image: Fig.1. Schematic of the experimental system for the SSTF high-repetition-rate fs laser micromachining
Credit: OEA
A new publication from Opto-Electronic Advances, 10.29026/oea.2023.230066 discusses three-dimensional isotropic microfabrication in glass using spatiotemporal focusing of high-repetition-rate femtosecond laser pulses.
Simultaneous spatiotemporal focusing (SSTF) technique was originally developed for bio-imaging applications and has been applied in fs laser micromachining. The SSTF technique provides a new temporal focusing dimension, making it prominent in improving the axial fabrication resolution and eliminating the nonlinear self-focusing effect. The mechanism of the SSTF technique is that different frequency components of fs laser pulses are spatially dispersed by gratings and then recombined by an objective lens, pulse width at focal point of objective lens is restored to fs level.
Currently, most research on 3D micromachining of fs laser SSTF technique are based on Ti: sapphire chirped pulse amplification system with wide bandwidth and low repetition rate, which limits the speed of laser processing. Therefore, applying SSTF to high-repetition-rate fs laser sources is an inevitable requirement for achieving high efficiency and three-dimensional isotropic processing simultaneously. However, the bandwidth of high-repetition-rate fs laser source is usually narrow, the spatial dispersion introduces a large number of negative time chirps, the laser itself cannot provide enough time compensation, resulting in the pulse width at the focus cannot restore to fs level, limiting the application of SSTF technique in high-repetition-rate laser processing. Therefore, 3D isotropic microfabrication in transparent materials using SSTF high-repetition-rate fs laser pulses need additional time compensation.
The authors of this article propose a pulse compensation scheme by building a pulse stretcher outside a high-repetition-rate fs laser source for the generation of the SSTF fs laser pulses, which realize truly 3D isotropic microfabrication with a tunable resolution ranging from 8 µm to 22 µm in glass. In this work, a Martinez-type pulse stretcher was adopted to introduce a large number of positive temporal chirps, the output pulse width was stretched to the picosecond level, and then different frequency components of laser pulses were spatially dispersed by grating pair and then recombined by an objective lens, pulse width at the focus of objective lens was restored to fs level. The experimental system is shown in Fig. 1.
As we all know, femtosecond laser processing effect is related to writing direction, pulse energy and processing depth. To verify the 3D isotropic fabrication resolution using the SSTF scheme, authors demonstrated optical micrographs of the lines in glass at different depths along different directions and with different pulse energy (see in Fig. 2). The experimental results show that in the SSTF scheme, all the cross-sectional profiles in both XZ and YZ planes were symmetrical and round-shaped, 3D tunable isotropic fabrication resolution ranging from 8 μm to 22 μm in glass can be achieved by varying the pulse energy of the fs laser, and the fabrication resolution were insensitive to the depth of the focal position. The significance of this work is mainly to meet the high laser processing efficiency and continuously 3D adjustable isotropic fabrication resolution, which provides a new technical means for laser processing.
To demonstrate the unique capability of 3D isotropic fabrication in glass with the SSTF scheme, authors demonstrated 3D isotropic microfluidic structures inside the glass fabricated by SSTF fs laser direct writing and chemical etching (see in Fig. 3). Compared with conventional laser processing, SSTF high-repetition-rate fs laser pulse has the advantages of high efficiency, 3D adjustable isotropic fabrication resolution. The research results are expected to be applied to the fabrication of 3D microfluidic chip, photonic chip and laser 3D printing.
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The Center of Light Manipulations and Applications at Shandong Normal University (www.gctk.sdnu.edu.cn) was founded in May 2018. In the same year, the center was selected as Shandong Provincial Engineering and Technical Center. The research team is led by Professor Yangjian Cai, who is the winner of the National Science Foundation for Distinguished Young Scholars and the Fellow of Optica. The team focuses on the research of the light fields’ manipulation and their applications in the new generation of information technologies such as optical communication in complex environments, precision optical processing, lidar detection, optical imaging, and instrument research. Since 2018, the center has obtained more than 50 national projects, such as the National Natural Science Foundation of China and the National Key Research and Development Program of China. The term has published more than 200 papers in international journals, such as Physical Review Letters, Laser & Photonics Reviews, PhotoniX, Nano Letters, Opto-Electronic Advances, ACS Photonics, Physical Review series.
Ya Cheng is a Professor of East China Normal University and Shanghai Institute of Optics and Fine Mechanics, Chinese Academy of Science. He is also an Optica Fellow and a Fellow of Institute of Physics, UK. His work focuses on lithium niobate integrated photonics, femtosecond laser fabrication of microfluidics, and strong-field atomic and molecular physics. He is the chief scientist of the key R&D program of the ministry of science and technology of PRC and has won the national science fund for distinguished young scholars. He has been granted more than 30 Chinese invention patents and 7 American patents and published more than 200 SCI papers which has been cited more than 11000 times, with H-index 55 both from Web of Science. He has also published 5 books in English, and 1 book in Chinese. Additionally, he has given more than 100 invited talks (including plenary and keynote talks) at various international conferences. He is the fellow of the American Optical Society and Institute of Physics, UK.
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Opto-Electronic Advances (OEA) is a high-impact, open access, peer reviewed monthly SCI journal with an impact factor of 14.1 (Journal Citation Reports for IF2022). OEA is indexed in SCI, EI, DOAJ, Scopus, CA and ICI databases.
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Tan YX, Lv HT, Xu J, Zhang AD, Song YP et al. Three-dimensional isotropic microfabrication in glass using spatiotemporal focusing of high-repetition-rate femtosecond laser pulses. Opto-Electron Adv 6, 230066 (2023). doi: 10.29026/oea.2023.230066
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