Xylem-Inspired Polyimide/MXene Aerogels with Radial Lamellar Architectures for Highly Sensitive Strain Detection and Efficient Solar Steam Generation

Liao, Pu; Ma, Huijuan; Dong, Jiancheng; Zhang, Chao; Lai, Feili; He, Guanjie; Ma, Piming; Dong, Weifu; Huang, Yunpeng; Liu, Tianxi

doi:10.1021/acs.nanolett.2c01486

Cited by 44 publications

(34 citation statements)

References 45 publications

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“…The rapid development of artificial intelligence and the Internet of things (IoT) is updating our lifestyle in a noticeable way, and the cornerstone of these technologies is the powerful and accurate communication between humankind and machines. − Particularly, deformable on-skin electronics are becoming the primary interactive medium for next-generation HMIs to meet the needs of stretchability, portability, and low power consumption. − Deformable electronics generally consist of stretchable substrates assembled with flexible circuits. Yet conventional wearable devices are usually made up of rigid, brittle, and hermetical matrixes that cannot realize the intimate contact with human skin nor satisfy long-term wearing comfort.…”

Section: Design Of the Janus E-textilementioning

confidence: 89%

Perspiration-Wicking and Luminescent On-Skin Electronics Based on Ultrastretchable Janus E-Textiles

et al. 2022

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Stretchable electronics have attracted surging attention for next-generation smart wearables, yet traditional flexible devices fabricated on hermetical elastic substrates cannot satisfy lengthy wearing comfort and signal stability due to their poor moisture and air permeability. Herein, perspiration-wicking and luminescent on-skin electrodes are fabricated on superelastic nonwoven textiles with a Janus configuration. Through the electrospin-assisted face-to-face assembly of all-SEBS microfibers with differentiated diameters and composition, porosity and wettability asymmetry are constructed across the textile, endowing it with antigravity water transport capability for continuous sweat release. Also, the phosphor particles evenly encapsulated in the elastic fibers empower the Janus textile with stable light-emitting capability under extreme stretching in a dark environment. Additionally, the precise printing of highly conductive liquid metal (LM) circuits onto the matrix not only equips the electronic textile with broad detectability for various biophysical and electrophysiological signals but also enables successful implementation of human–machine interface (HMIs) to control a mechanical claw.

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Section: Design Of the Janus E-textilementioning

confidence: 89%

Perspiration-Wicking and Luminescent On-Skin Electronics Based on Ultrastretchable Janus E-Textiles

et al. 2022

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“…There are five typical types of microstructures, including isotropic cellular, aligned honeycomb, and aligned lamellar configurations for which the last can be further divided into local oriented, long-range ordered, and radial ones. To date, all of them have been introduced into the MXene monoliths ( Figure 3 ) [ 34 , 53 , 55 , 59 , 60 ]. Moreover, by adjusting the interactions between the components (MXenes and additives), or by varying the manufacturing parameters (concentrations, and freezing rate/direction), a high degree control of the microstructure over the MXene monoliths has been achieved, enabling a wide range of hierarchies at the nano-, micro-, and mesoscales.…”

Section: Types Of Microstructures and Fabrication Of Mxene-based Poro...mentioning

confidence: 99%

“…GO aerogel with a radial and centrosymmetric structure exhibited superior elasticity and absorption capacity to that of GO aerogels with “traditional” pore structures made by conventional FC, showing the great value of this configuration [ 114 ]. Building MXene monoliths with radially distributed lamellar structure is a cutting-edge topic, which was recently achieved by Liu and co-workers [ 53 ]. They reported a Ti 3 C 2 T x /PI aerogel with vertically and radially aligned layers formed via a radial freeze casting (RFC) process.…”

Section: Types Of Microstructures and Fabrication Of Mxene-based Poro...mentioning

confidence: 99%

MXene-Based Porous Monoliths

Yang

Wang

et al. 2022

Nanomaterials

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In the past decade, a thriving family of 2D nanomaterials, transition-metal carbides/nitrides (MXenes), have garnered tremendous interest due to its intriguing physical/chemical properties, structural features, and versatile functionality. Integrating these 2D nanosheets into 3D monoliths offers an exciting and powerful platform for translating their fundamental advantages into practical applications. Introducing internal pores, such as isotropic pores and aligned channels, within the monoliths can not only address the restacking of MXenes, but also afford a series of novel and, in some cases, unique structural merits to advance the utility of the MXene-based materials. Here, a brief overview of the development of MXene-based porous monoliths, in terms of the types of microstructures, is provided, focusing on the pore design and how the porous microstructure affects the application performance.

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“…In addition, Wang et al prepared a Murray membrane base on the transpiration of vascular plants by layer-by-layer deposition technology, which has multibranching macrometer-, micrometer-, and submicrometer-sized pores to guide directional water transport. In summary, to some extent, those strategies are useful to regulate the human body’s wet comfort, but they are also associated with shortcomings related to chemical stability and mechanical properties. , Kevlar fibers were selected as a traditional special material because of its high chemical stability and excellent mechanical properties. , Based on those researches, the preparation of wearable materials using Kevlar as a raw material is proposed. , Therefore, it would be of great interest to develop wearable materials with unidirectional liquid penetration and heat preservation properties by using Kevlar fibers as the raw material.…”

Section: Introductionmentioning

confidence: 99%

“…In summary, to some extent, those strategies are useful to regulate the human body's wet comfort, but they are also associated with shortcomings related to chemical stability and mechanical properties. 34,35 Kevlar fibers were selected as a traditional special material because of its high chemical stability and excellent mechanical properties. 36,37 Based on those researches, the preparation of wearable materials using Kevlar as a raw material is proposed.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Flexible Wearable Kevlar Aerogel Membranes with Breathable and Unidirectional Liquid Penetration Properties for Personal Thermal Management Application

Chen

Gan

Zhang³

et al. 2022

Ind. Eng. Chem. Res.

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Heat preservation, breathability, and unidirectional liquid penetration properties of wearable materials are vital for personal thermal management applications. Herein, flexible wearable Kevlar aerogel membranes with breathable and unidirectional liquid penetration properties were fabricated by underwater protection spraying of PDMS-trichlorotoluene onto one side of a Kevlar aerogel membrane and magnetron sputtering of Al nanoparticles on the other side of a Kevlar aerogel membrane PDMS (Al-KAM-PDMS). The results indicated that the PDMS side played an important role in improving the unidirectional liquid penetration property due to the asymmetric wettability property and an aerogel structure. To simulate unidirectional liquid penetration, simulated sweat can be penetrated from the PDMS side to the Al side of Al-KAM-PDMS within 14.4 s, implying excellent permeability. The Al side with high infrared reflectivity (72.77%) demonstrates that infrared radiation can be reflected back to the human body to achieve passive heating. An infrared image shows that Al-KAM-PDMS enables a simulated skin temperature decrease of 5 °C under a low temperature environment as compared to the Kevlar aerogel. The introduction of PDMS into Al-KAM-PDMS endows the membrane with high tensile stress of 5.60 MPa. In addition, Al-KAM-PDMS also possesses excellent breathability, showing its potential in wearable materials. Because of the exceptional unidirectional liquid penetration, breathability, and radiant heat insulation ability, Al-KAM-PDMS is a promising wearable material to help maintain a comfortable microclimate for individuals in outdoor environments.

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Xylem-Inspired Polyimide/MXene Aerogels with Radial Lamellar Architectures for Highly Sensitive Strain Detection and Efficient Solar Steam Generation

Cited by 44 publications

References 45 publications

Perspiration-Wicking and Luminescent On-Skin Electronics Based on Ultrastretchable Janus E-Textiles

Perspiration-Wicking and Luminescent On-Skin Electronics Based on Ultrastretchable Janus E-Textiles

MXene-Based Porous Monoliths

Multifunctional Flexible Wearable Kevlar Aerogel Membranes with Breathable and Unidirectional Liquid Penetration Properties for Personal Thermal Management Application

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