Comb-type polymer-hybridized MXene nanosheets dispersible in arbitrary polar, nonpolar, and ionic solvents

Park, Gyeong Seok; Ho, Dong Hae; Lyu, Benzheng; Jeon, Seungwon; Ryu, Du Yeol; Kim, Dae Woo; Lee, Namkon; Kim, Sung-Wook; Song, Young Jae; Jo, Sae Byeok; Cho, Jeong Ho

doi:10.1126/sciadv.abl5299

Cited by 39 publications

(20 citation statements)

References 45 publications

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“…Indeed, compound structures [376,377] analogous to MXene have been synthesized by chemical vapor deposition. Second, the solution processing of MXene [92] becomes promising for mass production of nanosheets in dispersions [378]. The MXene quantum dots [100] are efficient photoluminescent materials for near-infrared images [108].…”

Section: Conclusion and Future Opportunitiesmentioning

confidence: 99%

“…The MXene quantum dots [100] are efficient photoluminescent materials for near-infrared images [108]. Besides, the long-term stability of MXene-based aqueous solutions or dispersion could be improved by polymer hybridization [379] and surface engineering [93,378] without oxidation [95]. Indeed, printed electronics require the long durability of MXene-based inks [119] for reducing manufacturing costs and maintaining the uniformity of fabricated films.…”

Section: Conclusion and Future Opportunitiesmentioning

confidence: 99%

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Applications of MXenes in human-like sensors and actuators

et al. 2022

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Human beings perceive the world through the senses of sight, hearing, smell, taste, touch, space, and balance. The first five senses are prerequisites for people to live. The sensing organs upload information to the nervous systems, including the brain, for interpreting the surrounding environment. Then, the brain sends commands to muscles reflexively to react to stimuli, including light, gas, chemicals, sound, and pressure. MXene, as an emerging two-dimensional material, has been intensively adopted in the applications of various sensors and actuators. In this review, we update the sensors to mimic five primary senses and actuators for stimulating muscles, which employ MXene-based film, membrane, and composite with other functional materials. First, a brief introduction is delivered for the structure, properties, and synthesis methods of MXenes. Then, we feed the readers the recent reports on the MXene-derived image sensors as artificial retinas, gas sensors, chemical biosensors, acoustic devices, and tactile sensors for electronic skin. Besides, the actuators of MXene-based composite are introduced. Eventually, future opportunities are given to MXene research based on the requirements of artificial intelligence and humanoid robot, which may induce prospects in accompanying healthcare and biomedical engineering applications.

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Section: Conclusion and Future Opportunitiesmentioning

confidence: 99%

Section: Conclusion and Future Opportunitiesmentioning

confidence: 99%

Applications of MXenes in human-like sensors and actuators

et al. 2022

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“…Through such approaches, it is possible to transform the hydrophilic MXene to hydrophobic and disperse it in specific organic solvents. However, highly concentrated MXene nonpolar dispersions have not been achieved and each surface modification can only provide a narrow stable dispersibility duration because the kinetics of the dispersion process relies on the balance of thermodynamic interactions. , In other words, exploring effective strategies to broaden the dispersion duration at a high concentration of MXene to achieve large-scale manufacturing of flexible electronic devices is highly in need . The formation of the Janus structure allows for the combination of materials with different properties, facilitating the realization of versatile functions and the expansion of multiple applications.…”

Section: Introductionmentioning

confidence: 99%

Two-Dimensional Janus MXene Inks for Versatile Functional Coatings on Arbitrary Substrates

Chen

Deng

et al. 2023

ACS Appl. Mater. Interfaces

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Solution processing of two-dimensional nanomaterial inks guarantees efficient, straightforward fabrication of functional films, coatings, flexible devices, etc. Despite the excellent solution processibility and viscoelasticity of MXene aqueous inks, formulation of nonaqueous MXene inks with great affinity to both hydrophilic and hydrophobic substrates has proven quite challenging, limiting the practical applications of MXenes in printing/coatings on various substrates. Here, MXene surface chemistry is manipulated by asymmetrically grafting polystyrene and further concentrating the flakes into additive-free Janus MXene organic inks. The modified MXene nanosheets exhibit hydrophilicity on one side and hydrophobicity on the other. As a result, Janus MXene nanosheets ensure broad dispersibility in polar and nonpolar solvents, which in turn greatly extends the ink shelf life by slowing down the oxidation kinetics. Janus MXene sheets dispersed in toluene at room temperature remain at 90% of the initial solids after 1 month of storage. Janus surface engineering on MXene flakes guarantees the straightforward formation of uniform yet firm, large-area coatings on hydrophilic or hydrophobic substrates. These coatings demonstrate improved photothermal properties and chemical stability as well as good electromagnetic interference shielding performance. This strategy provides a simple and cost-effective way to promote the performance of MXene electronics in a variety of applications.

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“…[1][2][3][4][5] Over the past years, abundant investigation on MAMs has been conducted to try to understand the intrinsic loss mechanism and improve their EM absorption performance. [6][7][8][9][10] The multitudinous MAMs with excellent absorption bandwidths typically lower than 2 GHz. [34] It follows that there exist various problems for these methods to adjust the effective absorption frequency of MAMs, mainly including the narrow frequency tuning range, complex technological process, and incompatibility between the frequency regulation and the wave absorption properties.…”

Section: Introductionmentioning

confidence: 99%

“…[ 1–5 ] Over the past years, abundant investigation on MAMs has been conducted to try to understand the intrinsic loss mechanism and improve their EM absorption performance. [ 6–10 ] The multitudinous MAMs with excellent characteristics are ferreted out and can be classified into broad categories as dielectric loss materials, [ 11–13 ] magnetic loss material, [ 14–16 ] chiral materials, [ 17–19 ] and metamaterials. [ 20,21 ] Thereinto, some material systems with ingenious designs have nearly satisfied the high‐specification using needs, namely thin coating, light weight, wide bandwidth, and strong absorption.…”

Section: Introductionmentioning

confidence: 99%

Carbon Nanocoils/Carbon Foam as the Dynamically Frequency‐Tunable Microwave Absorbers with an Ultrawide Tuning Range and Absorption Bandwidth

Shi

Wang

et al. 2022

Adv Funct Materials

102

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The absorption frequency of conventional microwave absorbing materials (MAMs) is hardly tuned in operando, while such dynamic frequency regulation of MAMs is of great significance to meet the high demands of modern radars and intelligent electron devices. Here, an ingenious frequency-tuning strategy by means of the pressure variations is developed by fabricating highly compressible carbon nanocoils/carbon foam (CNCs/CF) as a dynamically frequency-tunable microwave absorber. Through adjusting the compression strain, the absorption bandwidth of CNCs/CF can be precisely tuned from S-band (2−4 GHz) to Ku-band (12−18 GHz). The adjustable effective absorption bandwidth is as wide as 15.4 GHz, which covers 96% of the entire microwave frequency. Under 10% compression strain, CNCs/ CF shows an attractive bandwidth of 9.0 GHz and a strong reflection loss of −64.6 dB. Furthermore, the CNCs/CF also exhibit a good thermal insulation, strong hydrophobicity, and strain-sensitive conductivity, endowing them with fascinating functions of heat insulation and self-cleaning. The method of utilizing an external pressure to dynamically adjust the absorption frequencies of CNCs/CF is demonstrated for the first time, which opens an avenue for the applications of dynamically frequency-tunable MAMs with an ultrawide adjusting range and absorption bandwidth.

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Comb-type polymer-hybridized MXene nanosheets dispersible in arbitrary polar, nonpolar, and ionic solvents

Cited by 39 publications

References 45 publications

Applications of MXenes in human-like sensors and actuators

Applications of MXenes in human-like sensors and actuators

Two-Dimensional Janus MXene Inks for Versatile Functional Coatings on Arbitrary Substrates

Carbon Nanocoils/Carbon Foam as the Dynamically Frequency‐Tunable Microwave Absorbers with an Ultrawide Tuning Range and Absorption Bandwidth

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