Biodegradable Metallic Glass for Stretchable Transient Electronics

Bae, Jae‐Young; Gwak, Eun‐Ji; Hwang, Gyeong‐Seok; Hwang, Hae Won; Lee, Dong-Ju; Lee, Jongsung; Joo, Young‐Chang; Sun, Jeong‐Yun; Jun, Sang Ho; Ok, Myoung‐Ryul; Kim, Ju‐Young; Kang, Seung‐Kyun

doi:10.1002/advs.202004029

Cited by 27 publications

(18 citation statements)

References 45 publications

(70 reference statements)

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“…layer in fully biodegradable MgZnCa metallic glass (MG) film for application in intrinsically stretchable electrodes. [262] The PCL is another candidate that can be used in the biodegradable encapsulation of biodegradable magnesium/iron batteries. The use of PCL encapsulation minimized the volume of electrochemical cells and provided higher discharge rates and longer discharge lifetimes.…”

Section: Biodegradable Encapsulationmentioning

confidence: 99%

Advances in Biodegradable Electronic Skin: Material Progress and Recent Applications in Sensing, Robotics, and Human–Machine Interfaces

et al. 2022

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The signals generated by these stimuli are transferred to the central neural network and brain to provide an appropriate response. In addition, biological skin possesses unique characteristics, such as stretchability, self-healing ability, and mechanical toughness. [1][2][3] It also provides an effective barrier against ambient elements such as chemicals, gases, radiation, and external biological agents.Electronic skin (e-skin) is an artificial smart skin composed of various electronic sensors distributed on a single uniform surface or stacked on multiple surfaces. It mimics some of the biological skin senses and provides a promising sensing platform for key application areas such as wearable sensors, robotics, and prosthetics (Figure 1). [1,[4][5][6][7][8][9][10][11] However, serious concerns have arisen regarding the production of electronic waste (e-waste), the influence of e-skin on human health, the safety of wearable electronic devices, costs, and environmental limitations. These concerns have encouraged researchers to develop biocompatible, renewable, sustainable, and biodegradable flexible wearable detection devices and biosensing platforms. [12][13][14][15][16] Biological skin regularly regenerates the old superficial layer of the epidermis with new skin cells during the healing process. Inspired by this natural degradation cycle, artificial biodegradable skin-based electronics should be designed for programmable degradation, in contrast to conventional electronic materials. To achieve this goal, the development of biocompatible, environmentally friendly electronic systems that can be used for the fabrication of biodegradable and sustainable e-skins is important.Various low-cost, nontoxic, renewable, and natural substances and polymer-based materials that can be applied to the development of sustainable, biodegradable e-skins and alleviate the environmental and health risks of e-waste materials are available. [17][18][19][20][21][22] E-waste disrupts the biological activity of microbial enzymes and their metabolisms, which decreases the resistance and the diversity of soil-based microbial communities. [23] In addition, in the human body, the accumulation of metals and metalloids used in the fabrication of conventional electronics can cause a range of biophysical malfunctions and diseases, such as liver damage by Cu, behavioral disorders by Pb, and lung cancer and kidney damage by Cd. [24][25][26][27] The rapid growth of the electronics industry and proliferation of electronic materials and telecommunications technologies has led to the release of a massive amount of untreated electronic waste (e-waste) into the environment. Consequently, catastrophic environmental damage at the microbiome level and serious human health diseases threaten the natural fate of the planet. Currently, the demand for wearable electronics for applications in personalized medicine, electronic skins (e-skins), and health monitoring is substantial and growing. Therefore, "green" characteristics such as biodegradability, self-healin...

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Section: Biodegradable Encapsulationmentioning

confidence: 99%

Advances in Biodegradable Electronic Skin: Material Progress and Recent Applications in Sensing, Robotics, and Human–Machine Interfaces

et al. 2022

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“…Flexible conductive circuits with special deformability and conductivity are in essential demand for applications in wearable electronic devices, 1−3 medical implants, 4,5 and electromagnetic interference materials. 6,7 To fulfill the requirements of these applications, stable conductivity under various types of deformation or external stress conditions is highly desired, so a stable conductive network on a flexible polymeric insulating material as a substrate is the key.…”

Section: Introductionmentioning

confidence: 99%

“…Flexible conductive circuits with special deformability and conductivity are in essential demand for applications in wearable electronic devices, − medical implants, , and electromagnetic interference materials. , To fulfill the requirements of these applications, stable conductivity under various types of deformation or external stress conditions is highly desired, so a stable conductive network on a flexible polymeric insulating material as a substrate is the key. Therefore, various techniques, such as inkjet printing, , screen printing, ligand-induced electroless plating, and meniscus-limited electrodeposition, have been investigated in the past for the construction of high-quality flexible conductive circuits.…”

Section: Introductionmentioning

confidence: 99%

Laser Direct Activation of Polyimide for Selective Electroless Plating of Flexible Conductive Patterns

Ren

Zhang

et al. 2022

ACS Appl. Electron. Mater.

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Flexible conductive patterns on polyimide substrates are attracting increasing research interest in the areas of wearables, biomedicals, automotives, and energy harvesters. This paper reports a laser-induced selective activation (LISA) process for electroless metallization and, therefore, the creation of complex conductive patterns on polyimide substrates. In this process, a Q-switched pulsed laser is utilized for scanning the surface and forming the catalytic layer consisting of microporous structures, which enhances the stability of electroless plated metallic structures on the polyimide surface and exhibits superior mechanical stability under repeated bending and harsh environments. The high resolution of the metallic patterning enables the demonstration of a copper microgrid pattern with a line width down to 50 μm. Moreover, flexible light-emitting diode displays and electromagnetic interference shielding films are successfully manufactured to indicate the promising capability of our LISA process.

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“…Recently, stretchable electronic materials that can be integrated seamlessly with deformable, dynamic, and irregular surfaces, particularly on the human body, have presented new opportunities for wearable applications [ 1 , 2 , 3 , 4 , 5 , 6 ]. In addition to stretchable electronics, transient electronics built with biodegradable materials are of increasing interest for future wearable and implantable applications [ 2 , 6 , 7 , 8 , 9 , 10 ].…”

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Composite Microfiber for Biodegradable Stretchable Electronics

et al. 2021

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Biodegradable stretchable electronics have demonstrated great potential for future applications in stretchable electronics and can be resorbed, dissolved, and disintegrated in the environment. Most biodegradable electronic devices have used flexible biodegradable materials, which have limited conformality in wearable and implantable devices. Here, we report a biodegradable, biocompatible, and stretchable composite microfiber of poly(glycerol sebacate) (PGS) and polyvinyl alcohol (PVA) for transient stretchable device applications. Compositing high-strength PVA with stretchable and biodegradable PGS with poor processability, formability, and mechanical strength overcomes the limits of pure PGS. As an application, the stretchable microfiber-based strain sensor developed by the incorporation of Au nanoparticles (AuNPs) into a composite microfiber showed stable current response under cyclic and dynamic stretching at 30% strain. The sensor also showed the ability to monitor the strain produced by tapping, bending, and stretching of the finger, knee, and esophagus. The biodegradable and stretchable composite materials of PGS with additive PVA have great potential for use in transient and environmentally friendly stretchable electronics with reduced environmental footprint.

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Biodegradable Metallic Glass for Stretchable Transient Electronics

Cited by 27 publications

References 45 publications

Advances in Biodegradable Electronic Skin: Material Progress and Recent Applications in Sensing, Robotics, and Human–Machine Interfaces

Advances in Biodegradable Electronic Skin: Material Progress and Recent Applications in Sensing, Robotics, and Human–Machine Interfaces

Laser Direct Activation of Polyimide for Selective Electroless Plating of Flexible Conductive Patterns

A Composite Microfiber for Biodegradable Stretchable Electronics

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