Transient Rechargeable Batteries Triggered by Cascade Reactions

Fu, Kun; Liu, Zhen; Yao, Yonggang; Wang, Zhengyang; Zhao, Bin; Luo, Wei; Dai, Jiaqi; Lacey, Steven D.; Zhou, Lihui; Shen, Fei; Kim, Myeongseob; Swafford, Laura A.; Sengupta, L. C.; Hu, Liangbing

doi:10.1021/acs.nanolett.5b01451

Cited by 78 publications

(97 citation statements)

References 25 publications

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“…Alternative strategies with nonmetallic electrode materials have been proposed, such as edible sodium‐ion batteries based on melanins or activated carbon and sugar‐based enzymatic fuel cells . Eco‐friendly battery systems targeting nonbiological applications have also been presented, including transient lithium‐ion batteries through chemical reactions or chemical/mechanical disintegration and primary flow battery using organic quinone redox species . The major challenges of these systems are either containing nondegradable or non‐biocompatible battery components resulting in unnecessary materials retention that could cause adverse effects to the human body and the environment, or battery characteristics (e.g., voltage, power, capacity, or lifetime) that could fall beyond practical applications.…”

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confidence: 99%

A Fully Biodegradable Battery for Self‐Powered Transient Implants

Huang

Wang

Yuan

et al. 2018

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Biodegradable transient devices represent an emerging type of electronics that could play an essential role in medical therapeutic/diagnostic processes, such as wound healing and tissue regeneration. The associated biodegradable power sources, however, remain as a major challenge toward future clinical applications, as the demonstrated electrical stimulation and sensing functions are limited by wired external power or wireless energy harvesters via near-field coupling. Here, materials' strategies and fabrication schemes that enable a high-performance fully biodegradable magnesium-molybdenum trioxide battery as an alternative approach for an in vivo on-board power supply are reported. The battery can deliver a stable high output voltage as well as prolonged lifetime that could satisfy requirements of representative implantable electronics. The battery is fully biodegradable and demonstrates desirable biocompatibility. The battery system provides a promising solution to advanced energy harvesters for self-powered transient bioresorbable implants as well as eco-friendly electronics.

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confidence: 99%

A Fully Biodegradable Battery for Self‐Powered Transient Implants

Huang

Wang

Yuan

et al. 2018

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181

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“…Carefully selected device designs and encapsulation layers allow electronic systems formed with these materials to operate in a stable, high-performance manner for a desired time and then to degrade and disappear completely, at a molecular level, to biocompatible and ecocompatible end products. The results enable bioresorbable implants that bypass secondary surgical procedures for extraction, environmental sensors that avoid the need for retrieval and collection after use, and compostable electronics that eliminate costs and risks associated with recycling operations (24)(25)(26). Specific examples in the research literature include simple passive and active components (e.g., resistors, Si transistors), complementary metal-oxide-semiconductor (CMOS) inverters and their logic gates, sensors and detectors, energy storage devices and harvesters, and wireless RF power scavengers (27)(28)(29)(30).…”

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confidence: 99%

Materials and processing approaches for foundry-compatible transient electronics

Chang

Fang

Bower³

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Foundry-based routes to transient silicon electronic devices have the potential to serve as the manufacturing basis for "green" electronic devices, biodegradable implants, hardware secure data storage systems, and unrecoverable remote devices. This article introduces materials and processing approaches that enable state-of-theart silicon complementary metal-oxide-semiconductor (CMOS) foundries to be leveraged for high-performance, water-soluble forms of electronics. The key elements are (i) collections of biodegradable electronic materials (e.g., silicon, tungsten, silicon nitride, silicon dioxide) and device architectures that are compatible with manufacturing procedures currently used in the integrated circuit industry, (ii) release schemes and transfer printing methods for integration of multiple ultrathin components formed in this way onto biodegradable polymer substrates, and (iii) planarization and metallization techniques to yield interconnected and fully functional systems. Various CMOS devices and circuit elements created in this fashion and detailed measurements of their electrical characteristics highlight the capabilities. Accelerated dissolution studies in aqueous environments reveal the chemical kinetics associated with the underlying transient behaviors. The results demonstrate the technical feasibility for using foundry-based routes to sophisticated forms of transient electronic devices, with functional capabilities and cost structures that could support diverse applications in the biomedical, military, industrial, and consumer industries.soft electronics | biodegradable electronics | transfer printing | undercut etching | hydrolysis S emiconductor technology is increasingly essential to nearly all aspects of modern society, with projections of market sizes that will exceed $7 trillion in 2017, equivalent to 10% of the world's gross domestic product (1-4). The rapid and accelerating pace of innovation in this area leads to increases in the frequency with which consumers upgrade their devices, thereby contributing to the production of >50 million tons of electronic waste (e-waste) each year (5, 6). Furthermore, the anticipated emergence of electronics for internet-of-things applications, along with the continued proliferation of radio frequency (RF) identification tags and other high-volume electronic goods, create daunting challenges with the management of this e-waste (7, 8). These considerations motivate research into forms of electronics that can degrade naturally into the environment to harmless end products. Such technology is also of interest for other, unique classes of applications, ranging from biodegradable, temporary electronic implants to hardware secure data systems and unrecoverable, field-deployed devices (9-12). Sometimes referred to collectively as transient electronics, these types of devices can be constructed by using designer materials, such as specially formulated polymers or natural products (13-16), or clever combinations of established materials, well-aligned to existing ...

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“…Other strategies, such as overcoats of inactive encapsulation layers, regulation of properties, and dimensions of active materials, can be exploited to control the transience time in function . Beyond dissolution control with prescribed time span in a passive manner, actively programmable and on‐demand controlled degradations are possible via optical sources, temperature, and a series of chemical reactions . Figure b presents a schematic description and transient circuit diagram of in vitro demonstration for a tunable lifetime of a dissolvable integrated circuit in response to optical stimuli using commercial light‐emitting diodes (LED) connected with Mg electrodes/interconnects.…”

Section: Resultsmentioning

confidence: 99%

Biosafe, Eco‐Friendly Levan Polysaccharide toward Transient Electronics

Kwon

Lee

et al. 2018

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New options in the material context of transient electronics are essential to create or expand potential applications and to progress in the face of technological challenges. A soft, transparent, and cost-effective polymer of levan polysaccharide that is capable of complete, programmable dissolution is described when immersed in water and implanted in an animal model. The results include chemical analysis, the kinetics of hydrolysis, and adjustable dissolution rates of levan, and a simple theoretical model of reactive diffusion governed by temperature. In vivo experiments of the levan represent nontoxicity and biocompatibility without any adverse reactions. On-demand, selective control of dissolution behaviors with an animal model demonstrates an effective triggering strategy to program the system's lifetime, providing the possibility of potential applications in envisioned areas such as bioresorbable electronic implants and drug release systems.

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Transient Rechargeable Batteries Triggered by Cascade Reactions

Cited by 78 publications

References 25 publications

A Fully Biodegradable Battery for Self‐Powered Transient Implants

A Fully Biodegradable Battery for Self‐Powered Transient Implants

Materials and processing approaches for foundry-compatible transient electronics

Biosafe, Eco‐Friendly Levan Polysaccharide toward Transient Electronics

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