Your search keyword '"Yaozha Lv"' showing total 8 results

1. Size-Dependent Alloying Ability of Immiscible W-Cu Bimetallic Nanoparticles: A Theoretical and Experimental Study

Author

Hongbo Zhang, Tao Liu, Siqi Zhao, Zhanyuan Xu, Yaozha Lv, Jinglian Fan, and Yong Han

Subjects

nanoscale size effect, alloying ability, immiscible W–Cu systems, bimetallic nanoparticles, bond energy model, Chemistry, QD1-999

Abstract

The preparation of alloyed bimetallic nanoparticles (BNPs) between immiscible elements is always a huge challenge due to the lack of thermodynamic driving forces. W–Cu is a typical immiscible binary system, and it is difficult to alloy them under conventional circumstances. Here, we used the bond energy model (BEM) to calculate the effect of size on the alloying ability of W–Cu systems. The prediction results show that reducing the synthesis size (the original size of W and Cu) to less than 10 nm can obtain alloyed W–Cu BNPs. Moreover, we prepared alloyed W50Cu50 BNPs with a face-centered-cubic (FCC) crystalline structure via the nano in situ composite method. Energy-dispersive X-ray spectroscopy (EDS) coupled with scan transmission electron microscopy (STEM) confirmed that W and Cu are well mixed in a single-phase particle, instead of a phase segregation into a core-shell or other heterostructures. The present results suggest that the nanoscale size effect can overcome the immiscibility in immiscible binary systems. In the meantime, this work provided a high-yield and universal method for preparing alloyed BNPs between immiscible elements.

Published

2021

2. High rate-performance supercapacitors based on nitrogen-doped graphitized carbon nanotube networks in situ grown on 316L stainless steel as binder-free electrodes

Author

Rui Lei, Xuetao Hu, Xingxing Li, Renzhe Lu, Zhengyu Liu, Xianyao Wei, Shengjiang Shi, Yaozha Lv, Hua Zhang, Yu Zhang, and Honghong Yang

Subjects

Materials Chemistry, General Chemistry, Catalysis

Abstract

Heteroatom-doped carbon nanotubes are considered as promising materials for supercapacitors because of their prominent contributions in terms of faradaic capacitance and electron donor capability.

Published

2023

3. Highly oxidation-resistant Ti-Mo alloy with two-scale network Ti5Si3 reinforcement

Author

Yaozha Lv, Chi Zhang, Qiong Lu, Hongbo Zhang, Peizhong Feng, Wei Chen, Zhanyuan Xu, and Jinglian Fan

Subjects

Materials science, Polymers and Plastics, Mechanical Engineering, Composite number, Metals and Alloys, Oxide, Spark plasma sintering, chemistry.chemical_element, Temperature cycling, chemistry.chemical_compound, chemistry, Mechanics of Materials, Materials Chemistry, Ceramics and Composites, Thermal stability, Surface layer, Composite material, Tin, Layer (electronics)

Abstract

There is keen interest in using Ti alloys as lightweight structural materials for aerospace and automotive industries. However, a long-standing problem for these materials is their poor oxidation resistance. Herein, we designed and fabricated a Ti5Si3 reinforced Ti-4(wt.%)Mo composite with two-scale network architecture by low energy milling and spark plasma sintering. It displays superior oxidation resistance at 800°C owing to the in-situ formation of a multi-component surface layer. This oxide layer has a dense grain size gradient structure that consists of an outer TiO2 layer and an inner SiO2-padding-TiO2 layer, which has remarkable oxidation resistance and thermal stability. Furthermore, it was revealed that the hitherto unknown interaction between Ti5Si3 reinforcement and nitrogen during oxidation would contribute to the formation of a TiN nano-twin interface layer, which accommodates the thermal mismatch strain between the oxide layer and matrix. This, along with high adhesion, confers excellent thermal cycling life with no cracking or spallation during long-term oxidation. In this regard, the secure operating temperature of this new composite can be increased to 800°C, which provides a design pathway for a new family of Ti matrix composites for high-temperature applications.

Published

2022

4. High temperature oxidation behavior of MoSi2–Al2O3 composite coating on TZM alloy

Author

Zhanggen Liu, Wei Li, Jinglian Fan, YaoZha Lv, Zhenwei Wang, and Xiaojun Zhao

Subjects

Process Chemistry and Technology, Materials Chemistry, Ceramics and Composites, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials

Published

2022

5. Size-Dependent Alloying Ability of Immiscible W-Cu Bimetallic Nanoparticles: A Theoretical and Experimental Study

Author

Jinglian Fan, Yaozha Lv, Tao Liu, Yong Han, Siqi Zhao, Zhanyuan Xu, and Hongbo Zhang

Subjects

bimetallic nanoparticles, Materials science, General Chemical Engineering, nanoscale size effect, Alloy, Nanoparticle, alloying ability, engineering.material, bond energy model, Article, Chemistry, Chemical engineering, Phase (matter), Nano, engineering, Particle, immiscible W–Cu systems, General Materials Science, Binary system, Bond energy, Bimetallic strip, QD1-999

Abstract

The preparation of alloyed bimetallic nanoparticles (BNPs) between immiscible elements is always a huge challenge due to the lack of thermodynamic driving forces. W–Cu is a typical immiscible binary system, and it is difficult to alloy them under conventional circumstances. Here, we used the bond energy model (BEM) to calculate the effect of size on the alloying ability of W–Cu systems. The prediction results show that reducing the synthesis size (the original size of W and Cu) to less than 10 nm can obtain alloyed W–Cu BNPs. Moreover, we prepared alloyed W50Cu50 BNPs with a face-centered-cubic (FCC) crystalline structure via the nano in situ composite method. Energy-dispersive X-ray spectroscopy (EDS) coupled with scan transmission electron microscopy (STEM) confirmed that W and Cu are well mixed in a single-phase particle, instead of a phase segregation into a core-shell or other heterostructures. The present results suggest that the nanoscale size effect can overcome the immiscibility in immiscible binary systems. In the meantime, this work provided a high-yield and universal method for preparing alloyed BNPs between immiscible elements.

Published

2021

6. Highly Anti-Oxidized Ti-4Mo Alloy With Two-Scale Network Architectured Ti 5Si 3 Reinforcement

Author

Peizhong Feng, Qiong Lu, Chi Zhang, Wei Chen, Yaozha Lv, Hongbo Zhang, Jinglian Fan, and Zhanyuan Xu

Subjects

chemistry.chemical_compound, Materials science, chemistry, Oxide, Mixed oxide, chemistry.chemical_element, Titanium alloy, Spark plasma sintering, Surface layer, Temperature cycling, Composite material, Tin, Layer (electronics)

Abstract

Titanium alloys are desirable for applications in advanced hypersonic aircraft engines and gas turbines, but currently few materials can satisfy the associated high temperature oxidation requirements. Herein, we designed and fabricated a Ti5Si3 reinforced Ti-4Mo composite with a two-scale network architecture by low energy milling and spark plasma sintering. It displays superior oxidation resistance at 800°C owing to the in-situ formation of a multi-component surface layer. This oxide layer has been revealed to have a dense grain size gradient structure that consists of an outer TiO2 oxide layer and an inner TiO2 and SiO2 mixed oxide layer with a core-shell structure, which has remarkable oxidation resistance and thermal stability. Furthermore, it was revealed that the hitherto unknown interaction between Ti5Si3 reinforcements and nitrogen during oxidation would contribute to the formation of a TiN nano-twin interface layer, which accommodates the thermal mismatch strain between oxide layer and matrix. This along with high adhesion confers excellent thermal cycling life with no cracking or spallation during long term oxidation. In this regard, the secure operating temperature can be increased to 800°C, which can provide a design pathway for a new family of titanium matrix composites for high-temperature applications.

Published

2021

7. Microstructure evolution and tensile properties of as-rolled Ti-Mo-Si composite

Author

Qiong Lu, Yaozha Lv, Chi Zhang, Shuai Jiang, and Jinglian Fan

Subjects

Mechanics of Materials, Mechanical Engineering, Materials Chemistry, Metals and Alloys

Published

2022

8. Microstructure and texture evolution in warm-rolled fine-grained tungsten

Author

Zhiyuan Du, Yaozha Lv, Jinglian Fan, Lei Ye, Yuan Li, Pengfei Li, and Yongqi Lv

Subjects

Materials science, chemistry, Metallurgy, chemistry.chemical_element, Sintering, Grain boundary, General Medicine, Texture (crystalline), Tungsten, Pole figure, Microstructure, Grain size, Intensity (heat transfer)

Abstract

Fine-grained tungsten was prepared by sintering nano‑tungsten powder and its properties was further improved by warm rolling in the paper. And the microstructure and texture evolution of fine-grained tungsten under different rolling reduction was mainly investigated. Detailed microstructure characterizations under different rolling reduction stages showed a large number of sub-grain structures appeared in the fine-grained rolling tungsten grains, which increases the grain boundary area. Quantitative texture analysis showed that the rolled fine-grained tungsten had a typical BCC texture, the overall texture strength was enhanced after 50% RR and the texture intensity of grains larger than the average grain size was stronger than that of the whole grains, especially in the center of {111} pole figure. Warm rolling of fine-grained tungsten strongly affects the mechanical properties of tungsten, such insights in warm-rolled tungsten are valuable for an understanding of their performance as potential plasma-facing materials in future fusion reactors.

Published

2021