Laser & Optoelectronics Progress, Volume. 55, Issue 1, 11410(2018)
3D Femtosecond Laser Nanoprinting
Figures & Tables(9)
![Basics of two-photon photopolymerization (TPP)[48]. (a) Schematic of TPP fabrication; (b) achievement of sub-diffraction-limit (SDL) fabrication accuracy [the absorption probabilities of single photo absorption (SPA) and TPA are denoted by dashed and solid lines, respectively; the inset is a diffraction pattern]](/Images/icon/loading.gif){kind=icon}
Fig. 1. Basics of two-photon photopolymerization (TPP)[48]. (a) Schematic of TPP fabrication; (b) achievement of sub-diffraction-limit (SDL) fabrication accuracy [the absorption probabilities of single photo absorption (SPA) and TPA are denoted by dashed and solid lines, respectively; the inset is a diffraction pattern]
Fig. 4. Schematics and SEM images of microlens arrays with different curvature units (MLADC) fabricated via 3D FsLNP. (a) Schematic of perspective view; (b) schematic of cross-section view as well as the focal plane; (c) SEM image shot from top; (d) SEM image shot from side[67]
Fig. 5. Top-view SEM micrographs of the microlasers with different shapes fabricated via 3D FsLNP on the narrow band filter substrate[68]. (a) Circular disk; (b) circular ring; (c) spiral ring; (d) spiral ring stacked on circular ring; (e) spiral ring stacked on circular disk
Fig. 6. 3D FsLNP using diversiform silk-based aqueous inks[49]. (a) Image of silk fibroin extracted from Bombyx mori silkworm cocoons in the inset; (b) image of renewable silk fibroin (RSF) aqueous mother solution (mass fraction of 3%); (c) diversiform silk-based aqueous inks [(I) RSF/MB aqueous solution, (II) RSF/Ag nanoseed aqueous solution, (III) RSF/AgNO3 aqueous solution, (IV) RSF/HAuCl4 aqueous solution]; (d) schematic
Fig. 7. Protein-based multi-mode interference (MMI) optical micro-splitters via 3D FsLNP[88]. (a) Schematic of 3D FsLNP of protein-based MMI micro-splitters; (b) optical microscopic image of protein-based MMI micro-splitters prepared on MgF2 substrate, the scale bar is 10 μm
Fig. 8. Natural compound eye and high quality artificial compound eye via 3D FsLNP combined with the high-speed voxel-modulation laser scanning method[89]. (a) Top-view and(b) magnified SEM images of a natural compound eye showing a macrobase and hundreds of 100% filled hexagonal micro-ommatidia; (c) top-view and (d) 30°-tilted magnified SEM images of the bio-inspired artificial compound eye, the 100% fill factor of hexagonal ommatidia is comparable to t
Table 1. Comparison between 3D FsLNP and 3D laser printing
View tableTable 1. Comparison between 3D FsLNP and 3D laser printing
Technique Material Precision Scale Mechanism 3D FsLNP Polymers, metal, metal oxide, silk fibroin, etc. ~10 nm μm Two-photon photopolymerization SLM[ 50 -53 ]Plastic fine powder, ceramic powder >10 μm cm Selective powder sintering LENS[ 54 -55 ]Metal powder >10 μm mm Selective laser sintering & laser cladding
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Liu Monan, Li Mutian, Sun Hongbo. 3D Femtosecond Laser Nanoprinting[J]. Laser & Optoelectronics Progress, 2018, 55(1): 11410
Paper Information
Category: Lasers and Laser Optics
Received: Aug. 9, 2017
Accepted: --
Published Online: Sep. 10, 2018
The Author Email: Sun Hongbo (hbsun@jlu.edu.cn)
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