Formation of Triboelectric Series <i>via</i> Atomic-Level Surface Functionalization for Triboelectric Energy Harvesting

Shin, Sung Ho; Bae, Young Eun; Moon, Hyun Kyung; Kim, Jungkil; Choi, Suk Ho; Kim, Yong-Ho; Yoon, Ho‐Geun; Lee, Min Hyung; Nah, Junghyo

doi:10.1021/acsnano.7b02156

Cited by 178 publications

(113 citation statements)

References 45 publications

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“…For a structural approach, uniquely designed micro/nanoscale structures such as surface micropatterns, micropore, nanoscale assembly, and hierarchical nanoporous and interlocked microridge structures have been suggested, which enables the increases in surface area and stress‐induced deformability, thereby producing enhanced power up to a few tens of milliwatts. In addition, chemically modified surface charge by self‐assembled monolayers using an end‐fluorine terminated group, thiol with a different head group, and atomic‐level halogens and amines influences the surface potential and surface charge density, enabling control of triboelectric output.…”

Section: Discussionmentioning

confidence: 99%

Mimicking Human and Biological Skins for Multifunctional Skin Electronics

Lee

Park

Choe

et al. 2019

Adv Funct Materials

267

220

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Electronic skin (e-skin) technology is an exciting frontier to drive the next generation of wearable electronics owing to its high level of wearability, enabling high accuracy to harvest information of users and their surroundings. Recently, biomimicry of human and biological skins has become a great inspiration for realizing novel wearable electronic systems with exceptional multifunctionality as well as advanced sensory functions. This review covers and highlights bioinspired e-skins mimicking perceptive features of human and biological skins. In particular, five main components in tactile sensation processes of human skin are individually discussed with recent advances of e-skins that mimic the unique sensing mechanisms of human skin. In addition, diverse functionalities in user-interactive, skinattachable, and ultrasensitive e-skins are introduced with the inspiration from unique architectures and functionalities, such as visual expression of stimuli, reversible adhesion, easy deformability, and camouflage, in biological skins of natural creatures. Furthermore, emerging wearable sensor systems using bioinspired e-skins for body motion tracking, healthcare monitoring, and prosthesis are described. Finally, several challenges that should be considered for the realization of next-generation skin electronics are discussed with recent outcomes for addressing these challenges.

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Section: Discussionmentioning

confidence: 99%

Mimicking Human and Biological Skins for Multifunctional Skin Electronics

Lee

Park

Choe

et al. 2019

Adv Funct Materials

267

220

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“…The output power of the corresponding TEG was enhanced by almost 4 times. A wide spectrum of controllable triboelectric polarity was obtained through the functionalization of surfaces with the halogen (Br, F and Cl)-containing molecules or the aminated molecules, as shown in Figure 6(b) [104]. Here, hydroxyl surface groups formed by oxygen plasma treatment played a crucial role as strong covalent bonds between the substrate and the molecules.…”

Section: Chemical Functionalization and Modificationmentioning

confidence: 99%

“…(b) Schematic illustrations of surfacefunctionalized polyethylene terephthalate (PET) substrates with various organic molecule head groups for negatively or positively charging. Reprinted with permission from[104]. Copyright 2017 American Chemical Society.…”

mentioning

confidence: 99%

Modulation of surface physics and chemistry in triboelectric energy harvesting technologies

Lee

Kim

Park

et al. 2019

Science and Technology of Advanced Materials

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Mechanical energy harvesting technology converting mechanical energy wasted in our surroundings to electrical energy has been regarded as one of the critical technologies for self-powered sensor network and Internet of Things (IoT). Although triboelectric energy harvesters based on contact electrification have attracted considerable attention due to their various advantages compared to other technologies, a further improvement of the output performance is still required for practical applications in next-generation IoT devices. In recent years, numerous studies have been carried out to enhance the output power of triboelectric energy harvesters. The previous research approaches for enhancing the triboelectric charges can be classified into three categories: i) materials type, ii) device structure, and iii) surface modification. In this review article, we focus on various mechanisms and methods through the surface modification beyond the limitations of structural parameters and materials, such as surficial texturing/patterning, functionalization, dielectric engineering, surface charge doping and 2D material processing. This perspective study is a cornerstone for establishing next-generation energy applications consisting of triboelectric energy harvesters from portable devices to power industries.

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“…e) Results from contact electrification of poly(ethylene terephthalate) (PET) functionalized with different types of functional groups on its surface and unmodified PET. d,e) Reproduced with permission . Copyright 2017, American Chemical Society.…”

Section: Strategies For Controlling Surface Chargementioning

confidence: 99%

“…Coating surfaces is another way to control the amount of charge generated by contact electrification. For example, coating self‐assembled monolayers (SAMs) of nonionic molecules of different types of functional groups on surfaces has been demonstrated to give rise to a wide range of charging behavior . In one experiment, the surface of poly(ethylene terephthalate) (PET) was coated with SAMs of nonionic molecules that consisted of halogen‐terminated arylsilane molecules and aminated molecules (Figure d).…”

Section: Strategies For Controlling Surface Chargementioning

confidence: 99%

Controlling Surface Charge Generated by Contact Electrification: Strategies and Applications

et al. 2018

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Contact electrification is the phenomenon in which charge is generated on the surfaces of materials after they come into contact. The surface charge generated has traditionally been known to cause a vast range of undesirable consequences in our lives and in industry; on the other hand, it can also give rise to many types of useful applications. In addition, there has been a lot of interest in recent years for fabricating devices and materials based on regulating a desired amount of surface charge. It is thus important to understand the general strategies for increasing, decreasing, or controlling the surface charge generated by contact electrification. Herein, the fundamental mechanisms for influencing the amount of charge generated, the methods used for implementing these mechanisms, and some of the recent interesting applications that require regulating the amount of surface charge generated by contact electrification, are briefly summarized.

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Formation of Triboelectric Series via Atomic-Level Surface Functionalization for Triboelectric Energy Harvesting

Cited by 178 publications

References 45 publications

Mimicking Human and Biological Skins for Multifunctional Skin Electronics

Mimicking Human and Biological Skins for Multifunctional Skin Electronics

Modulation of surface physics and chemistry in triboelectric energy harvesting technologies

Controlling Surface Charge Generated by Contact Electrification: Strategies and Applications

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