Skin Electronics: Oxide Nanomembrane Hybrids with Enhanced Mechano‐ and Thermo‐Sensitivity for Semitransparent Epidermal Electronics (Adv. Healthcare Mater. 7/2015)

Park, Minjoon; Do, Kyungsik; Kim, Jaemin; Son, Donghee; Koo, Ja Hoon; Park, Jinkyung; Song, Jae Yoon; Kim, Ji Hoon; Lee, Minbaek; Hyeon, Taeghwan; Kim, Dae‐Hyeong

doi:10.1002/adhm.201570042

Cited by 5 publications

(2 citation statements)

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“…One of the ultimate goals for flexible electronics is to be applied on the human skin. The skin electronics own advantages of comfortable and flexible feature [141,142]. Once this application is realised, it will contribute a lot to the health management.…”

Section: Typical Approaches To Innovate Liquid Metallic Biomaterialsmentioning

confidence: 99%

Liquid metal biomaterials: a newly emerging area to tackle modern biomedical challenges

Long

Liu

2017

International Materials Reviews

131

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Conventional biomaterials, such as metals, polymers, composites and ceramics, may not work well when facing certain tough medical challenges. As an alternative, body-temperature liquid metals, such as gallium, or its alloys are recently emerging as new generation functional materials which display many unconventional properties superior to traditional biomaterials, i.e. high fluidity, excellent electrical and thermal conductivities, good biocompatibility, sufficient radiopacity, controllable behaviour, easy manufacture and low cost. This article aims to outline a new biomedical category: liquid metal biomaterials. Representative applications enabled by liquid metal biomaterials from both therapeutic and diagnostic aspects were reviewed. Furthermore, related efforts and perspective for future development of employing liquid metals to resolve modern biomedical tough issues were discussed. With continuous technical progresses and fundamental discoveries, liquid metals are expected to offer more and more outstanding merits as a new class of biomaterials which are promising a generalised way towards resolving biomedical challenges.

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Section: Typical Approaches To Innovate Liquid Metallic Biomaterialsmentioning

confidence: 99%

Liquid metal biomaterials: a newly emerging area to tackle modern biomedical challenges

Long

Liu

2017

International Materials Reviews

131

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“…The emerging AM technologies applied to the micro-and nanoscales [3,6] demonstrate preliminary applications in mechanics [17], electronics (sensors, light-emitting diodes-LEDs) [18,19], optics and photonics (filters, photonic crystals, meta-materials, diffractive elements) [20][21][22], medicine [23] and bionics [24][25][26]. The rise of AM is expected in some emerging fields of microstructures such as wearable electronics [27,28], flexible batteries management, internet of things (IOT) [29], printed bionics/biomechanics [19], lab-onchip [30], and self-powered sensors.…”

Section: Introductionmentioning

confidence: 99%

Additive Manufacturing of Micro-Electro-Mechanical Systems (MEMS)

Pasquale

2021

Micromachines

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Recently, additive manufacturing (AM) processes applied to the micrometer range are subjected to intense development motivated by the influence of the consolidated methods for the macroscale and by the attraction for digital design and freeform fabrication. The integration of AM with the other steps of conventional micro-electro-mechanical systems (MEMS) fabrication processes is still in progress and, furthermore, the development of dedicated design methods for this field is under development. The large variety of AM processes and materials is leading to an abundance of documentation about process attempts, setup details, and case studies. However, the fast and multi-technological development of AM methods for microstructures will require organized analysis of the specific and comparative advantages, constraints, and limitations of the processes. The goal of this paper is to provide an up-to-date overall view on the AM processes at the microscale and also to organize and disambiguate the related performances, capabilities, and resolutions.

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3D printing methods for micro- and nanostructures

Fritzler¹,

Prinz²

2019

Phys.-Usp.

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The physical and physicochemical fundamentals of three-dimensional (3D) micro- and nanoprinting are presented. 3D printing (or additive manufacturing technology) is a process which fabricates structures and devices by depositing material (usually layer by layer) according to a 3D digital model. The methods and results reviewed here are limited to those from micro- and nanoscale fields, which are in demand in the fields of electronics, photonics, and bionics. Special attention is given to methods for fabricating sub-100-nm structures, including single- and two-photon polymerization stereolithography, electrohydrodynamic inkjet printing, and laser-induced forward transfer. The advantages and disadvantages of 3D printing methods are discussed, together with prospects for their development and application.

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Skin Electronics: Oxide Nanomembrane Hybrids with Enhanced Mechano‐ and Thermo‐Sensitivity for Semitransparent Epidermal Electronics (Adv. Healthcare Mater. 7/2015)

Cited by 5 publications

References 0 publications

Liquid metal biomaterials: a newly emerging area to tackle modern biomedical challenges

Liquid metal biomaterials: a newly emerging area to tackle modern biomedical challenges

Additive Manufacturing of Micro-Electro-Mechanical Systems (MEMS)

3D printing methods for micro- and nanostructures

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