Kaiqiang Zheng scite author profile

The development of integrated high-performance supercapacitors with all-in-one configuration, excellent flexibility and autonomously intrinsic self-healability, and without the extra healable film layers, is still tremendously challenging. Compared to the sandwich-like laminated structures of supercapacitors with augmented interfacial contact resistance, the flexible healable integrated supercapacitor with all-in-one structure could theoretically improve their interfacial contact resistance and energy densities, simplify the tedious device assembly process, prolong the lifetime, and avoid the displacement and delamination of multilayered configurations under deformations. Herein, a flexible healable all-in-one configured supercapacitor with excellent flexibility and reliable self-healing ability by avoiding the extra healable film substrates and the postassembled sandwich-like laminated structures is developed. The healable all-in-one configured supercapacitor is prepared from in situ polymerization and deposition of nanocomposites electrode materials onto the two-sided faces of the self-healing hydrogel electrolyte separator. The self-healing hydrogel film is obtained from the physically crosslinked hydrogel with enormous hydrogen bonds, which can endow the healable capability through dynamic hydrogen bonding. The assembled all-in-one configured supercapacitor exhibits enhanced capacitive performance, good cycling stability, reliable self-healing capability, and excellent flexibility. It holds broad prospects for obtaining various flexible healable all-in-one configured supercapacitors for working as portable energy storage devices in wearable electronics.

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Highly stable graphene oxide composite nanofiltration membrane

Zheng

Zhou

et al. 2021

Nanoscale

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Self‐Aided Batch Growth of 12‐Inch Transfer‐Free Graphene Under Free Molecular Flow

Liu

Sun

Cui

et al. 2022

Adv Funct Materials

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Direct synthesis of large‐area graphene on functional substrates via chemical vapor deposition has become a frontier research stream targeting practical applications. However, the batch production of transfer‐free graphene film with favorable quality and homogeneity remains a grand challenge. Herein, the direct growth of 12‐inch‐sized graphene is demonstrated over fused quartz in a batch manner. The key design of the synthetic route is the construction of a nano‐scale compartment to allow the formation of free molecular flow during growth, as well as to trap the hydroxyl species in situ released from the quartz substrates. Density functional theory calculations reveal that the hydroxyl species help decrease the energy barrier for feedstock decomposition and facilitate the carbon attachment to boost graphene growth. Thus‐prepared graphene possesses excellent optical transmittance (96% ± 1%) and electrical properties (1.22 ± 0.08 kΩ sq‒1). These findings unlock new opportunities for achieving batch production of graphene‐skinned functional materials with practical scalability and quality toward emerging uses.

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Transparent Electrothermal Heaters Based on Vertically-Oriented Graphene Glass Hybrid Materials

Cui

et al. 2019

Nanomaterials

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Transparent heating devices are widely used in daily life-related applications that can be achieved by various heating materials with suitable resistances. Herein, high-performance vertically-oriented graphene (VG) films are directly grown on soda-lime glass by a radio-frequency (rf) plasma-enhanced chemical vapor deposition (PECVD) method, giving reasonable resistances for electrothermal heating. The optical and electrical properties of VG films are found to be tunable by optimizing the growth parameters such as growth time, carrier gas flow, etc. The electrothermal performances of the derived materials with different resistances are thus studied systematically. Specifically, the VG film on glass with a transmittance of ~73% at 550 nm and a sheet resistance of ~3.9 KΩ/□ is fabricated into a heating device, presenting a saturated temperature up to 55 °C by applying 80 V for 3 min. The VG film on the glass at a transmittance of ~43% and a sheet resistance of 0.76 KΩ/□ exhibits a highly steady temperature increase up to ~108 °C with a maximum heating rate of ~2.6 °C/s under a voltage of 60 V. Briefly, the tunable sheet resistance, good adhesion of VG to the growth substrate, relative high heating efficiency, and large heating temperature range make VG films on glass decent candidates for electrothermal related applications in defrosting and defogging devices.

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Variant Selection in the Thermally Treated Ti-6Al-4V Processed by Laser Metal Deposition

Li¹,

Zheng²,

Zhao³

et al. 2023

Metallogr. Microstruct. Anal.

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Kaiqiang Zheng

A Flexible Stretchable Hydrogel Electrolyte for Healable All‐in‐One Configured Supercapacitors

Highly stable graphene oxide composite nanofiltration membrane

Self‐Aided Batch Growth of 12‐Inch Transfer‐Free Graphene Under Free Molecular Flow

Transparent Electrothermal Heaters Based on Vertically-Oriented Graphene Glass Hybrid Materials

Variant Selection in the Thermally Treated Ti-6Al-4V Processed by Laser Metal Deposition

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