Novel Fabrication Method of Microcoil Springs Using Laser-Scan Helical Patterning and Nickel Electroplating

Horiuchi, Toshiyuki; Ishii, Hidetoki; Shinozaki, Yasuhide; Ogawa, Tetsuya; Kojima, Kesao

doi:10.1143/jjap.50.06gm10

Cited by 17 publications

(11 citation statements)

References 18 publications

(18 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Recently, various micro-components with three-dimensional (3D) cylindrical shapes are required. They are used as contact-probe springs in testing systems of semiconductor integrated circuits [1], syringe needles with surface textures for detecting their positions when they are stuck into bodies [2], medical stents [3][4][5], surgery tools [6], micro-needles [7] and others [8][9][10][11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

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

Takahashi

Horiuchi²

2018

J. Photopol. Sci. Technol.

Self Cite

View full text Add to dashboard Cite

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.

show abstract

Section: Introductionmentioning

confidence: 99%

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

Takahashi

Horiuchi²

2018

J. Photopol. Sci. Technol.

Self Cite

View full text Add to dashboard Cite

show abstract

“…3D helical mesostructures hold great potential for a broad range of applications in microsystem technologies, such as microelectromechanical systems (MEMS), electrodes for lab‐on‐a‐chip systems, and stretchable electronics . To form 3D architectures of helical and other relevant topologies at the micro/nanoscale, several classes of fabrication/assembly approaches have been developed by exploiting different working mechanisms . Representative approaches include microcontact printing, MEMS lithography/electroplating techniques, manual winding, residual‐stress‐induced self‐rolling of thin films/belts, controlled mechanical buckling, and 3D additive printing based on direct ink deposition, or direct laser writing (sometimes in combination with liquid metal paste filling or the electrochemical deposition and plasma etching) .…”

Section: Introductionmentioning

confidence: 99%

“…To form 3D architectures of helical and other relevant topologies at the micro/nanoscale, several classes of fabrication/assembly approaches have been developed by exploiting different working mechanisms . Representative approaches include microcontact printing, MEMS lithography/electroplating techniques, manual winding, residual‐stress‐induced self‐rolling of thin films/belts, controlled mechanical buckling, and 3D additive printing based on direct ink deposition, or direct laser writing (sometimes in combination with liquid metal paste filling or the electrochemical deposition and plasma etching) . Most of these approaches, such as lithography/electroplating techniques, manual winding, and 3D additive printing, apply directly only to certain classes of materials, e.g., metals and/or polymers, and generally not to high‐performance semiconductors (e.g., single‐crystal silicon) or other advanced materials that are widely adopted in modern high‐quality electronics and optoelectronics.…”

Section: Introductionmentioning

confidence: 99%

“…Representative approaches include microcontact printing, MEMS lithography/electroplating techniques, manual winding, residual‐stress‐induced self‐rolling of thin films/belts, controlled mechanical buckling, and 3D additive printing based on direct ink deposition, or direct laser writing (sometimes in combination with liquid metal paste filling or the electrochemical deposition and plasma etching) . Most of these approaches, such as lithography/electroplating techniques, manual winding, and 3D additive printing, apply directly only to certain classes of materials, e.g., metals and/or polymers, and generally not to high‐performance semiconductors (e.g., single‐crystal silicon) or other advanced materials that are widely adopted in modern high‐quality electronics and optoelectronics. Although the methods based on residual‐stress‐induced self‐rolling are naturally compatible with modern planar technologies and offer yields and throughputs necessary for practical applications, they provide direct access only to certain classes of hollow polyhedral or cylindrical geometries, with the upper length scales limited, to a certain extent, by the achievable levels of residual stresses.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Guided Formation of 3D Helical Mesostructures by Mechanical Buckling: Analytical Modeling and Experimental Validation

Liu

Yan

Lin

et al. 2016

Adv Funct Materials

View full text Add to dashboard Cite

Three-dimensional (3D) helical mesostructures are attractive for applications in a broad range of microsystem technologies, due to their mechanical and electromagnetic properties as stretchable interconnects, radio frequency antennas and others. Controlled compressive buckling of 2D serpentine-shaped ribbons provides a strategy to formation of such structures in wide ranging classes of materials (from soft polymers to brittle inorganic semiconductors) and length scales (from nanometer to centimeter), with an ability for automated, parallel assembly over large areas. The underlying relations between the helical configurations and fabrication parameters require a relevant theory as the basis of design for practical applications. Here, we present an analytic model of compressive buckling in serpentine microstructures, based on the minimization of total strain energy that results from various forms of spatially dependent deformations. Experiments at micro- and millimeter-scales, together with finite element analyses (FEA), were exploited to examine the validity of developed model. The theoretical analyses shed light on general scaling laws in terms of three groups of fabrication parameters (related to loading, material and 2D geometry), including a negligible effect of material parameters and a square root dependence of primary displacements on the compressive strain. Furthermore, analytic solutions were obtained for the key physical quantities (e.g., displacement, curvature and maximum strain). A demonstrative example illustrates how to leverage the analytic solutions in choosing the various design parameters, such that brittle fracture or plastic yield can be avoided in the assembly process.

show abstract

“…With such technologies, space between resist patterns is filled by metal through plating or sputtering. The authors formed helical patterns on stainless steel (SUS 304) wire, plated nickel in the spacing, and then removed the stainless wire core to produce a nickel microcoil . However, it takes a long time to obtain a thick film by plating or sputtering, and it is difficult to ensure thickness uniformity and reproducibility.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of Stainless‐Steel Microcoils and Mesh Pipes Using Lithography

Sakabe

Horiuchi

2014

Elect Comm in Japan

Self Cite

View full text Add to dashboard Cite

SUMMARY Precise microcoils and mesh pipes with outer and inner diameters of 100 μm and 60 μm were fabricated using laser‐scan lithography and electrolytic etching. Non‐magnetizable stainless‐steel (SUS304) pipes were coated with resist films, and helical patterns were delineated using a laser‐scan exposure system. Positive resist PMER P‐LA900 was used for fabricating microcoils, and negative resist PMER N‐CA3000 was used for fabricating micromesh pipes. Mesh patterns were formed by doubly delineating helical patterns coiled in opposite directions each other. Widths of resist patterns used for fabricating mesh patterns were also controlled by stitching two helical patterns. Because space widths of coils and sizes of mesh holes became larger than space widths and hole sizes of resist patterns caused by undercut in etching process, widths of resist patterns were adjusted by considering the undercut depths. As a result, pipe specimens were suitably etched in a solution of sodium chloride and ammonium chloride in water, and microcomponents with homogeneous widths were successfully fabricated.

show abstract

Novel Fabrication Method of Microcoil Springs Using Laser-Scan Helical Patterning and Nickel Electroplating

Cited by 17 publications

References 18 publications

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

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

Guided Formation of 3D Helical Mesostructures by Mechanical Buckling: Analytical Modeling and Experimental Validation

Fabrication of Stainless‐Steel Microcoils and Mesh Pipes Using Lithography

Contact Info

Product

Resources

About