New Laser-Scan Exposure System for Delineating Precise Helical Patterns onto Sub-50-µm Wires

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Stent-like complicated cylindrical structures were made with pipes of stainless-steel SUS 304 using new lithography and wet chemical etching. In the new lithography, patterns on a flat reticle were printed on a pipe coated with a resist film by synchronously scanning the reticle linearly and rotating the pipe around the axis, and limiting the momentary exposure area on the top ridge of the pipe by placing an oblong slit on the reticle in parallel to the pipe axis. The patterned pipe was wetly etched in an aqueous solution of ferric chloride using the resist patterns as etching masks. Because the etching was progressed equally in all the directions from the resist pattern edges, masked parts under the resist patterns were also gradually etched from the pattern edges and undercut during the pipe was penetrated through the wall. Caused by the undercut, obtained mesh widths became narrower than the resist pattern widths. However, a stent-like mesh structure with widths of 108±12.4 (3σ) µm was decently fabricated by appropriately controlling the resist pattern width and the etching time. To attain higher accuracy in the future, cross section profiles of the mesh and relationship between resist pattern widths and mesh widths were discussed in detail.

Section: Resist Patterning Using Synchronized Scan Rotation Lithographymentioning

confidence: 99%

Fabrication of Stent-Like Mesh Structures Using Synchronized Scan Rotation Lithography and Wet Etching

Horiuchi

Ito

Suzuki

et al. 2020

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“…Delineation of multi-slit patterns using laser-scan lithography was investigated using the latter exposure system developed in the past research [18]. The exposure wavelength was 408 nm.…”

Section: Delineation Of Slit Patterns Using Laser-scan Lithographymentioning

confidence: 99%

“…In our laboratory, two laser-scan exposure systems were developed for delineating patterns on wires and pipes placed horizontally and vertically, respectively [1,18]. Using the former exposure system, in which the specimens were set horizontally, nickel coil springs were fabricated by forming helical resist patterns on a stainless-steel wire with diameters of 80-100 µm using the laser-scan lithography, and electroplating nickel between the resist patterns [1].…”

Section: Introductionmentioning

confidence: 99%

Laser-Scan Lithography and Electrolytic Etching for Fabricating Meshed Pipes of Stainless Steel

Takahashi

Horiuchi²

2018

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Numerous micro-slits were opened penetrating through fine stainless steel pipes using laser-scan lithography and electrolytic etching, and meshed pipes were fabricated. Such micro-fabrication technology will be useful for developing bio-medical micro-stents, syringe needles, mesh filters, and others. As original materials, stainless-steel pipes with an outer diameter of 100 μm, a thickness of 20 μm and a length of 40 mm were used. At first, each pipe coated with a positive resist was exposed to a beam spot of violet laser, and multi-slit patterns were delineated by scanning and intermittently moving the pipe in the axial and rotational directions. After the development, each pipe masked by the resist film except the slit pattern parts were etched individually. Electrolytic etching was applied by using an aqueous solution of NaNO3 and NH 4 Cl as an electrolyte. As a result, mesh structures composed of four linearly arrayed 22 slits arranged at every 90° circumferential angle were fabricated.

“…To answer the requirement, various researches on developing lithography systems for replicating or delineating patterns on cylindrical materials were carried out [1][2][3][4][5][6][7]. The authors also developed laser-scan exposure systems onto fine wires and pipes with diameters of 40-500 µm [8][9][10][11][12][13]. It was demonstrated that very precise patterns were arbitrarily delineated on surfaces of such very fine cylindrical materials.…”

Section: Introductionmentioning

confidence: 99%

Lithography onto Surfaces of Fine-Diameter Pipes Using Rotary Scan-Projection Exposure

Horiuchi

Fujii

Yasunaga

2015

Self Cite

A new rotary scan-projection exposure system was developed for replicating patterns with widths of around 100 μm. As the first step, a reticle was fixed steady on the reticle stage, and only specimen pipes were rotated. As a result, 100-μm line-and-space (L&S) patterns were successfully replicated on whole circumferences. Deviation 3 σ of the resist pattern widths was as small as 5 μm for the mean width of 100 μm. Next, a reticle with oblique L&S patterns was also scanned synchronously with the rotation of the specimen pipe. However, stitching of patterns doubly exposed at the start and stop parts of rotary exposure was difficult. Although large patterns with widths of 400 μm were successfully replicated on whole surface, 100-μm L&S patterns were replicated only on partial areas of the pipe surface. It was clarified that yaw alignment of the reticle, and alignment between the centers of chucked pipe and the rotation stage should be improved. By working on these subjects, the new system will be graded up further more.