Your search keyword '"Shang-Sheng Li"' showing total 26 results

1. Synthesis and mechanism of TiB2–TiN ceramic composites by high-pressure method

Author

Mei Hua Hu, Yue Yue Wang, Shang Sheng Li, Ning Bi, Ming Ming Liu, and Yong Li

Subjects

010302 applied physics, Materials science, Process Chemistry and Technology, chemistry.chemical_element, 02 engineering and technology, Raw material, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, Grain size, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry, High pressure, visual_art, 0103 physical sciences, Vickers hardness test, Materials Chemistry, Ceramics and Composites, visual_art.visual_art_medium, Relative density, Ceramic, Composite material, 0210 nano-technology, Tin

Abstract

Using pure Ti and hexagonal-BN powder as raw materials, TiB2–TiN ceramic composites were synthesized by high-pressure method at 5.0 GPa and 1400–1800 °C. The phase composition, microstructure, density and hardness of TiB2–TiN ceramic composites were analyzed. The results shown that when the pressure was constant, the synthesis temperature had an important effect on the phase composition of the samples. When TiB2–TiN ceramic composites synthesized at 1800 °C for 30 min, the relative density reached 96.2% and the maximum Vickers hardness reached 17.9 GPa with the load of 4.9 N. The grain size of the TiB2–TiN ceramic composites changed with the change of synthesis temperature, which resulted in the change of density and hardness.

Published

2021

2. The Crystal Stock Phenomenon in the Process of the Plate Shape for Type Ib Large Synthetic Diamond Single Crystals

Author

Junzhuo Wang, Shang-sheng Li, Tai-chao Su, Yue You, Mingming Guo, Xiangyi Luo, Guangjin Gao, Mei-hua Hu, and Xiaolin Zhou

Subjects

010302 applied physics, Materials science, Synthetic diamond, Scanning electron microscope, Infrared spectroscopy, Diamond, 02 engineering and technology, engineering.material, 01 natural sciences, law.invention, Catalysis, Inorganic Chemistry, Crystal, 020303 mechanical engineering & transports, 0203 mechanical engineering, Chemical engineering, law, 0103 physical sciences, engineering, General Materials Science, Fourier transform infrared spectroscopy, Single crystal

Abstract

The crystal stock defect was formed in growing for a long time (22 h) of plate type Ib large diamond single crystals from the NiMnCo−C system at high pressure and high temperature (HPHT). The existence of crystal stock defect has great influence on the synthesis of high quality and large size diamond single crystal. In this paper, the effects of crystal growth rate and catalyst components on diamond crystal stock defects are studied. Firstly, the results show that the growth rate of diamond crystals is closely related to the generating of diamond crystal stock. This defect can be eliminated as the growth rate of diamond crystal synthesized with NiMnCo catalyst is reduced to less than 3 mg/h. Secondly, the composition of the catalyst also affects the formation of the crystal stock. High viscous FeNi catalyst is used to grow high quality large single crystals of diamonds at a growth rate of 3.18 mg/h for a long time (22 h). Thirdly, the effect of catalyst composition on diamond crystal stock was analyzed by testing the micro-morphology and nitrogen content of diamond. It can be shown from the results by scanning electron microscopy (SEM) that the surface of crystals synthesized with low-viscosity catalyst is rough, while it synthesized with high-viscosity catalyst is smooth. It was found from the test results of micro Fourier-transform infrared spectroscopy (FTIR) that the content of nitrogen in the crystals synthesized with FeNi catalyst was much lower than that in the crystals synthesized with NiMnCo. FeNi catalyst can effectively avoid the crystal stock, and is more suitable for the growth of large-size and high-quality diamond single crystal. Changing the composition of the catalyst is an effective way to avoid the crystal stock phenomenon.

Published

2020

3. ASSA13-15-12 Effects of Intracoronary Sodium Nitroprusside Compared with Adenosine on Fractional Flow Reserve Measurement

Author

Xiao-Zeng, Wang, Ya-Ling, Han, Shang-Sheng, Li, Xin, Zhao, Kai, Xu, Fan-Fei, Wang, Jin, Zhang, and Yan-Song, Peng

Published

2013

4. The effect of adding Cu on the nitrogen removal efficiency of Ti for the synthesis of a large type IIa diamond under high temperature and high pressure

Author

Junzhuo Wang, Yue You, Mingming Guo, Shang-sheng Li, Yuan Nie, Lu Feng, Guangjin Gao, Tai-chao Su, and Mei-hua Hu

Subjects

Materials science, Materials Science (miscellaneous), Analytical chemistry, Infrared spectroscopy, Diamond, chemistry.chemical_element, 02 engineering and technology, General Chemistry, engineering.material, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Decomposition, Nitrogen removal, 0104 chemical sciences, law.invention, Optical microscope, chemistry, law, High pressure, engineering, General Materials Science, 0210 nano-technology, Tin, Single crystal

Abstract

Large single crystal diamonds were synthesized using Ti/TiC and Cu as additives in the Fe64Ni36-C system under 5.6 GPa and at 1543 K. The synthesized crystals were characterized by optical microscopy and infrared spectroscopy. Results show that both Ti and TiC react with N to form TiN and Ti (C1-x, Nx), respectively, which leads to a poor nitrogen removal efficiency and a large number of inclusions and pits in the crystals. Co-doping TiorTiC with Cu promotes the decomposition of TiC to release Ti, which improves the nitrogen removal efficiency, and thereby reduces the number of defects and inclusions in the diamond crystals. A high-quality type IIa diamond crystal was optimally synthesized when the Ti/Cu contents were 1.70 wt.%/1.06 wt.% (Ti: Cu = 4: 2.5).

Published

2021

5. Synthesis and Decomposition of Ti3SiC2 under 1-5GPa at 1400°C

Author

Shang Sheng Li, Yuanyuan Zhu, Liang Li, and Aiguo Zhou

Subjects

Materials science, Scanning electron microscope, Mechanical Engineering, Mineralogy, Decomposition, Carbide, chemistry.chemical_compound, Chemical engineering, chemistry, Mechanics of Materials, Boron nitride, Impurity, Phase (matter), General Materials Science, Graphite, Ternary operation

Abstract

Ternary carbide Ti3SiC2 is a good binder to make superhard composites with diamonds or cubic boron nitride. Superhard composites are normally made at high temperature and under high pressure around 5 GPa to avoid the phase transformation of diamonds or cubic boron nitride. This paper researched the synthesis of Ti3SiC2 from the powders of Ti, Si, and graphite by a cubic presser under 1 GPa to 4 GPa at 1400°C. The decomposition of Ti3SiC2 under 5GPa at 1400°C was also researched. From X-ray diffraction (XRD) and scanning electron microscopy (SEM) results, Ti3SiC2 was synthesized in 30 min under 1 GPa at 1400°C. The impurities were TiSi2, Ti5Si3Cx, and TiC. As the pressure increased from 1GPa to 4GPa, less Ti3SiC2 more TiSi2 was synthesized. Therefore, high presser > 1GPa is unfavorable for the synthesis of Ti3SiC2. After treated under 5GPa at 1400°C, pure Ti3SiC2 was decomposed.

Published

2014

6. Study on Grain Fragmentation of Aluminum Nitride Microcrystal under High Pressure

Author

Su Taichao, Li-Ying Wang, Hong-Liang Wang, Shang-Sheng Li, Li Xiaolei, and Qin-Shan Zhang

Subjects

Inorganic Chemistry, Materials science, Fragmentation (mass spectrometry), chemistry, Aluminium, High pressure, Metallurgy, chemistry.chemical_element, General Materials Science, Nitride

Published

2013

7. Synthesize Ti3SiC2 and Ti3SiC2-Diamond Composites at High Pressure and High Temperature

Author

Shang Sheng Li, Tai Chao Su, Liang Li, and Aiguo Zhou

Subjects

Materials science, Mechanical Engineering, Diamond, engineering.material, Carbide, Metal, Mechanics of Materials, Impurity, visual_art, engineering, visual_art.visual_art_medium, General Materials Science, Graphite, Ceramic, Crystallite, Composite material, Ternary operation

Abstract

Ti3SiC2, a ternary carbide, was proposed at this paper to use as the binder of polycrystalline diamonds to overcome the weaknesses of traditional metal binders and ceramic binders. Ti3SiC2was first reported to be in-situ synthesized under high pressure (4GPa) and at high temperature (1400°C) (HPHT) from the mixtures of Ti, Si and graphite powders or the mixture of Ti, SiC and graphite powders. Ti3SiC2-damond composites were also made at HPHT from the previous mixtures and diamond particles. TiCx, Ti5Si3Cxand TiSi2were main impurities and/or intermediate products of Ti3SiC2samples synthesized at HPHT. Ti3SiC2content increased as synthesized time increased from 10 min to 60 min. For as-synthesized composites, diamond particles were evenly distributed in matrix. The diamond particles are bonded well with the matrix by three types of interface.

Published

2012

8. Effect of Ni70Mn25Co5 or Fe55Ni29Co16 on the Growth of Type-II a Large Diamonds with Al as Nitrogen Getter

Author

Yi Shun Zhang, Shang Sheng Li, Tai Chao Su, Ning Luo, Xiao Peng Jia, Xiao Lei Li, and You Mou Zhou

Subjects

Materials science, Metallurgy, General Engineering, Diamond, chemistry.chemical_element, engineering.material, Nitrogen, Catalysis, Temperature gradient, chemistry, Getter, High pressure, engineering, Growth rate, Solubility

Abstract

With adopting Al as the nitrogen getter in Ni70Mn25Co5 or Fe55Ni29Co16 catalyst, High-quality type-Ⅱa large diamonds have been grown under the conditions of about 5.5GPa and 1580K by using the temperature gradient method. While Al(2.0wt%) is added in the Fe55Ni29Co16, the nitrogen concentration(Nc) in the diamond is less than 1ppm. While Al(4.0wt%) is added in the Ni70Mn25Co5, the Nc in the diamond is highly arrived at 48ppm. The different of solubility of nitrogen in both catalyst at high pressure and high temperature is the basic reason of the different effect of eliminating nitrogen of Al. It can be shown in experamentals that Al is a less efficient nitrogen getter in Ni70Mn25Co5 than in Fe55Ni29Co16. While Al(2.0wt%) is added in the Fe55Ni29Co16, the high-quality type-Ⅱa large diamond, in which nitrogen is less than 1ppm and which the size was arrived at 3.3mm, had grown by decreasing the growth rate of diamond.

Published

2011

9. Synthesis of diamond co-doped with B and S under high pressure and high temperature and electrical properties of the synthesized diamond

Author

Li Yong, Shang-Sheng Li, Ran Maowu, Ying Wang, Zong-Bao Li, Song Mousheng, and Kai-Wu Luo

Subjects

Materials science, Chemical engineering, High pressure, engineering, General Physics and Astronomy, Diamond, engineering.material, Co doped

Abstract

As is well known, diamond is extensively used in many fields, because of its excellent properties, such as its hardness, high thermal conductivity, high electron and hole mobility, high breakdown field strength and large band gap (5.4 eV). However, its application in semiconductor area needs to be further understood, because it is irreplaceable by conventional semiconductor materials, especially in the extreme working conditions. Furthermore, the preparation of n-type diamond semiconductors is still an unsolved problem. The reason is that an effective donor element has not yet been found. Recently, both the theoretical and experimental studies show that it is difficult to obtain n-type diamond semiconductor with excellent properties by doping single element in the synthetic system. In this paper, diamond single crystals co-doped with B and S are successfully synthesized in FeNiMnCo-C system at a pressure of 6.5 GPa and temperature ranging from 1280 ℃ to 1300 ℃, by using temperature gradient method. The impurity defects in the synthesized diamond single crystals are characterized by Fourier infrared absorption spectra and the results indicate that the corresponding characteristic absorption peaks of B and S are located at 1298 cm–1 and 847 cm–1, respectively. Furthermore, the absorption attributed to B-S group is not detected. The N concentration of the synthesized diamond crystals decreases to 195 ppm, resulting from the incorporation of B and S impurities into the diamond lattices. Additionally, the electrical properties of the typical diamond single crystals are measured in virtue of Hall effects at room temperature. The measurement results display that the electrical conductivity of the diamond doped with B is obviously enhanced, resulting from the involvement of the S when B addition amount is fixed in the synthesis system. Hall mobility of the corresponding diamond crystals increases from 12.5 cm–2·V–1·s–1 to 760.87 cm–2·V–1·s–1. And then, the relative proportion of S and B will determine the p/n properties of the obtained diamond. In order to further study the electrical properties of diamond, first-principles calculations are adopted and the theoretical calculation results show that the impurity elements involved in the obtained diamond can affect the band structures of the synthetic diamond crystals, which is consistent with the experimental result.

Published

2019

10. Fabrication and Residual Stresses of Aluminum Nitride Ceramics Sintered at High-Pressure

Author

Xiao Lei Li, Xiao Peng Jia, Shang Sheng Li, and Hong An Ma

Subjects

Materials science, Fabrication, Metallurgy, General Engineering, Sintering, chemistry.chemical_element, Nitride, Residual, chemistry, Aluminium, Residual stress, visual_art, visual_art.visual_art_medium, Ceramic, Spectroscopy

Abstract

High-density AlN ceramics were fabricated without sintering additives at high pressure (5.0 GPa) and temperature (1300-1700 °C). The sintered bodies were characterized by XRD and micro-Raman spectroscopy (MRS). The values of residual stresses due to the distortion of the AlN lattice were assessed using the Micro-Raman Spectroscopy (MRS). Residual compression stress of the AlN ceramics sintered at 5.0 GPa and 1700 °C for 125 min is -2.0 GPa. The residual compression stress increased according to the extension of the sintering time.

Published

2009

11. Synthesis of n-type semiconductor diamond single crystal under high pressure and high temperature

Author

Xuemao Guan, Shang-Sheng Li, She Yanchao, Li Yong, Mousheng Song, and Wang Qiang

Subjects

Materials science, business.industry, Analytical chemistry, Infrared spectroscopy, chemistry.chemical_element, Diamond, 02 engineering and technology, General Medicine, engineering.material, 021001 nanoscience & nanotechnology, 01 natural sciences, Semiconductor, chemistry, Hall effect, 0103 physical sciences, engineering, Fourier transform infrared spectroscopy, 010306 general physics, 0210 nano-technology, business, Boron, Single crystal, Extrinsic semiconductor

Abstract

In this paper, diamond single crystal co-doped with sulfur and boron was successfully synthesized at the fixed pressure of 6.0 GPa and temperature range of 1535 K. Sulfur was detected in the co-doped diamond by Fourier Transform Infrared Spectroscopy (FTIR) and the corresponding characteristic peak located at 848 cm-1. Interestingly, Hall effect measurements indicated that the diamond co-doped with sulfur and boron exhibited n-type semiconductor behaviour. Furthermore, the Hall mobility and carrier concentration of the co-doped diamond higher than those of the boron-doping diamond.

Published

2017

12. B–C Bond in Diamond Single Crystal Synthesized with h-BN Additive at High Pressure and High Temperature

Author

Yong, Li, primary, Zhen-Xiang, Zhou, additional, Xue-Mao, Guan, additional, Shang-Sheng, Li, additional, Ying, Wang, additional, Xiao-Peng, Jia, additional, and Hong-An, Ma, additional

Published

2016

13. Study on passivity-based control and its robust analyzing of active power filter

Author

Sun Jianjun, Shang-sheng Li, Gong Jinwu, Cong Li, and Zha Xiaoming

Subjects

Harmonic analysis, Engineering, Active power filter, Damping matrix, business.industry, Control theory, Robustness (computer science), Passivity, Control engineering, Robust control, business, Active filter, Control methods

Abstract

This paper proposes a new passivity-based control method for APF. Such method introduces damping matrix R a to improve harmonic compensation effect and accelerate the convergence speed. It also includes Robust stability analysis and the results proved that APF system can still maintain stable after the parameter variation and load disturbance. Based on the Robust analysis, the control equations are further simplified to make them more realizable. This new passive current control strategy is supported by simulation results.

Published

2009

14. HPHT Synthesis of Different Shape Coarse-Grain Diamond Single Crystals

Author

Sheng-Guo, Zhou, primary, Chuan-Yi, Zang, additional, Hong-An, Ma, additional, Qiang, Hu, additional, Xiao-Lei, Li, additional, Shang-Sheng, Li, additional, He-Min, Zhang, additional, and Xiao-Peng, Jia, additional

Published

2009

15. Finite Element Analysis of Convection in Growth Cell for Diamond Growth Using Ni-Based Solvent

Author

Yu, Tian, primary, Xiao-Peng, Jia, additional, Chuan-Yi, Zang, additional, Rui, Li, additional, Shang-Sheng, Li, additional, Hong-Yu, Xiao, additional, Ya-Fei, Zhang, additional, Guo-Feng, Huang, additional, Qi-Gang, Han, additional, Li-Qiu, Ma, additional, Yong, Li, additional, Xiao-Zhou, Chen, additional, Cong, Zhang, additional, and Hong-An, Ma, additional

Published

2009

16. Effects of Al and Ti/Cu on Synthesis of Type-IIa Diamond Crystals in Ni 70 Mn 25 Co 5 -C System at HPHT

Author

Shang-Sheng, Li, primary, Xiao-Peng, Jia, additional, Chuan-Yi, Zang, additional, Yu, Tian, additional, Ya-Fei, Zhang, additional, Hong-Yu, Xiao, additional, Guo-Feng, Huang, additional, Li-Qiu, Ma, additional, Yong, Li, additional, Xiao-Lei, Li, additional, and Hong-An, Ma, additional

Published

2008

17. HPHT Synthesis of Micron Grade Boron-Doped Diamond Single Crystal in Fe-Ni-C-B Systems

Author

He-Min, Zhang, primary, Chuan-Yi, Zang, additional, Xiao-Lei, Li, additional, Hong-An, Ma, additional, Shang-Sheng, Li, additional, Sheng-Guo, Zhou, additional, Wei, Guo, additional, and Xiao-Peng, Jia, additional

Published

2008

18. Dependence of Limited Growth Rate of High-Quality Gem Diamond on Growth Conditions

Author

Yu, Tian, primary, Hong-An, Ma, additional, Shang-Sheng, Li, additional, Hong-Yu, Xiao, additional, Ya-Fei, Zhang, additional, Guo-Feng, Huang, additional, Li-Qiu, Ma, additional, and Xiao-Peng, Jia, additional

Published

2007

19. Grow Large High-Quality Diamonds with Different Seed Surfaces

Author

Chuan-Yi, Zang, primary, Xiao-Peng, Jia, additional, Hong-An, Ma, additional, Shang-Sheng, Li, additional, Yu, Tian, additional, and Hong-Yu, Xiao, additional

Published

2006

20. Growth of Large High-Quality Type-II a Diamond Crystals

Author

Xian-Cheng, Wang, primary, Hong-An, Ma, additional, Chuan-Yi, Zang, additional, Yu, Tian, additional, Shang-Sheng, Li, additional, and Xiao-Peng, Jia, additional

Published

2005

21. Study on passivity-based control and its robust analyzing of active power filter.

Author

Jian-jun Sun, Cong Li, Xiao-ming Zha, Jin-wu Gong, and Shang-sheng Li

Published

2009

22. Growth characteristics of type IIa large single crystal diamond with Ti/Cu as nitrogen getter in FeNi–C system.

Author

Ming-Ming Guo, Shang-Sheng Li, Mei-Hua Hu, Tai-Chao Su, Jun-Zuo Wang, Guang-Jin Gao, Yue You, and Yuan Nie

Subjects

*COPPER-titanium alloys, *DIAMOND crystals, *SINGLE crystals, *CRYSTAL surfaces, *NITROGEN, *SCANNING electron microscopy, *CRYSTAL growth

Abstract

High-quality type IIa large diamond crystals are synthesized with Ti/Cu as nitrogen getter doped in an FeNi–C system at temperature ranging from 1230 °C to 1380 °C and at pressure 5.3–5.9 GPa by temperature gradient method. Different ratios of Ti/Cu are added to the FeNi–C system to investigate the best ratio for high-quality type IIa diamond. Then, the different content of nitrogen getter Ti/Cu (Ti : Cu = 4 : 3) is added to this synthesis system to explore the effect on diamond growth. The macro and micro morphologies of synthesized diamonds with Ti/Cu added, whose nitrogen concentration is determined by Fourier transform infrared (FTIR), are analyzed by optical microscopy (OM) and scanning electron microscopy (SEM), respectively. It is found that the inclusions in the obtained crystals are minimal when the Ti/Cu ratio is 4:3. Furthermore, the temperature interval for diamond growth becomes narrower when using Ti as the nitrogen getter. Moreover, the lower edge of the synthesis temperature of type IIa diamond is 25 °C higher than that of type Ib diamond. With the increase of the content of Ti/Cu (Ti : Cu = 4 : 3), the color of the synthesized crystals changes from yellow and light yellow to colorless. When the Ti/Cu content is 1.7 wt%, the nitrogen concentration of the crystal is less than 1 ppm. The SEM results show that the synthesized crystals are mainly composed by (111) and (100) surfaces, including (311) surface, when the nitrogen getter is added into the synthesis system. At the same time, there are triangular pits and dendritic growth stripes on the crystal surface. This work will contribute to the further research and development of high-quality type IIa diamond. [ABSTRACT FROM AUTHOR]

Published

2020

23. Synthesis and Characteristics of Type Ib Diamond Doped with NiS as an Additive.

Author

Jian-Kang Wang, Shang-Sheng Li, Ning Wang, Hui-Jie Liu, Tai-Chao Su, Mei-Hua Hu, Fei Han, Kun-Peng Yu, and Hong-An Ma

Subjects

*DIAMOND crystals, *DIAMONDS, *FOURIER transform infrared spectroscopy, *X-ray photoelectron spectroscopy, *N-type semiconductors, *SINGLE crystals

Abstract

Large diamond single crystals doped with NiS are synthesized under high pressure and high temperature. It is found that the effects on the surface and shape of the synthesized diamond crystals are gradually enhanced by increasing the NiS additive amount. It is noted that the synthesis temperature is necessarily raised to 1280°C to realize the diamond growth when the additive amount reaches 3.5% in the synthesis system. The results of Fourier transform infrared spectroscopy (FTIR) demonstrate that S is incorporated into the diamond lattice and exists in the form of C–S bond. Based on the FTIR results, it is found that N concentration in diamond is significantly increased, which are ascribed to the NiS additive. The analysis of x-ray photoelectron spectroscopy shows that S is present in states of C–S, S–O and C–S–O bonds. The relative concentration of S compared to C continuously increases in the synthesized diamonds as the amount of additive NiS increases. Additionally, the electrical properties can be used to characterize the obtained diamond crystals and the results show that diamonds doped with NiS crystals behave as n-type semiconductors. [ABSTRACT FROM AUTHOR]

Published

2019

24. Inclusions in large diamond single crystals at different temperatures of synthesis.

Author

Fei Han, Shang-Sheng Li, Xue-Fei Jia, Wei-Qin Chen, Tai-Chao Su, Mei-Hua Hu, Kun-Peng Yu, Jian-Kang Wang, Yu-Min Wu, Hong-An Ma, and Xiao-Peng Jia

Subjects

*DIAMOND crystals, *SINGLE crystals, *HIGH pressure (Technology), *HIGH temperatures, *ENERGY dispersive X-ray spectroscopy

Abstract

The inclusions in large diamond single crystals have effects on its ultimate performance, which restricts its industrial applications to a great extent. Therefore, it is necessary to study the inclusions systematically. In this paper, large diamond single crystals with different content values of inclusions are synthesized along the (100) surface by the temperature gradient method (TGM) under 5.6 GPa at different temperatures. With the synthetic temperature changing from 1200 °C to 1270 °C, the shapes of diamonds change from plate to low tower, to high tower, even to steeple. From the microscopic photographs of the diamond samples, it can be observed that with the shapes of the samples changing at different temperatures, the content values of inclusions in diamonds become zero, a little, much and most, correspondingly. Consequently, with the temperature growing from low to high, the content values of inclusions in crystals increase. The origin of inclusions is explained by the difference in growth rate between diamond crystal and its surface. The content values of inclusions in diamond samples are quantitatively calculated by testing the densities of diamond samples. And the composition and inclusion content are analyzed by energy dispersive spectroscopy (EDS) and x-ray diffraction (XRD). From contrasting scanning electron microscopy (SEM) photographs, it can be found that the more the inclusions in diamond, the more imperfect the diamond surface is. [ABSTRACT FROM AUTHOR]

Published

2019

25. Effect of FeS doping on large diamond synthesis in FeNi–C system.

Author

Jian-Kang Wang, Shang-Sheng Li, Quan-Wei Jiang, Yan-Ling Song, Kun-Peng Yu, Fei Han, Tai-Chao Su, Mei-Hua Hu, Qiang Hu, Hong-An Ma, Xiao-Peng Jia, and Hong-Yu Xiao

Subjects

*DIAMOND crystals, *IRON sulfides, *FOURIER transform infrared spectroscopy, *CORROSION & anti-corrosives, *SURFACE morphology

Abstract

The large single-crystal diamond with FeS doping along the (111) face is synthesized from the FeNi–C system by the temperature gradient method (TGM) under high-pressure and high-temperature (HPHT). The effects of different FeS additive content on the shape, color, and quality of diamond are investigated. It is found that the (111) face of diamond is dominated and the (100) face of diamond disappears gradually with the increase of the FeS content. At the same time, the color of the diamond crystal changes from light yellow to gray-green and even gray-yellow. The stripes and pits corrosion on the diamond surface are observed to turn worse. The effects of FeS doping on the shape and surface morphology of diamond crystal are explained by the number of hang bonds in different surfaces of diamond. It can be shown from the test results of the Fourier transform infrared (FTIR) spectrum that there exists an S element in the obtained diamond. The N element content values in different additive amounts of diamond are calculated. The XPS spectrum results demonstrate that our obtained diamond contains S elements that exist in S–C and S–C–O forms in a diamond lattice. This work contributes to the further understanding and research of FeS-doped large single-crystal diamond characterization. [ABSTRACT FROM AUTHOR]

Published

2018

26. Different effect of NiMnCo or FeNiCo on the growth of type-IIa large diamonds with Ti/Cu as nitrogen getter.

Author

Shang-Sheng Li, He Zhang, Tai-Chao Su, Qiang Hu, Mei-Hua Hu, Chun-Sheng Gong, Hon-An Ma, Xiao-Peng Jia, Yong Li, and Hong-Yu Xiao

Subjects

*DIAMONDS, *CATALYSTS, *TEMPERATURE lapse rate, *ATMOSPHERIC temperature, *NICKEL-manganese alloys

Abstract

In order to synthesize high-quality type-IIa large diamond, the selection of catalyst is very important, in addition to the nitrogen getter. In this paper, type-IIa large diamonds are grown under high pressure and high temperature (HPHT) by using the temperature gradient method (TGM), with adopting Ti/Cu as the nitrogen getter in Ni70Mn25Co5 (abbreviated as NiMnCo) or Fe55Ni29Co16 (abbreviated FeNiCo) catalyst. The values of nitrogen concentration (Nc) in both synthesized high-quality diamonds are less than 1 ppm, when Ti/Cu (1.6 wt%) is added in the FeNiCo or Ti/Cu (1.8 wt%) is added in the NiMnCo. The difference in solubility of nitrogen between both catalysts at HPHT is the basic reason for the different effect of Ti/Cu on eliminating nitrogen. The nitrogen-removal efficiency of Ti/Cu in the NiMnCo catalyst is less than in the FeNiCo catalyst. Additionally, a high-quality type-IIa large diamond size of 5.0 mm is obtained by reducing the growth rate and keeping the nitrogen concentration of the diamond to be less than 1 ppm, when Ti/Cu (1.6 wt%) is added in the FeNiCo catalyst. [ABSTRACT FROM AUTHOR]

Published

2017