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Cell Filling in Gravure Printing for Printed Electronics
Langmuir, 2014Highly scaled direct gravure is a promising printing technique for printed electronics due to its large throughput, high resolution, and simplicity. Gravure can print features in the single micron range at printing speeds of ∼1 m/s by using an optimized cell geometry and optimized printing conditions. The filling of the cells on the gravure cylinder is
Jialiang Cen +2 more
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Advanced Functional Materials, 2021
MXenes are interesting 2D materials that have been considered as attractive frontier materials for potential applications in the fields of energy and electronic devices due to their excellent optoelectronic properties including metallic conductivity and ...
X. Tang +12 more
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MXenes are interesting 2D materials that have been considered as attractive frontier materials for potential applications in the fields of energy and electronic devices due to their excellent optoelectronic properties including metallic conductivity and ...
X. Tang +12 more
semanticscholar +1 more source
IEEE Sensors Journal, 2022
Printed electronics (PEs), as a fast-growing advanced manufacturing technology in recent years, plays an essential role in development of wearable electronic sensors, flexible displays, human-machine interaction, and thin electronics owing to its low ...
Li-Ya Ma, N. Soin
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Printed electronics (PEs), as a fast-growing advanced manufacturing technology in recent years, plays an essential role in development of wearable electronic sensors, flexible displays, human-machine interaction, and thin electronics owing to its low ...
Li-Ya Ma, N. Soin
semanticscholar +1 more source
Biphasic Liquid Metal Composites for Sinter‐Free Printed Stretchable Electronics
Advanced Materials Interfaces, 2022This work introduces and presents a comprehensive study on a series of biphasic liquid metal (LM) composites that benefit from high conductivity, excellent stretchability, a low gauge‐factor, excellent adhesion to a wide range of substrates, for sinter ...
A. Hajalilou +5 more
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Introduction to nanomaterials for printed electronics
Nanoscale, 2023Guest Editors Cinzia Casiraghi, Oana D. Jurchescu, Shlomo Magdassi and Wenming Su introduce the themed collection on Nanomaterials for printed electronics.
Cinzia Casiraghi +3 more
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Laser Printing of Electronic Materials
2018International ...
Anne-Patricia Alloncle +3 more
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A New Frontier of Printed Electronics: Flexible Hybrid Electronics
Advances in Materials, 2019The performance and integration density of silicon integrated circuits (ICs) have progressed at an unprecedented pace in the past 60 years. While silicon ICs thrive at low‐power high‐performance computing, creating flexible and large‐area electronics ...
Yasser Khan +5 more
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Nanoparticle composites for printed electronics
Nanotechnology, 2014Printed Electronics is a rapidly developing sector in the electronics industry, in which nanostructured materials are playing an increasingly important role. In particular, inks containing dispersions of semiconducting nanoparticles, can form nanocomposite materials with unique electronic properties when cured.
C. van den Berg +7 more
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Oh, Snap! A Fabrication Pipeline to Magnetically Connect Conventional and 3D-Printed Electronics
International Conference on Human Factors in Computing Systems, 20213D printing has revolutionized rapid prototyping by speeding up the creation of custom-shaped objects. With the rise of multi-material 3D printers, these custom-shaped objects can now be made interactive in a single pass through passive conductive ...
Martin Schmitz +4 more
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Organic materials for printed electronics
Nature Materials, 2007Organic materials can offer a low-cost alternative for printed electronics and flexible displays. However, research in these systems must exploit the differences - via molecular-level control of functionality - compared with inorganic electronics if they are to become commercially viable.
David Nilsson +2 more
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