Your search keyword '"Chen, Yugu"' showing total 15 results

1. Lattice dynamics and terahertz response of microwave dielectrics: A case study of Al-doped Ca0.6Sm0.27TiO3 ceramics.

Author

Guo, Weijia, Ma, Zhiyu, Chen, Yugu, Lu, Yutian, and Yue, Zhenxing

Abstract

Low-loss microwave dielectric ceramics are of great significance for fifth-generation telecommunication (5G) devices used for higher frequencies, while reducing the dielectric loss in the microwave band is still a technical challenge. Lattice dynamics and terahertz response are closely related to the polarization of dielectrics, and can be used as effective methods to explore the loss mechanism of microwave dielectrics. Here, Al3+ was doped into the conventional high-permittivity (ε r) Ca 1- x Sm 2 x /3 TiO 3 (x = 0.4) ceramic system, enhancing the Q × f values significantly. Raman spectra, thermally stimulated depolarization currents (TSDC) and terahertz time-domain spectra (THz-TDS) together showed that the stiffness of cation vibration became stronger when z value was larger, indicating a smaller damping of the lattice vibration, and leading to lower extrinsic losses and higher Q × f values. The relationship between lattice dynamics, defect behavior and microwave dielectric loss will provide a significant reference for the development of low-loss microwave dielectric ceramics. • Medium/high- ε r dielectrics of microwave/terahertz devices are developed. • The Q × f values in the microwave and terahertz bands are essentially constant. • Bond strength, defects, lattice vibration and dielectric loss have strong correlation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Thermally-stimulated defect relaxations and microwave/terahertz dielectric response of La,Al co-doped (Ba,Sr)La4Ti4O15 ceramics.

Author

Luo, Yu, Guo, Weijia, Chen, Yugu, Zhang, Jie, and Yue, Zhenxing

Subjects

*CERAMICS, *LATTICE constants, *MICROWAVES, *DIELECTRICS, *DIELECTRIC loss, *DIELECTRIC properties

Abstract

• The defect dipoles and oxygen vacancies were supposed to be the main defects in La,Al co-doped (Ba,Sr)La 4 Ti 4 O 15 ceramics. • The oxygen vacancies in the ceramics were affected by the lattice parameters. • The oxygen vacancies in the ceramics dominated the dielectric loss in microwave/terahertz frequency ranges. The thermally-stimulated relaxation of defects in La,Al co-substituted (Ba,Sr)La 4 Ti 4 O 15 dielectric ceramics with hexagonal perovskite structure were investigated systematically with the thermally stimulated depolarization current (TSDC) measurements. The ion substitution decreased the lattice parameters and the bond lengths of the cations and O2−. TSDC spectra indicated the main extrinsic defects in the ceramics were oxygen vacancies and the concentration of oxygen vacancies decreased with the increasing ion substitutions, which was derived from the decrease in the lattice parameters. The terahertz time-domain spectra indicated the damping factor of lattice vibration was reduced with the decline of the concentration of oxygen vacancies, which decreased the microwave/terahertz dielectric loss. High-performance (Ba 0.2 Sr 0.8) 0.75 La 4.25 Ti 3.75 Al 0.25 O 15 (ε r = 43.9, Q × f = 84300 GHz, τ f = -18.0 ppm/°C) ceramics were obtained. The correlations between crystal structures, defect behaviors and dielectric properties discussed in this work could provide guidance for the modification of microwave dielectric ceramics. [ABSTRACT FROM AUTHOR]

Published

2021

3. Ultralight and high-strength bulk alumina/zirconia composite ceramic foams through direct foaming method.

Author

Huo, Wenlong, Zhang, Xiaoyan, Chen, Yugu, Hu, Zunlan, Wang, Dong, and Yang, Jinlong

Subjects

*ALUMINUM oxide, *ZIRCONIUM oxide, *CERAMICS, *POROSITY, *COMPOSITE materials

Abstract

Abstract The mechanical strength of highly porous ceramic foams shows significant attenuation with the increase of porosity, especially for ceramic foams with very high porosity level above 95%. Ultra-light bulk composite ceramic foams were fabricated via introducing 20 wt% zirconia in alumina-based cell wall, aiming at improving mechanical strength of alumina based ceramic foams. The preparation and stability of alumina and zirconia particles synergistically stabilized foams were investigated. The obtained bulk ceramic foams manifested an exciting combination of both high porosity above 96% and excellent specific compressive strength, due to their closed pore structure, defect-free cell wall with uniform thickness, and uniformly distributed zirconia grains in alumina matrix. The alumina/zirconia composite ceramic foams with porosity of 96.7% exhibited compressive strength of 1.11 ± 0.07 MPa, which was much higher than that of alumina ceramic foams in the case of same porosity. [ABSTRACT FROM AUTHOR]

Published

2019

4. Mechanical strength of highly porous ceramic foams with thin and lamellate cell wall from particle-stabilized foams.

Author

Huo, Wenlong, Zhang, Xiaoyan, Chen, Yugu, Wang, Dong, Liu, Jingjing, Yan, Shu, and Yang, Jinlong

Subjects

*STRENGTH of materials, *POROUS materials, *CERAMIC materials, *FOAM, *ZIRCONIUM oxide

Abstract

Compressive strength is one of the most important mechanical properties for ceramic foams but the dependence of compressive strength of highly porous ceramic foams on porosity remains unclear up to now, especially for the ceramic foams with porosity above 94%. In this paper, the relationship between compressive strength and porosity of ceramic foams with high porosity in the range of 79–98% was studied for the first time. The alumina ceramic foams and zirconia foams were prepared by particle-stabilized foaming method using sodium dodecyl sulfonate (SDS) as foaming agent. It was found that the function relation between compressive strength and porosity depended on porosity level. Specifically, compressive strength of ceramic foams fitted well with Rice Model when the porosity ranged from 79% to 94%. When the porosity increased above 95%, compressive strength of ceramic foams showed linear relation to porosity, which was probably due to the characteristic of highly porous ceramic foams with thin and lamellate cell wall. [ABSTRACT FROM AUTHOR]

Published

2018

5. Novel mullite ceramic foams with high porosity and strength using only fly ash hollow spheres as raw material.

Author

Huo, Wenlong, Zhang, Xiaoyan, Chen, Yugu, Lu, Yuju, Liu, Jingjing, Yan, Shu, Wu, Jia-Min, and Yang, Jinlong

Subjects

*MULLITE synthesis, *FLY ash, *POROSITY, *SINTERING, *FRACTURE mechanics

Abstract

A novel approach to fabricate mullite ceramic foams with high porosity and mechanical strength using fly ash hollow spheres (FAHSs) as the only raw material was reported for the first time, in which FAHSs served as both matrix and pore-forming agent. It was demonstrated that uniform FAHS ceramic foams without cracks could be fabricated by both direct stack sintering method and gel-casting route. The effect of sintering temperature on linear shrinkage, porosity, phase composition and mechanical properties was investigated. With the increase of sintering temperature from 1200 °C to 1350 °C, the fracture mechanism changed from fracturing along FAHSs to fracturing across FAHSs, and the compressive strength of the FAHS ceramic foams increased from 4.4 MPa to 33.4 MPa. The FAHS ceramic foams exhibited high porosity in the range of 73–81% and high mechanical strength, which benefited from the dense assembling of small FAHSs with natural diameter distribution and excellent wall-thickness uniformity. [ABSTRACT FROM AUTHOR]

Published

2018

6. Highly porous and hierarchical MgAl2O4 ceramics with improved pore connectivity prepared from gelled particle-stabilized foams.

Author

Ren, Bo, Liu, Jingjing, Wang, Yali, Xi, Xiaoqing, Lu, Yuju, Yedong, Rong, Wang, Lu, Chen, Yugu, and Yang, Jinlong

Subjects

*CERAMICS, *CATALYST supports, *FIRING (Ceramics), *HIGH temperature physics, *COMPRESSIVE strength, *FOAM

Abstract

Ultralight ceramics with striking mechanical properties and improved pore connectivity could have wide applications in areas ranging from catalyst support to hot gas filtration. However, creating such materials has proven to be a challenging target. This work demonstrated a novel methodology to prepare porous MgAl 2 O 4 ceramics by calcining gelled MgO–Al 2 O 3 –SiO 2 particle-stabilized foams. The striking green strength of dried foams can be achieved as a consequence of MgO hydration and subsequent formation of gelled Mg(OH) 2 and MgO–SiO 2 –H 2 O skeleton. The decomposition of colloidal substance at elevated temperature resulted in the formation of small pores on the cell wall, thus forming the hierarchical porous architecture and improving the pore connectivity. The highly porous MgAl 2 O 4 ceramics fired at 1600°C possessed the integrated properties of ultrahigh porosity (87.0%), improved pore connectivity and satisfactory compressive strength (7.93 MPa), showing great potential to be used in multiple industrial fields. [ABSTRACT FROM AUTHOR]

Published

2019

7. Preparation of low-shrinkage and high-performance alumina ceramics via incorporation of pre-sintered alumina powder based on Isobam gelcasting.

Author

Lv, Lin, Lu, Yuju, Zhang, Xiaoyan, Chen, Yugu, Huo, Wenlong, Liu, Wei, and Yang, Jinlong

Subjects

*GELCASTING, *ALUMINUM oxide, *CERAMICS, *POWDERS, *ALUMINA composites, *SPECIFIC gravity

Abstract

Mechanically robust alumina ceramics with low shrinkage were successfully prepared via gelcasting using Isobam as the gelling agent and pre-sintered alumina powder as the raw material for the first time. The influence of amount of pre-sintered alumina powder and powder's pre-sintering temperature on the viscosity of suspension and mechanical properties of low-shrinkage alumina ceramics were systematically investigated. The results showed that low-shrinkage alumina ceramics with flexural strength of 294.5 ± 33.0 MPa, linear shrinkage of 7.79% and relative density of 91.5% can be obtained with the addition of 60 wt% alumina powder pre-sintered at 1600 °C. This convenient and facile approach is promising to fabricate low-shrinkage alumina ceramics with large sizes, high dimensional accuracy and complex shapes. [ABSTRACT FROM AUTHOR]

Published

2019

8. Hierarchical porous ceramics with 3D reticular architecture and efficient flow-through filtration towards high-temperature particulate matter capture.

Author

Liu, Jingjing, Ren, Bo, Wang, Yali, Lu, Yuju, Wang, Lu, Chen, Yugu, Yang, Jinlong, and Huang, Yong

Subjects

*CERAMICS, *PARTICULATE matter, *AIR pollutants, *CARBAMATES, *ALUMINUM oxide

Abstract

Graphical abstract Highlights • Carbamate functional group was grafted onto carbon black surface. • Hierarchical PACs with 3D reticular architectures were fabricated. • PACs showed superior high-temperature particulate matter filtration. Abstract Porous ceramics with high porosity and extensive interconnected pores have great application potential in fields ranging from dye removal to high-temperature particulate matter (PM) capture. However, constructing these materials to achieve efficient filtration is extremely challenging. Herein, a novel strategy to create hierarchical-structured porous alumina ceramics (PACs) with three-dimensional (3D) reticular architecture is reported based on polyurethane (PU) foaming method. To ensure the efficient flow-through filtration, carbamate-grafted carbon black is used as the pore-forming agent and assembled into the porous PU framework. Submicron and micron-sized pores on the cell walls are observed in hierarchical-structured PACs. This unique structure enables a high PM removal efficiency (94.1%) at an ultralow pressure drop (20 Pa). Our work has demonstrated great application potentials of as-prepared PACs as an efficient high-temperature PM filter and provided new insights to develop highly effective filter. [ABSTRACT FROM AUTHOR]

Published

2019

9. Preparation of Al2O3-Si3N4 porous ceramics with a cactus-like architecture for potential filters applications.

Author

Ren, Bo, Wang, Yali, Liu, Jingjing, Zhang, Xiaoyan, Chen, Yugu, Rong, Yedong, and Yang, Jinlong

Subjects

*ALUMINUM oxide, *SILICON compounds, *POROUS materials, *CERAMIC materials, *FILTERS & filtration, *FOAM

Abstract

Abstract In the present work, Al 2 O 3 -Si 3 N 4 porous ceramics with a cactus-like architecture were fabricated by calcining Al 2 O 3 -Si binary particle-stabilized foams in the nitrogen atmosphere. A large number of acicular Si 3 N 4 nanobelts were constructed on the surface of cell walls as a consequence of CVD process to achieve an interlaced network. Such structure was beneficial to realize a high capture efficiency of particulate matters (PM) during filtration. Resultant products having a bulk density of 0.38 g/cm3 at an apparent porosity of 86% can potentially be applied as the air filters in environment field. [ABSTRACT FROM AUTHOR]

Published

2019

10. Ceramic particle-stabilized foams/emulsions with UV light response and further synthesis of ceramic capsules.

Author

Huo, Wenlong, Zhang, Xiaoyan, Gan, Ke, Li, Hezhen, Yan, Shu, Chen, Yugu, and Yang, Jinlong

Subjects

*EMULSION polymerization, *EMULSIONS, *FOAM, *CERAMIC materials, *THERMAL insulation, *AQUEOUS solutions

Abstract

Graphical abstract Highlights • Aqueous ceramic particle-stabilized foams with UV light response are prepared. • Photocurable particle-stabilized emulsions with controllable structure are achieved. • The colloid foams/emulsions demonstrate excellent stability and photocuring ability. • Rapid and scalable synthesis of ceramic capsules is developed based on the emulsions. Abstract We herein report the design and preparation of ceramic particle-stabilized emulsions/foams with distinct ultraviolet light (UV) response, which can be used for the rapid fabrication of ceramic foams with complex shape, for synthesis of ceramic hollow spheres, and can potentially be used for 3D printing lightweight and hierarchical ceramics with porous skeleton. Photocurable foams/emulsions stabilized by ceramic particles are achieved for the first time using photosensitive oligomer as oil phase and/or using photosensitive aqueous solution containing acrylamide monomer as water phase. Four kinds of photocurable emulsions are demonstrated by adjusting emulsion structure and photosensitive phase. We further synthesize internal multiple-pore structured capsules and lightweight nanoparticle-assembled capsules in micron-scale based on the photocurable particle-stabilized, by separating emulsion into small droplets via diluting and stirring, followed by rapid curing under UV. This new strategy may potentially open opportunities for the rapid and cost-effective synthesis of high-output ceramic capsule materials. The synthesized thin-shell alumina capsules exhibit large specific area surface of 323.18 m2/g as well as uniform mesoporous structure in shell with average pore diameter of 3.4 nm, which has potential application in the fields of adsorption, load and release of materials and thermal insulation. [ABSTRACT FROM AUTHOR]

Published

2019

11. Facile fabrication of nanofibrous network reinforced hierarchical structured porous Si3N4-based ceramics based on Si-Si3N4 binary particle-stabilized foams.

Author

Ren, Bo, Liu, Jingjing, Huo, Wenlong, Gan, Ke, Lu, Yuju, Chen, Yugu, Wang, Lu, Yang, Jinlong, and Huang, Yong

Subjects

*CERAMICS, *ANNEALING of metals, *SINTERING, *ISOSTATIC pressing, *PARTIAL oxidation, *COMPRESSIVE strength, *COMPRESSIVE force

Abstract

Abstract A facile method for preparation of SiC nanofibrous network reinforced hierarchical structured porous Si 3 N 4 based ceramics via annealing Si-Si 3 N 4 binary particle-stabilized foam in coke bed is reported in this work for the first time. The atmosphere created by coke bed enables the fabrication of Si 3 N 4 based porous ceramics at 1450 °C without using sintering additives. As prepared specimens possess a relative high compressive strength due to the partial oxidation of Si 3 N 4 particles. This novel structure with three levels of hierarchy characterized by flexible SiC nanofibrous network, cell walls and unit cells can be characterized. The vaporization of silicon powder results in formation of Si(g), SiO(g) and allows subsequent generation of SiC nanofibrous network, leading to a considerable number of micro-pores on cell walls simultaneously. As-prepared porous ceramics contained 76.7% porosity and had compressive strength of 10.81 MPa. [ABSTRACT FROM AUTHOR]

Published

2019

12. Effect of zeta potential on properties of foamed colloidal suspension.

Author

Huo, Wenlong, Zhang, Xiaoyan, Gan, Ke, Chen, Yugu, Xu, Jie, and Yang, Jinlong

Subjects

*COLLOIDAL suspensions, *ZETA potential, *ISOELECTRIC point, *SURFACE active agents, *FOAM

Abstract

Abstract We reveal that zeta potential has a notable effect on properties of foamed suspension, which remains poorly explored. It is demonstrated low zeta potential is beneficial for foam stability, and the experimental results show that absolute value of zeta potential of 30–40 mV is the boundary between stable foams and unstable foams. High zeta potential above 40 mV gives rise to instability of foamed colloidal suspension, owing to strong interparticle repulsion force that prevents particles from forming a closely packed particle network at liquid/air interfaces. Besides, it is found that high zeta potential leads to low foamability of foamed colloidal suspension. It is also demonstrated herein that stable and uniform foams with thin and homogeneous-thickness wall without agglomerates can be prepared at the isoelectric point (IEP) using long-chain surfactant, which generates weak agglomerated particles that can be re-separated to monodisperse particles due to the steric hindrance effect of surfactant. [ABSTRACT FROM AUTHOR]

Published

2019

13. Enhanced mechanical properties and decreased thermal conductivity of porous alumina ceramics by optimizing pore structure.

Author

Liu, Jingjing, Ren, Bo, Zhu, Tianbin, Yan, Shu, Zhang, Xiaoyan, Huo, Wenlong, Chen, Yugu, and Yang, Jinlong

Subjects

*ALUMINUM oxide, *CERAMIC materials, *MECHANICAL behavior of materials, *THERMAL conductivity, *MICROSTRUCTURE

Abstract

In order to reduce thermal conductivity but to exhibit better mechanical properties of porous alumina ceramics (PACs), a novel approach, based on the modification of pore structures (i.e. mean pore size, micro-pore proportions and pore shape factor) by impregnation of alumina sol, is reported in the present work. The properties of as-impregnated samples were compared with commercial alumina hollowsphere bricks. Results show that impregnation of alumina sol in PACs has a positive influence on pore structures, leading to a superior strength and a lower thermal conductivity. In particular, when 8 wt% alumina sol solid content is impregnated, the crushing strength (35.3 MPa) and thermal conductivity (0.15 W/m K at 200 °C) of sample are much better than that of the commercial alumina hollowsphere bricks. This novel method for excellent PACs provides promising applications as insulating lining materials in the fields of industrial furnace. [ABSTRACT FROM AUTHOR]

Published

2018

14. Innovative application of PVA hydrogel for the forming of porous Si3N4 ceramics via freeze-thaw technique.

Author

Zhang, Xiaoyan, Huo, Wenlong, Yan, Shu, Chen, Yugu, Gan, Ke, Liu, Jingjing, and Yang, Jinlong

Subjects

*POLYVINYL alcohol, *HYDROGELS, *SILICON nitride, *CERAMICS, *FREEZE-thaw cycles

Abstract

The generation of PVA hydrogel through freeze-thaw technique has been utilized innovatively to complete the forming process of porous Si 3 N 4 ceramics in the present work. In comparison with gelcasting method, green body with comparable strength has been achieved by this novel forming process, which is owing to the strong function of PVA gel caused by the freeze-thaw cycles. Herein, Si 3 N 4 hollow spheres are employed as pore-forming agent in order to achieve closed pores. The morphology of green body illustrates that pores originate from both hollow spheres and the space occupied by ice crystals, and the latter gives rise to the increase of porosity around 10%. Studies on the mechanical, dielectric and thermal properties of porous Si 3 N 4 ceramics dependent on freeze-thaw cycle and freezing time have been performed. It is found that porous ceramics treated for freeze-thaw 2 cycles with freezing time of 24 h present excellent properties, which are promising to be applied as radome materials. [ABSTRACT FROM AUTHOR]

Published

2018

15. Temperature induced gelation of non–aqueous alumina suspension using oleic acid as dispersant.

Author

Yang, Jinlong, Gan, Ke, Li, Shiji, Gai, Yanjiao, Zhang, Zaijuan, Yan, Shu, Chen, Yugu, Zhang, Xiaoyan, Lu, Yuju, and Xu, Jie

Subjects

*THERMISTORS, *THERMAL stresses, *THERMOMETERS, *ALUMINUM oxide, *GELATION

Abstract

A novel temperature induced gelation method for alumina suspension using oleic acid as dispersant is reported. Non–aqueous suspension with high solid loading and low viscosity is prepared using normal octane as solvent. Influence of oleic acid on the dispersion of suspension was investigated. There was a well disperse alumina suspension with 1.3 wt% oleic acid. Influence of gelation temperature on the coagulation process and properties of green body was investigated. The sufficiently high viscosity to coagulate the suspension was achieved at −20 °C. The gelation temperature was controlled between the melting point of dispersant and solvent. The gelation mechanism is proposed that alumina suspension is destabilized by dispersant separating out from the solvent and removing from the alumina particles surface. The alumina green body with wet compressive strength of 1.07 MPa can be demolded without deformation by treating 53 vol% alumina suspension at −20 °C for 12 h. After being sintered at 1550 °C for 3 h, dense alumina ceramics with relative density of 98.62% and flexural strength of 371±25 MPa have been obtained by this method. [ABSTRACT FROM AUTHOR]

Published

2017