang, C L Ding, D Z Zhu et al. High-speed two-photon lithography based on femtosecond laser. Opto-Electron Eng, 50, 220133(2023).

[12] H Q Wang, J S Wen, Z Y Yang et al. High-speed parallel two-photon laser direct writing lithography system. Chin J Lasers, 49, 2202009(2022).

[13] C H Lee, H Yoshida, Y Miura et al. Local liquid crystal alignment on patterned micrograting structures photofabricated by two photon excitation direct laser writing. Appl Phys Lett, 93, 173509(2008).

[14] X Q Liu, Q D Chen, K M Guan et al. Dry-etching-assisted femtosecond laser machining. Laser Photonics Rev, 11, 1600115(2017).

[15] X Q Liu, L Yu, S N Yang et al. Optical nanofabrication of concave microlens arrays. Laser Photonics Rev, 13, 1800272(2019).

[16] J H Liu, J B Liu, Q Y Deng et al. Intensity modulation based optical proximity optimization for the maskless lithography. Opt Express, 28, 548-557(2020).

[17] I Artyukov, L Balakireva, F Bijkerk et al. Projection x-ray lithography implemented using point sources. Sov J Quantum Electron, 22, 99-110(1992).

[18] J Du, J B Liu, H Y Quan et al. Displacement measurement analysis in distortion detection of lithography projection objective. Opto-Electron Eng, 50, 220226(2023).

[19] B Li, Y Che, H Xu et al. Lithography technical science knowledge map and multidimensional theme analysis. Laser Optoelectron Prog, 60, 2300004(2023).

[20] A Vlad, I Huynen, S Melinte. Wavelength-scale lens microscopy via thermal reshaping of colloidal particles. Nanotechnology, 23, 285708(2012).

[21] W B Veldkamp. Binary optics: a new approach to optical design and fabrication. Opt News, 14, 29-30(1988).

[22] C Y Chang, S Y Yang, L S Huang et al. Fabrication of plastic microlens array using gas-assisted micro-hot-embossing with a silicon mold. Infrared Phys Technol, 48, 163-173(2006).

[23] X C Dong, C L Du, L Pan et al. A new method for control relief depth of micro-lens array. Opto-Electron Eng, 30, 1-3(2003).

[24] W G Zhang, X C Dong, C L Du. Zooming method for microlens array imaging photolithography. Opto-Electron Eng, 37, 39-43(2010).

[25] C L Du, X C Dong, Q L Deng et al. Micro-optical structures formed by a mask moving method. Optoelectron Lett, 3, 95-98(2007).

[26] A X Cao, J Z Wang, H Pang et al. Design and fabrication of a multifocal bionic compound eye for imaging. Bioinspir Biomim, 13, 026012(2018).

[27] B Im, F D Prasetyo, H T Yudistira et al. Drop-on-demand electrohydrodynamic jet printing of microlens array on flexible substrates. ACS Appl Polym Mater, 5, 2264-2271(2023).

[28] R Zhao, C Peng, K Zhang et al. Design and simulation of bionic compound eye with electrowetting liquid lens. Opto-Electron Eng, 48, 49-56(2021).

[29] L F Shi, C L Du, X C Dong et al. Effective formation method for an aspherical microlens array based on an aperiodic moving mask during exposure. Appl Opt, 46, 8346-8350(2007).

[30] L F Shi, A X Cao, Y Liu et al. Design and experiments of artificial compound eye with large view field. Opto-Electron Eng, 40, 27-33(2013).

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Jianwen Gong, Jian Wang, Junbo Liu, Haifeng Sun, Song Hu. Microlens array machining method based on projection lithography[J]. Opto-Electronic Engineering, 2023, 50(12): 230281-1

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Paper Information

Category: Article

Received: Nov. 20, 2023

Accepted: Dec. 20, 2023

Published Online: Mar. 26, 2024

The Author Email: Hu Song (胡松)

DOI:10.12086/oee.2023.230281

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology

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