Your search keyword '"Huang, Zeya"' showing total 3 results

1. Enhanced anti-deliquescent property and ultralow thermal conductivity of magnetoplumbite-type LnMeAl11O19 materials for thermal barrier coating.

Author

Wang, Chang‐An, Lu, Haoran, Huang, Zeya, and Xie, Huimin

Subjects

CERAMICS, THERMAL barrier coatings, THERMAL conductivity, MAGNESIUM ions, DELIQUESCENCE, STRUCTURAL stability, TRANSITION metal ions, PHONON scattering

Abstract

Magnetoplumbite-type LaMgAl11O19 ceramic has been proposed as one of promising candidates for the next generation thermal barrier coatings ( TBCs) due to its low thermal conductivity. However, LaMgAl11O19 shows poor water-resistance with significant weight loss at elevated temperatures in water-containing atmosphere. In this work, we revealed that the essential reason for the poor water-resistance of magnetoplumbite-type LaMgAl11O19 ceramic is Mg2+ migration from the intrinsic site under moisture environment. And then an effective approach was proposed to improve its anti-deliquescent property by completely substituting divalent alkaline earth ions Mg2+ with Zn2+. Finally, a panoscopic strategy was proposed to further lower thermal conductivity through co-substituting La and Zn sites in LaZnAl11O19 with trivalent and divalent transition metal ions. The mechanism for the lowered thermal conductivity is due to the panoscopic approach, which providing all-scale hierarchical architectures of phonon scattering mechanisms. The excellent anti-moisture performance and ultralow thermal conductivity endow the LaZnAl11O19 based ceramics as a kind of promising candidates for advanced thermal barrier coatings. [ABSTRACT FROM AUTHOR]

Published

2018

2. Construction of 3D MXene/Silver nanowires aerogels reinforced polymer composites for extraordinary electromagnetic interference shielding and thermal conductivity.

Author

Liu, Houbao, Huang, Zeya, Chen, Tian, Su, Xinqing, Liu, Yunan, and Fu, Renli

Subjects

*ELECTROMAGNETIC shielding, *THERMAL shielding, *ELECTROMAGNETIC interference, *THERMAL conductivity, *AEROGELS, *ELECTRIC conductivity, *NANOWIRES

Abstract

• MXene/AgNWs aerogels with interpenetrating double-network structure were fabricated. • The porous structure contributes to higher attenuation of electromagnetic waves. • 3D network provides channel for electron and phonon transmission in epoxy composites. • The composites possess remarkable EMI SE and thermal conductivity. The novel multifunctional materials with anti-electromagnetic interference (EMI) and effective thermal management are ideal for modern electronic industry. Generally, the EMI shielding effectiveness (SE) and thermal conductivity (TC) of materials can be effectively enhanced by compounding with high electrically and thermally conductive fillers. However, it seems that the high-performance cannot be compensated without sacrificing the high fillers loading. Herein, from one-dimensional silver nanowires (AgNWs) and two-dimensional MXene, three-dimensional MXene/AgNWs aerogels were designed as electric and heat transferring skeletons for epoxy nanocomposites by directional-freezing and freeze-drying methods. The resultant MXene/AgNWs/Epoxy nanocomposites with a low MXene/AgNWs content of 8.2 wt% combine a high electrical conductivity of 1532 S/m, and an exceptional EMI SE value of 94.1 dB with 3 mm thickness at the X-band frequency, as well as an improved TC of 2.34 W/m·K. The fabricated MXene/AgNWs/Epoxy nanocomposites possess excellent comprehensive properties enable valuable applications in electronic devices for EMI shielding and thermal management. [ABSTRACT FROM AUTHOR]

Published

2022

3. Superior hydrophobicity of nano-SiO2 porous thermal insulating material treated by oil-in-water microemulsion.

Author

Song, Xiaolong, Fu, Renli, Liu, Houbao, Huang, Zeya, Su, Xinqing, and Liu, Xuhai

Subjects

*PHYSICAL & theoretical chemistry, *MICROEMULSIONS, *THERMAL conductivity, *CONTACT angle, *POROSITY

Abstract

Nano-SiO 2 porous thermal insulating material (TIM) has drawn tremendous research interests due to its advantages of low density, high porosity and low thermal conductivity. However, its long-term stability in humid environment can be severely deteriorated by the high hydrophilicity resulting from tetrahedral coordination of oxygen and capillary effect of porous structure. It is still a great challenge to cost-effectively fabricate bulk TIM with superior hydrophobicity and consequent remarkable self-cleaning capability. Herein, via an oil-in-water microemulsion treatment, we have proposed a new strategy to construct 3D superior hydrophobic nano-SiO 2 porous TIM. The polymethylhydrosiloxane-modified TIM exhibits a large water contact angle of 166°, and corresponding excellent self-cleaning characteristic while maintaining low thermal conductivity of 0.031 W/m·K. Moreover, our high hydrophobicity of TIM exhibits excellent durability under high temperature up to 400 °C, high humidity of 100%, and chemical erosions. Detailed knowledge of the physical chemistry basis of the superior hydrophobic nano-SiO 2 porous TIM can provide great opportunity to fabricate advanced self-cleaning and heat insulating devices especially targeted for harsh environments. [ABSTRACT FROM AUTHOR]

Published

2022