Your search keyword '"Liu Shiying"' showing total 10 results

1. Thermoelectric properties of Bi2Te3 films with low-angle grain boundaries formed through high pulse current density

Author

Lan, Mingdi, Sun, Shang, Liu, Shiying, Li, Guojian, Sun, Xiao, and Wang, Qiang

Published

2024

2. Generation and characterization of a human iPSC line and gene-corrected isogenic line derived from a patient with a CELF2 gene mutation

Author

Hua, Michelle, Williams, Laura, Burns, Kaylan, Liu, Shiying, Ellis, James, Innes, A. Micheil, McPherson, Melissa, and Yang, Guang

Published

2024

3. Tunable magnetic properties in evaporated Co–Sm/Fe–Sm bilayer films by crystalline states of under-layer and high magnetic field.

Author

Liu, Shiying, Lu, Fangxu, Shao, Yan, Wang, Chao, and Wang, Zhanjie

Subjects

*MAGNETIC properties, *MAGNETIC fields, *MAGNETIC structure, *MAGNETIC field effects, *MAGNETIC films, *FLUX pinning

Abstract

Bilayer is an effective structure to enhance magnetic properties of films. This study employs high magnetic field (HMF) and amorphous Fe–Sm under-layer to tune the magnetic properties of evaporated Co–Sm/Fe–Sm bilayer films. Various analysis methods are used to explore the relation of microstructure evolution under above conditions with magnetic performance. The results show that both the amorphous Fe–Sm under-layer and the HMF can decrease surface roughness. Further, the HMF exhibits other effects that reduces column size, increases interplanar spacing and affects interface at atomic scale. The structural variation has effect on magnetic properties of bilayer films. The amorphous Fe–Sm under-layer increases magnetization, coercivity and squareness through changing the amount of non-magnetic structure at atomic scale. Meanwhile, the HMF decreases coercivity by changing pinning via the interface variation. Both the HMF and amorphous under-layer have no influence on the anisotropy of bilayer films. These results present an effective method to tune the magnetic properties of films through amorphous under-layer and HMF. • Amorphous FeSm under-layer has effect on microstructure and magnetic performance. • High magnetic field improves magnetization by affecting non-magnetic structure. • High magnetic field decreases coercivity by changing interface pinning. • Effect of high magnetic field on squareness is smaller than that of amorphous layer. [ABSTRACT FROM AUTHOR]

Published

2024

4. Carbon inequality in residential buildings: Evidence from 321 Chinese cities.

Author

Chen, Liu, Liu, Shiying, Cai, Weiguang, Chen, Rundong, Zhang, Jinbo, and Yu, Yanhui

Subjects

CITIES & towns, DWELLINGS, CLIMATIC zones, CARBON emissions, GINI coefficient, REGIONAL economic disparities

Abstract

All human beings contribute to climate change; however, their contributions are not equal. Using China as an example, the core objective of this study is to explore the city-level carbon inequality of residential buildings from 2015 to 2020 combined Theil index and Gini coefficient. The outcomes indicate that: (1) Total residential buildings' carbon emissions in 321 Chinese cities increased from 987.81 million tons (Mt) in 2015 to 1161.70 Mt. in 2020; the leading five cities that own the largest carbon emissions are Beijing, Tianjin, Shanghai, Shenyang, and Harbin in 2020. (2) Among eight major economic zones of China, the highest residential buildings' carbon emission per capita and residents' disposable income per capita are the Northeast Economic Zone and Eastern Coastal Economic Zone, respectively. (3) Both the Theil index and Gini coefficient show that the overall carbon inequality is higher than income inequality; the Theil index decomposition indicates that city-level carbon inequality has declined; the key forces of carbon emission per capita and disposable income per capita inequality are inter-regional inequality (contribution rate: 55%–63%) and intra-regional inequality (contribution rate: 59%–63%), respectively. (4) Moreover, regarding income earners during 2015–2020 period, the top 10% of 321 cities occupy about 33% in the total national residential buildings' carbon emissions; the medium 40% of cities account for about 42% in total carbon emissions; in contrast, the bottom 50% of cities represent only about 25% of the total carbon emissions. These discoveries emphasize the necessity for the Chinese government to pay more attention to city-level residential building carbon emissions to track advances toward residents' sustainable lifestyles. • The city-level features of carbon emissions and resident incomes were analyzed. • Carbon and income inequality via Theil index and Gini coefficient were compared. • Carbon emission per capita inequality's core force via Theil index was identified. • Carbon inequality's disparities in economic zones and climate zones were discussed. [ABSTRACT FROM AUTHOR]

Published

2024

5. Investigating the high-temperature and self-lubricating properties of TiAlSiCN hard coating coordinated using double amorphous phases.

Author

Li, Xianliang, Li, Guojian, Liu, Shiying, Lan, Mingdi, Sun, Shang, and Wang, Qiang

Subjects

*SURFACE coatings, *WEAR resistance, *TITANIUM alloys, *HIGH temperatures, *MAGNETRON sputtering, *FRICTION

Abstract

In this work, the competitive relationship between the double amorphous phases is systematically investigated to increase the high-temperature wear resistance of the self-lubricating TiAlSiCN coating. These double amorphous phases combine the SiN x phase with high-temperature resistance and the C-related phase with a low friction coefficient. An increase in the Si content facilitates the change in the phase composition. The resultant coating exhibits an adhesion strength of 153 N, a friction coefficient of 0.24 and a hardness of 25.24 GPa upon generation of the TiAlN(C), the SiN x and the C-related phase. In this case, the TiAlSiCN coating achieves long-term self-lubrication at high temperatures with the titanium alloy friction pair. This mechanism stems from the SiN x phase replacing the portion of the easily oxidized amorphous C-related phase, which yields an enhanced high-temperature wear resistance. The cutting distance of this TiAlSiCN is 120% higher than that of the TiAlCN during the high-speed cutting of the titanium alloy. This outcome provides an effective solution for high-temperature applications of self-lubricating coatings. • Long-term self-lubricating is remained in TiAlSiCN coating by optimal Si content. • Synergistic effect of amorphous SiN x and C-related phase is solved in TiAlSiCN. • Tool life of TiAlSiCN improved 225% by comparing with that of TiAlN. [ABSTRACT FROM AUTHOR]

Published

2024

6. Improved thermal properties and CMAS corrosion resistance of high-entropy RE zirconates by tuning fluorite-pyrochlore structure.

Author

Tian, Yue, Zhao, Xiuyi, Sun, Zhipei, Liang, Yongqi, Xiao, Guozheng, Wang, Chao, Liu, Shiying, Liu, Feng, Lu, Xuefeng, Wu, Yusheng, and Wang, Zhanjie

Subjects

*PYROCHLORE, *CORROSION resistance, *THERMAL properties, *ZIRCONATES, *THERMAL conductivity, *PHONON scattering, *THERMAL barrier coatings

Abstract

The order-disorder transition (ODT) of RE zirconate (RE 2 Zr 2 O 7) has received much attention due to its potential applications in the design of thermal barrier coatings (TBCs). A series of high entropy RE zirconates (RE = La, Sm, Gd, Er and Lu) were designed and synthesized in order to regulate the fluorite-pyrochlore phases, and to investigate the effect of phase composition on the microstructures and performances. The results showed that the sintering temperature, as well as equivalent ion radius, played an important role in regulating the phase transformation of fluorite-pyrochlore. The coexistence of pyrochlore-fluorite phases not only can result in the decrease in grain size but also increased the lattice strain of each phase, thereby enhancing the phonon scattering and contributing to the reduction in the thermal conductivity. The CMAS corrosion resistance was mainly related to phase compositions, and the thicknesses of reaction layer decreased gradually with the increasing fluorite phase content. The results will provide theoretical guidance for the microstructural design of high entropy RE zirconates as next generation TBC materials in future. [ABSTRACT FROM AUTHOR]

Published

2024

7. Study about heat treatment on microstructure, electrical conductivity and mechanical properties of Al-1Si-0.6Mg-0.2Fe alloy.

Author

Liu, Houyun, Liu, Jie, Wang, Yan, Liu, Shiying, Wang, Jun, Wang, Yongxiao, Li, Xinghui, Li, Hui, Cui, Hongwei, Pan, Yaokun, Feng, Rui, and Cui, Xiaoli

Subjects

*HEAT treatment, *ELECTRIC conductivity, *TENSILE strength, *ELECTRON transport, *MICROSTRUCTURE

Abstract

In this study, the electrical conductivity (EC) and mechanical properties of extruded state Al-1Si-0.6Mg-0.2Fe alloy (ES-Alloy) are enhanced through T6 heat treatment, and the underlying mechanisms are analyzed in conjunction with model calculations. Results demonstrate that the optimal heat treatment process for the ES-Alloy is 550 °C / 2 h + 230 °C / 16 h. Through the heat treatment process, the alloy's EC and ultimate tensile strength are 57.0% IACS and 247.6 MPa, respectively, which are improved by 4.6% and 54.8%, respectively. For ES-Alloy, after heat treatment, owing to reversion and recrystallization, the average grain size of the alloy is 175.9 μm and becomes 6.93 times larger. Combined with theoretical calculation, the contribution of grain boundary strengthening to the alloy's strength is only reduced by 9.1 MPa. However, the reduction of grain boundary area reduces the scattering of free electrons during the transport process, which is beneficial to improving EC. Moreover, by modifying the heat treatment parameters, nanoscale Mg 2 Si and large-size AlFeSi second phases present in the alloy keep a favorable lattice match with the Al matrix, proving that this makes the main contribution to the alloy's strength. The microstructures give consideration for both the high efficiency of electron transport and the enhancement of mechanical properties. So, it is advantageous for the improvement of EC and mechanical properties. • 550 °C/2 h + 230 °C/16 h balances alloy's electrical conductivity and mechanical properties. • Second phase strengthening contributes more to alloy's strength than grain boundary. • High angle grain boundary and β" phase are useful to improve electrical conductivity. [ABSTRACT FROM AUTHOR]

Published

2024

8. Investigation on the relation of microstructures and CMAS corrosion resistance of high entropy RE disilicates.

Author

Xiao, Guozheng, Shen, Qiyu, Tian, Yue, Wang, Chao, Lu, Xuefeng, Li, Liuyuan, Liu, Shiying, Wu, Yusheng, and Wang, Zhanjie

Subjects

*CORROSION resistance, *ENTROPY, *MICROSTRUCTURE, *PRECIPITATION (Chemistry), *LOW temperatures, *YTTERBIUM, *BIOACTIVE glasses, *CERAMICS

Abstract

Three kinds of high entropy (Y 0.25 Sc 0.25 Er 0.25 Yb 0.25) 2 Si 2 O 7 , (Y 0.2 Sc 0.2 Er 0.2 Yb 0.2 Lu 0.2) 2 Si 2 O 7 and (Y 0.2 Sc 0.2 Er 0.2 Yb 0.2 Gd 0.2) 2 Si 2 O 7 were designed and synthesized in order to investigate the relation of microstructures and CMAS corrosion resistance. At low temperature of 1300 °C, lattice distortion played a crucial role in resistance to CMAS corrosion, and larger lattice distortion contributed to CMAS corrosion resistance. However, the corrosion behavior at 1500 °C was related to the equivalent ionic radius and RE species. The smaller equivalent ionic radius tended to promote the re-precipitation of high entropy RE disilicate in residual CMAS glass rather than apatite. The results will provide theoretical guidance for the microstructural design of high entropy RE disilicate and selection of RE elements in future. • High entropy ceramics were synthesized by solid state reaction method. • (Y 0.2 Sc 0.2 Er 0.2 Yb 0.2 Gd 0.2) 2 Si 2 O 7 ceramics had a maximum lattice distortion. • (Y 0.2 Sc 0.2 Er 0.2 Yb 0.2 Gd 0.2) 2 Si 2 O 7 presented a best CMAS corrosion resistance. [ABSTRACT FROM AUTHOR]

Published

2024

9. High-temperature resistance and self-lubricating TiAlTaCN nanocomposite hard coating by synergistic interaction of TiAlN(C) and TaN(C) phases.

Author

Li, Xianliang, Li, Guojian, Lü, Wenzhang, Liu, Shiying, Deng, Jiwu, and Wang, Qiang

Subjects

*PHASE transitions, *NANOCOMPOSITE materials, *ALUMINUM oxide, *SURFACE coatings, *MAGNETRON sputtering

Abstract

The self-lubricating TiAlTaCN coating with high-temperature resistance above 800 °C is developed using magnetron sputtering. This mechanism stems from the TaN phase is easily oxidized to form a protective Ta 2 O 5 that compensates for the insufficient antioxidant capacity of Al 2 O 3. Moreover, the TaC phase, being resistant to oxidation, contributes to achieving the self-lubrication effect with amorphous C-related phases. The cutting distance of the TiAlTaCN is 250% greater than that of the TiAlCN during the high-speed cutting of titanium alloy. These results reveal the oxidation mechanism of different carbon nitrides and provide a new solution for the self-lubricating coatings applied at high temperatures. • A new high-temperature resistant (800 °C) self-lubricating (COF=0.27) TiAlTaCN nanocomposite coating was prepared. • The Ta addition inhibits the phase transition and increases the high thermal stability from 600 °C to 1000 °C. • The wear rate of the TiAlTaCN is 38.7% lower than that of the TiAlCN at 600 °C. • The cutting distance of the TiAlTaCN is 250% higher than the TiAlCN during the high-speed cutting of titanium alloy. [ABSTRACT FROM AUTHOR]

Published

2024

10. Improved thermal properties and CMAS corrosion resistance of rare-earth monosilicates by adjusting the configuration entropy with RE-doping.

Author

He, Yuxuan, Xiao, Guozheng, Wang, Chao, Lu, Xuefeng, Li, Liuyuan, Liu, Shiying, Wu, Yusheng, and Wang, Zhanjie

Subjects

*CORROSION resistance, *THERMAL properties, *ENTROPY, *THERMAL conductivity, *THERMAL expansion, *TERBIUM, *RARE earth metal alloys

Abstract

The novel rare earth monosilicates (xRE 1/x) 2 SiO 5 (RE=Yb, Tm, Er, Y, Dy and Tb, x = 2–6) were prepared in order to establish the relationship between configurational entropy and lattice distortion, and the effect of configurational entropy on their properties was investigated. The results showed that the lattice distortion of (xRE 1/x) 2 SiO 5 increased gradually with the increase of configurational entropy, but the multi-principal component solid solution tended to form a highly symmetrical crystal structure when the configurational entropy was large enough, thus inhibiting the lattice distortion. (5RE 1/5) 2 SiO 5 had a maximum lattice distortion, which leaded to a relatively low thermal conductivity and coefficient of thermal expansion, and good CMAS corrosion resistance. • The effect of configurational entropy on microstructure and properties was investigated. • (5RE 0.2) 2 SiO 5 ceramic had a maximum lattice distortion. • (5RE 0.2) 2 SiO 5 ceramic presented the relatively good thermal properties and CMAS corrosion resistance. [ABSTRACT FROM AUTHOR]

Published

2024