Your search keyword '"CHEN Liangxian"' showing total 4 results

1. Small-angle X-ray scattering performances of single crystal and polycrystalline diamond windows in a heated environment.

Author

Tu, Juping, Liu, Jinlong, Yao, Lei, Mo, Guang, Chen, Liangxian, Wei, Junjun, and Li, Chengming

Subjects

SINGLE crystals, SMALL-angle X-ray scattering, DIAMOND crystals, X-ray scattering, CHEMICAL vapor deposition, COHERENT scattering, ATOMIC clusters, CRYSTAL grain boundaries

Abstract

The demand of small-angle x-ray scattering (SAXS) windows for in-situ characterization of materials nano-structures in a heated vacuum environment has been increased dramatically. High-quality diamond prepared by chemical vapor deposition (CVD) has become the preferred window material due to its excellent optical and mechanical properties. However, impurities and defects in diamonds may lead to the strong X-ray scattering especially in the heating process, affecting the testing accuracy of the object. In this work, single-crystal diamond (SCD) and polycrystalline diamond (PCD) films with different quality were prepared, and their SAXS properties were investigated at room temperature and heating under vacuum. The results show that the scattering intensity of the undoped high-quality SCD is small and uniform, while that of the SCD window doped with a small amount of nitrogen increases, mainly due to the nitrogen atoms and vacancy clusters scattering. While for the PCDs, the grain boundaries and the dark features lead to strong scattering background. As the temperature rises from room temperature to 280 °C, although the phonon vibration of diamonds exhibits the obvious temperature dependence, the coherent scattering of diamonds with X-ray hardly changes, indicating no new scatterers with the changed gyration radius were generated in the heating process. SCD and PCD windows were successfully applied in an in-situ heating SAXS cell. [ABSTRACT FROM AUTHOR]

Published

2022

2. The Interface and Mechanical Properties of a CVD Single Crystal Diamond Produced by Multilayered Nitrogen Doping Epitaxial Growth.

Author

Zhao, Yun, Li, Chengming, Liu, Jinlong, An, Kang, Yan, Xiongbo, Hei, Lifu, Chen, Liangxian, Wei, Junjun, and Lu, Fanxiu

Subjects

SINGLE crystals, MULTILAYERED thin films, DIAMOND crystals, CHEMICAL vapor deposition, X-ray topography, BUFFER layers, MICROWAVE plasmas, EPITAXY

Abstract

In the present investigation, a nitrogen-doped multilayer homoepitaxial single crystal diamond is synthesized on a high-pressure high temperature (HPHT) Ib-type diamond substrate using the microwave plasma chemical vapor deposition (MPCVD) method. When 0.15 sccm of nitrogen was added in the gas phase, the growth rate of the doped layer was about 1.7 times that of the buffer layer, and large conical and pyramidal features are formed on the surface of the sample. Raman mapping and photoluminescence imaging of the polished cross sectional slice shows a broadband emission, with a characteristic zero phonon line (ZPL) at 575 nm in the doped layers, and large compressive stress was formed in the nitrogen-doped layers. X-ray topography shows that the defects at the interface can induce dislocation. The pyramid feature is formed at the defect, and more nitrogen-related defects are formed in the pyramid region. Thin nitrogen-doped multilayers were successfully prepared, and the thickness of the nitrogen-doped and buffer layers was about 650 nm each. The indentation measurements reveal that the thin nitrogen-doped multilayers are ultra-tough (at least ~22 MPa m1/2), compared to the Ib-type HPHT seed substrate (~8 MPa m1/2) and the unintentionally doped chemical vapor deposition (CVD) single crystal diamond (~14 MPa m1/2). [ABSTRACT FROM AUTHOR]

Published

2019

3. C+ ion implanted single crystal diamond with amorphous surface for efficient oxygen evolution catalysis.

Author

Tu, Juping, Wang, Yong, He, Jian, Liu, Jinlong, Jia, Baorui, Chen, Liangxian, Wei, Junjun, and Li, Chengming

Subjects

*SINGLE crystals, *DIAMOND surfaces, *HYDROGEN evolution reactions, *CARBON-based materials, *ION implantation, *DIAMOND films, *CATALYSIS, *DIAMOND crystals

Abstract

Oxygen evolution reaction (OER) is critical in water splitting for green hydrogen gas production due to its sluggish kinetics; however, commercial OER catalysts commonly suffer from high cost, low catalytic activity and poor stability. Herein, we developed a C+ ion implantation method to modify single crystal diamond, and the resultant surface amorphous layer not only raised the active site number but also increased the content of the C=O group, thus significantly improving the OER activity. The C+ ion implanted high-temperature and high-pressure (C+-HTHP) and chemical vapor deposition (C+-CVD) diamonds both exhibit low OER overpotential with η 10 of 317 mV and 325 mV respectively, superior to those of HTHP diamond (360 mV), CVD diamond (395 mV) and RuO 2 (364 mV). The potentiostatic testing shows that the C+ implanted diamonds almost didn't undergo the rise of OER overpotential upon catalysis for more than 12 h at a current density of 10 mA cm−2, suggesting a high catalytic stability, owing to the strong bonding between single crystal diamond and amorphous carbon layer. For the first time, we utilized carbon ion implantation to prepare diamond-based high-performance OER catalyst, which broadens the understanding of carbon-based materials in OER catalysis. [ABSTRACT FROM AUTHOR]

Published

2023

4. High charge collection efficiency detector based on plasma purified high-quality diamond.

Author

Mu, Lianxi, Su, Kai, Hu, Tingting, Liu, Jinlong, Zhang, Jinfeng, Chen, Liangxian, Wei, Junjun, Ouyang, Xiaoping, and Li, Chengming

Subjects

*NUCLEAR counters, *DIAMOND crystals, *SINGLE crystals, *DIAMONDS, *ELECTRON mobility, *IRRADIATION

Abstract

Diamond radiation detector is an ideal choice for the next-generation radiation detection in harsh environments, due to its small size, high irradiation resistance and fast response. However, high-purity single crystal diamond is hard to be prepared at the high growth rate due to the inevitable impurity incorporation. In this paper, based on the high-quality high-temperature/high-pressure (HPHT) single crystal diamond substrate, detector-grade single crystal diamonds material with high purity and low defect density were epitaxially grown at growth rate of about 4 μm/h by using plasma environment purification technology. It showed that the full width at half maximum of X-ray rocking curve of high-quality single crystal diamond could reach 0.007°, there was no nitrogen related impurity in PL spectrum, and the substitutional nitrogen content estimated by UV absorption spectrum was less than 10 ppb. After metallization and packaging process, the diamond detectors were prepared and the detector response under irradiation with 241Am α-particles was realized. For the sample with fewer dislocations, the charge collection efficiency and energy resolution of this detector were 86.8 % and 7.85 % for electrons, and 96.7 % and 2.48 % for holes. The product of mobility and lifetime of electrons and holes were 1.7 × 10−4 cm2V−1 and 3.7 × 10−4 cm2V−1, respectively. The high performances of the detector indicate that the current diamond detector can meet the application requirements of commercial diamond detectors. [Display omitted] • Detector-grade diamond was prepared by plasma environment purification technology. • The high-purity single crystal diamond was grown at growth rate of about 4 μm/h. • The diamond detector with charge collection efficiency of 96.7 % was realized. • The products of mobility and lifetime of electrons and holes were 1.7 × 10−4 and 3.7 × 10−4 cm2V−1. [ABSTRACT FROM AUTHOR]

Published

2022