Xiaoying Rong scite author profile

Pattern printing techniques have advanced rapidly in the past decade, driven by their potential applications in printed electronics. Several printing techniques have realized printed features of 10 μm or smaller, but unfortunately, they suffer from disadvantages that prevent their deployment in real applications; in particular, process throughput is a significant concern. Direct gravure printing is promising in this regard. Gravure printing delivers high throughput and has a proven history of being manufacturing worthy. Unfortunately, it suffers from scalability challenges because of limitations in roll manufacturing and limited understanding of the relevant printing mechanisms. Gravure printing involves interactions between the ink, the patterned cylinder master, the doctor blade that wipes excess ink, and the substrate to which the pattern is transferred. As gravure-printed features are scaled, the associated complexities are increased, and a detailed study of the various processes involved is lacking. In this work, we report on various gravure-related fluidic mechanisms using a novel highly scaled inverse direct gravure printer. The printer allows the overall pattern formation process to be studied in detail by separating the entire printing process into three sequential steps: filling, wiping, and transferring. We found that pattern formation by highly scaled gravure printing is governed by the wettability of the ink to the printing plate, doctor blade, and substrate. These individual functions are linked by the apparent capillary number (Ca); the printed volume fraction (φ(p)) of a feature can be constructed by incorporating these basis functions. By relating Ca and φ(p), an optimized operating point can be specified, and the associated limiting phenomena can be identified. We used this relationship to find the optimized ink viscosity and printing speed to achieve printed polymer lines and line spacings as small as 2 μm at printing speeds as high as ∼1 m/s.

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Development of MnO2 cathode inks for flexographically printed rechargeable zinc-based battery

Wang

Winslow

Madan

et al. 2014

Journal of Power Sources

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A flexographic printing method for battery fabrication was presented. Key criteria for developing functional flexographic inks were established. A variety of MnO 2 composite cathode inks were developed and analyzed. A PSBR based ink showed excellent printability and electrochemical performance. a b s t r a c tA novel roll-to-roll flexographic printing process for rechargeable zinc-based battery manufacturing was presented in this paper. Based on the fundamental operating mechanism of flexography, key criteria for developing functional flexographic printing inks were established, including composite ink rheology (steady-state viscosity and yield stress), ink wettability as well as ink dispersing qualities. A variety of MnO 2 cathode inks were developed and analyzed comprehensively based on these criteria. A novel type of aqueous cathode ink based on PSBR polymeric binder showed excellent flexographic printability as well as promising electrochemical performance.

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Impact of metal electrode work function of CH 3 NH 3 PbI 3 /p-Si planar heterojunction perovskite solar cells

Rong

Tian

et al. 2017

Solar Energy

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An artifact-metrics which utilizes laser speckle patterns for plastic ID card surface

Yamakoshi

Rong

Matsumoto

2010

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Establishing Standards for Color and Print Quality in Large Format Inkjet Printing

Sharma¹,

Rong²

2014

jist

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Xiaoying Rong

Femtoliter-Scale Patterning by High-Speed, Highly Scaled Inverse Gravure Printing

Development of MnO2 cathode inks for flexographically printed rechargeable zinc-based battery

Impact of metal electrode work function of CH 3 NH 3 PbI 3 /p-Si planar heterojunction perovskite solar cells

An artifact-metrics which utilizes laser speckle patterns for plastic ID card surface

Establishing Standards for Color and Print Quality in Large Format Inkjet Printing

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