Your search keyword '"Liu, Jingjing"' showing total 14 results

1. Highly porous and mechanically robust Al2O3-based foams with self-wrinkled and rough aperture surfaces via binary colloidal self-assembly of nanoparticle/gelation network.

Author

Liu, Jingjing, Yang, Jinlong, Zhang, Jiyuan, Chen, Haiyang, and Kang, Shaojun

Subjects

*NANOPARTICLES, *POROUS materials, *FOAM, *ROUGH surfaces, *GELATION, *WRINKLE patterns, *SILICA nanoparticles

Abstract

Porous materials with wrinkled surfaces could have broad applications in catalysis and adsorption. However, designing cellular ceramics with similar structures is challenging. Herein, we demonstrated the binary colloidal self-assembly of γ-Al 2 O 3 nanoparticle/silica gelation network for constructing such materials. The competitive effect between volume shrinkage and surface bend during water evaporation of silica gel contributed to wrinkled aperture surface. During calcination, silica nanoparticles were highly active to react with alumina to form mullite nanocrystals, bringing about high compressive strength at low relative densities. After calcining at 1350 °C, resultant products with hierarchical structure exhibited an outstanding compressive strength of 4.2 MPa, a relatively high surface area of 7.23 m2/g at a porosity level of 83.3%. The current strategy provides a feasible and affordable approach for producing high performance ceramic foams towards practical application fields in catalysis and adsorption. [ABSTRACT FROM AUTHOR]

Published

2023

2. Low-temperature preparation of alumina-mullite porous ceramic via gelation-assisted dual-phasic nanoparticle stabilized foams.

Author

Ren, Bo, Kang, Shaojun, Liu, Jingjing, Wang, Enhui, and Hou, Xinmei

Subjects

*NANOPARTICLES, *CERAMICS, *OSTWALD ripening, *FOAM, *RAW materials, *BOEHMITE

Abstract

Preparation of ultralight ceramic foams via aqueous-based direct foaming method for practical application is a challenging task owing to Ostwald ripening of wet foam and unsatisfied mechanical strength of final products. To tackle these issues, the current work demonstrates the construction of alumina-mullite ceramic foams via gelation-assisted dual-phasic nanoparticle stabilized foams using boehmite sol and nanosilica as the raw materials. The gelation process of boehmite sol inhibits the Ostwald ripening and pore enlargement during drying. The highly active alumina powder derived from boehmite sol and nanosilica enables the reaction by forming mullite at 1200 °C. Consequently, the resultant products demonstrate a compressive of 3.9 MPa at a porosity level of 95.9 %, a bulk density of 0.18 g/cm3 and an ultralow thermal conductivity of 0.1043 W m−1 K−1 after firing at 1200 °C. The current strategy provides new insight for fabricating high-performance ceramic foams for multiple applications. [ABSTRACT FROM AUTHOR]

Published

2024

3. Ultralight and mechanically robust SiC foams with interconnected cellular architecture.

Author

Liu, Jingjing, Ren, Bo, Rong, Yedong, Lu, Yuju, Zhao, Yi, Wang, Lu, Xi, Xiaoqing, Yang, Jinlong, and Huang, Yong

Subjects

*COMPRESSIVE strength, *RAW materials, *URETHANE foam, *POROSITY, *FOAM, *MULLITE

Abstract

Engineering highly porous SiC foams with interconnected cellular architecture and satisfactory compressive strength for the practical applications remains a challenging task. In the current work, SiC foams bonded by in-situ formed mullite phase were fabricated via polyurethane foaming using boehmite sol-coated SiC powder as the raw material. The strategy in the current work endowed the resultant products with ultrahigh porosity, interconnected pore structure, and a robust mullite bonding phase among the SiC particles. The resulting products with this cellular architecture possessed a high porosity level of 88.5% and maintained a robust compressive strength of 2.56 MPa. Our results showed that as-prepared products are promising for practical applications in the filtration, adsorption and catalytic areas. [ABSTRACT FROM AUTHOR]

Published

2020

4. Mechanically robust ZrO2 foams with 3D reticular architecture prepared from chemical‐modified ZrO2 powder.

Author

Liu, Jingjing, Ren, Bo, Lu, Yuju, Rong, Yedong, Wang, Chao, Wang, Lu, Yang, Jinlong, and Huang, Yong

Subjects

*POWDERS, *COMPRESSIVE strength, *URETHANE foam, *FOAM, *FUNCTIONAL groups, *POROSITY

Abstract

Engineering mechanically robust ZrO2 foams with three‐dimensional (3D) reticular architecture and high porosity is extremely challenging. In current work, we presented an approach for constructing such cellular ceramics via a combined polyurethane foaming and chemical grafting method. Ester functional groups were chemically grafted on the ZrO2 powder surface to enhance its dispersibility. This approach caused the micron‐sized windows to assemble onto the cell wall of porous framework, contributing to 3D interconnected reticular architecture. The resulting products with such cellular architecture possessed a high porosity level of 89.2% and maintained an ultrahigh compressive strength of 8.5 MPa. Our results open up new opportunities for fabricating high‐performance ZrO2 foams toward practical applications. [ABSTRACT FROM AUTHOR]

Published

2020

5. Highly porous alumina cellular ceramics bonded by in-situ formed mullite prepared by gelation-assisted Al2O3–Si particle-stabilized foams.

Author

Liu, Jingjing, Ren, Bo, Rong, Yedong, Zhao, Yi, Wang, Lu, Lu, Yuju, Wang, Chao, Sang, Guolong, and Yang, Jinlong

Subjects

*FOAM, *MULLITE, *CERAMICS, *GELATION, *CHEMICAL bonds, *COMPRESSIVE strength, *COMPOSITE construction

Abstract

Engineering high performance cellular ceramics with both ultralow density and satisfactory compressive strength for practical applications still represents a grand challenge. Herein, alumina-based cellular ceramics bonded by in-situ formed mullite phase were constructed by Al 2 O 3 –Si-boehmite particle-stabilized foams. The gelation of boehmite sol improved the stability and harnessed the deformation of dried Al 2 O 3 –Si composite foam. The oxidation of silicon and further generation of in-situ mullite phase enhanced the chemical bond between alumina particles on cell walls, resulting in the superior mechanical properties. As an exemplar, the resulting cellular ceramic possessed the robust compressive strength of 2.26 MPa at a high porosity of 87.8%. The gelation-assisted Al 2 O 3 –Si particle-stabilized foams provide a facile and convenient strategy for construction of composite ceramic foams with high porosity and robust strength. [ABSTRACT FROM AUTHOR]

Published

2020

6. Hierarchical cellular scaffolds fabricated via direct foam writing using gelled colloidal particle‐stabilized foams as the ink.

Author

Ren, Bo, Liu, Jingjing, Wang, Yali, Chen, Yugu, Gan, Ke, Rong, Yedong, and Yang, Jinlong

Subjects

*TISSUE scaffolds, *CATALYST supports, *INK, *COMPRESSIVE strength, *FOAM, *THERMAL insulation

Abstract

Hierarchical cellular architectures hold great potential in a vast range of applications due to their superior mechanical properties and multifunctionality. In the present work, hierarchical structures composed of porous struts patterned in the form of quadrangular and triangular honeycombs were fabricated via direct foam writing (DFW) using colloidal particle‐stabilized Al2O3‐MgO‐SiO2 foams as the ink. Hydration process of MgO and subsequent formation of colloidal Mg(OH)2 network endowed the foam ink with viscoelasticity and high storage modulus. The resulting honeycombs with ultrahigh overall porosity (95.3%) and robust compressive strength (2.5 MPa) can be readily fabricated by DFW. The current work exhibits a significant step toward the scalable production of cellular ceramics with hierarchical architecture for various applications, including tissue scaffolds, catalyst supports, thermal insulation, and lightweight structures. [ABSTRACT FROM AUTHOR]

Published

2019

7. 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

8. Novel design of alumina foams with three‐dimensional reticular architecture for effective high‐temperature particulate matter capture.

Author

Liu, Jingjing, Ren, Bo, Chen, Yugu, Lu, Yuju, Zhang, Shuhao, Rong, Yedong, and Yang, Jinlong

Subjects

*PARTICULATE matter, *CERAMIC materials, *FOAM, *ARCHITECTURE, *POLYURETHANES, *CARBON-black

Abstract

Ceramic foams with extensive interconnected pores have great application potential in high‐temperature particulate matter (PM) capture. Considering that there are still challenges to synthesize ceramic foams with efficient filtration, a novel hierarchical‐structured alumina foam with three‐dimensional (3D) reticular architecture has been fabricated via combining chemical grafting pore‐forming agent and polyurethane (PU) foaming technology. Carbon black is grafted with carbamate functional groups in order to enable a better dispersion in highly viscous PU. Submicrometer and micrometer‐sized pores on the cell walls are observed in hierarchical‐structured ceramic foams. The resulting alumina foam exhibits 95.2% removal efficiency for PM particles and low pressure drop of only 50 Pa when grafted carbon black content is 3 wt%. This filtration performance is much higher than that of existing ceramic materials. These features, combined with our experimental design strategy, provide a new insight to design high‐temperature PM filtration materials with durable high performance. [ABSTRACT FROM AUTHOR]

Published

2019

9. Ultrahigh‐strength alumina ceramic foams via gelation of foamed boehmite sol.

Author

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

Subjects

FOAM, COLLOIDS, ALUMINUM oxide, COMPRESSIVE strength, GRAIN size, GELATION

Abstract

Ceramic foams with significant porosity and robust mechanical properties have received extensive attentions. However, it is still difficult to achieve excellent compressive strength at high porosity levels. In this work, a gelation of foamed boehmite sol method is proposed to settle this issue. The technological parameters during preparation process are systematically investigated. As‐prepared alumina ceramic foams possess unprecedentedly high compressive strength of 34.1‐89.1 MPa at high porosity levels of 66.0%‐87.2%, which is attributed to the present of hierarchical pore structure, small grain size and pore size. This work demonstrates a facile and novel method for the fabrication of high‐performance alumina ceramic foams toward practical applications. [ABSTRACT FROM AUTHOR]

Published

2019

10. Highly porous barium strontium titanate (BST) ceramic foams with low dielectric constant from particle‐stabilized foams.

Author

Huo, Wenlong, Chen, Yugu, Zhang, Zaijuan, Liu, Jingjing, Yan, Shu, Wu, Jia‐Min, Zhang, Xiaoyan, and Yang, Jinglong

Subjects

BARIUM strontium titanate, POROUS materials, CERAMIC materials, FOAM, PERMITTIVITY, PROPYL gallate

Abstract

Abstract: A novel method for fabrication of highly porous barium strontium titanate (BST) ceramic foams based on particle‐stabilized foaming method was developed for the first time, in which propyl gallate (PG) was employed as BST particle modifier. The results showed that the stability of wet BST foams closely depends on the pH value and PG concentration, which could be explained by the adsorption behavior of PG on BST particle surface. BST ceramic foams with dense, uniform, and closed pore and defect‐free wall were obtained. The pore size and porosity can be well controlled by adjusting solid loading and sintering temperature. It was revealed that not only sintering temperature but also solid loading significantly influenced the growth of BST grain. The BST ceramic foams exhibited high porosity in the range of 81%‐95%, low dielectric constant in the range of 47‐150, and low dielectric loss below 0.0025. The BST ceramic foams with higher porosity presented a tendency of lower dielectric constant and the fitting results indicated that the natural logarithm of dielectric constant was linear correlated with porosity. [ABSTRACT FROM AUTHOR]

Published

2018

11. Green synthesis of high porosity waste gangue microsphere/geopolymer composite foams via hydrogen peroxide modification.

Author

Yan, Shu, Zhang, Fanyong, Liu, Jingjing, Ren, Bo, He, Peigang, Jia, Dechang, and Yang, Jinlong

Subjects

*HYDROGEN peroxide, *FOAM, *MICROSPHERES, *POROSITY, *SURFACE active agents, *CELL size

Abstract

A novel coal gangue microsphere/geopolymer composite foam (CGM/KGP) was firstly synthesized by adding coal gangue microspheres (CGM) into geopolymer foams. Effects of coal gangue microspheres, foaming agent (H 2 O 2) and stabling agent (SDS) on the microstructure, pore structure and mechanical properties of CGM/KGPs were investigated. The CGM/KGPs were composed of amorphous phase with some peaks of microshpheres. CGMs were dispersed and bonded well with the geopolymer matrix. Total and open porosity of M4H5S3 samples reached maximum value of 88.3 vol% and 80.5 vol%, respectively. Compression strength of CGM/KGPs reached the maximum value of 5.70 ± 0.88 MPa for the M4H1S3 sample. The increasing addition of H 2 O 2 led to the decrease strength of pure foams and CGM/KGPs. Moderate surfactant (SDS, 3 wt%) contributed to the formation of homogeneous cell size and porosity in the composite foams. The novel geopolymer composite foams have potential applications in membrane supports, catalysis and filtration fields. Image 1098 • Novel hybrid CGM/KGP foams were achieved by simultaneous hydrogen peroxide with microspheres. • Microstructure of the CGM/KGP foams were amorphous structure with high porosity. • CGM/KGPs have potential application in membrane supports, catalysis and filtration fields. [ABSTRACT FROM AUTHOR]

Published

2019

12. 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

13. Ceramic foams with micron/sub-micron sized porous structure for efficient high-temperature particulate matter capture.

Author

Zhang, Boran, Ren, Fuqiang, Wang, Chao, Liu, Jingjing, Zhao, Yi, He, Ge, and Yang, Jinlong

Subjects

*FOAM, *CERAMICS, *CRYSTAL filters, *PRESSURE drop (Fluid dynamics), *AIR filters, *KAOLIN, *PARTICULATE matter

Abstract

Constructing high-performance air filters for high-temperature particulate matter (PM) removal is of great importance but remains challenging. Here we demonstrate the ceramic foam-based filters via polyurethane (PU) foaming using diatomite and kaolin powder as the starting materials. Diatomite was grafted by dodecanedioic acid (DA) to improve the dispersity in the PU slurry. The calcined products demonstrated a hierarchical pore structure with multiple well-controlled micron-sized window pores on the cell wall of the sub-micron bubble. The resulting products exhibited a high removal efficiency (96.3%) at a pressure drop of 33 Pa. This research showed that as-prepared ceramic foams can be potentially used as new high-temperature filters for high-temperature PM removal. [ABSTRACT FROM AUTHOR]

Published

2022

14. 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