Fabrication of a metallic roll stamp with low internal stress and high hardness for large area display applications by a pulse reverse current electroforming process

Kim, Joongeok; Han, Jaejoon; Kim, Tae‐Kyung; Kang, Shinill

doi:10.1088/0960-1317/24/12/125004

Cited by 7 publications

(6 citation statements)

References 24 publications

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“…The hardness of Ni shim formed at a lower current is 257 ± 10 HV5, which is much higher compared to that formed at a high current (160 ± 7 HV5). This observation is consistent with reports on the effect of current on microstructure and hardness [30,33,34]. Overall, the Ni insert is composed of features and a bottom supporting layer.…”

Section: Ni Tool Insertsupporting

confidence: 92%

“…Although a lower current density eliminates or reduces the size of voids, electroforming time increases significantly. Pulse reverse current electroplating has been successfully used to eliminate voids in high aspect ratio (~4.5) submicron features by dissolving the deposited metal material according to the anodic reaction [30][31][32]. The effect of current on the microstructure of a feature is shown in Figure 13.…”

Section: Ni Tool Insertmentioning

confidence: 99%

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Manufacturing microstructured tool inserts for the production of polymeric microfluidic devices

Zhang

Srivastava

Kirwan

et al. 2015

J. Micromech. Microeng.

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Abstract:Tooling is critical in defining multi-scale patterns for mass production of polymeric microfluidic devices using the microinjection molding process. In the present work, fabrication of various microstructured tool inserts using stainless steel, nickel and Bulk Metallic Glasses (BMGs) is discussed based on die-sinking EDM (electrical discharge machining), electroforming, Focused Ion Beam milling and thermoplastic processes. Tool performance is evaluated in terms of surface roughness, hardness and tool life. Compared to stainless steel, nickel and BMGs are capable of integrating length scales from 10 0 to 10 -8 m and are good candidates for producing polymeric microfluidics. Selection of tool materials and manufacturing technologies should consider the end-user requirements of actual applications.

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Section: Ni Tool Insertsupporting

confidence: 92%

Section: Ni Tool Insertmentioning

confidence: 99%

Manufacturing microstructured tool inserts for the production of polymeric microfluidic devices

Zhang

Srivastava

Kirwan

et al. 2015

J. Micromech. Microeng.

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“…To improve the mechanical performance further, changing the stamp material is another possibility, , but Sylgard 184 has key advantages for the current work. First, this silicone is readily available at low cost to facilitate economical stamp fabrication as new circuits and features are under development.…”

Section: Resultsmentioning

confidence: 99%

“…A key advance is the development of a roll-to-roll UV-imprinting process with custom-made, rapidly produced, and easily exchanged prototype imprinting stamps. Most methods for fabricating stamps for roll-to-roll UV imprinting require complex or high-cost processing or are not capable of molding structures that are much higher than they are wide (high aspect ratio). ,, In the process described here, stamps are fabricated from a silicon wafer master pattern using liquid casting of low-cost silicone. A series of stamps is then bound to a poly(ethylene terephthalate) (PET) film to form a stamp assembly.…”

Section: Introductionmentioning

confidence: 99%

High-Resolution, High-Aspect-Ratio Printed and Plated Metal Conductors Utilizing Roll-to-Roll Microscale UV Imprinting with Prototype Imprinting Stamps

Jochem

Suszynski

Frisbie

et al. 2018

Ind. Eng. Chem. Res.

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Micron-scale, high-aspect-ratio features were imprinted by a roll-to-roll process into a UV-curable polymer and used to create high-current-carrying conductive networks on plastic substrates. A stamp fabrication method was developed to create low-cost, rapidly produced roll-to-roll imprinting stamps, which can mold features from 3 μm to 1 mm wide. Isolated raised features 50 μm high were molded from a 25-μm-thick layer of UV-curable resin by displacing resin into raised features in the stamp. Substrates with imprinted capillary channels were used to form electrical conductors by printing a silver ink into reservoirs connected to the channels and allowing capillary flow to coat the channel. Copper electroless plating then filled the channels. The conductors demonstrate high resolution, high aspect ratio (∼5:1 height:width), low resistance per length, and easy integration into networks. This roll-to-roll imprinting process provides a foundation for high-throughput manufacturing of high-resolution printed electronics.

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“…It was also possible to obtain cracked layers of superior quality via PRC, as shown in figure 19(B). Kim et al [124] compared the internal stress of the electroformed stamp by DC and PRC at various pulse frequencies. The internal stress of the stamp was effectively reduced by PRC electroforming compared to DC electroforming, as shown in figure 20, especially when the process used a high current density and low pulse frequency.…”

Section: Pulse Reverse Electroformingmentioning

confidence: 99%

Advances in precision micro/nano-electroforming: a state-of-the-art review

Zhang

Gilchrist

2020

J. Micromech. Microeng.

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Micro/nano-electroforming has received considerable interest from various industry sectors as an advanced micro-manufacturing technique that offers high dimensional precision and replication accuracy. When tight feature tolerances and miniaturized geometries are required, electroforming provides unique advantages and cost-effective characteristics for fabrication. This paper firstly reviews the historical development of micro-electroforming, particularly within the past two decades. The fundamentals of electroforming and relevant applications are firstly discussed, and the common requirements are then proposed. Based on these requirements, we have focused on the processes of micro-electroforming from the ultraviolet lithography, electroplating, and moulding process to electroforming process characterization and optimization, bath compositions, agitation, and some hybrid processes. Progress from electrochemical micro/nano-manufacturing processes, such as 3D printing by electrodeposition and electrochemical wet stamping, is also included. The eventual nanocomposite electroforming is highlighted from the perspectives of the formation mechanism, deposition properties and relevant applications. Finally, a conclusion and future perspectives are presented. This review will demonstrate how the micro/nano-electroforming process can be further developed to meet the requirements of new product development from precision optics, micro/nano-moulding, high-performance coatings and future micro/nano-manufacturing.

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Fabrication of a metallic roll stamp with low internal stress and high hardness for large area display applications by a pulse reverse current electroforming process

Cited by 7 publications

References 24 publications

Manufacturing microstructured tool inserts for the production of polymeric microfluidic devices

Manufacturing microstructured tool inserts for the production of polymeric microfluidic devices

High-Resolution, High-Aspect-Ratio Printed and Plated Metal Conductors Utilizing Roll-to-Roll Microscale UV Imprinting with Prototype Imprinting Stamps

Advances in precision micro/nano-electroforming: a state-of-the-art review

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