Experimental study of simultaneous high-temperature and high-pressure assembly of Paris-Edinburgh press for neutron diffraction

Yang Gong-Zhang; Xie Lei; Chen Xi-Ping; He Rui-Qi; Han Tie-Xin; Niu Guo-Liang; Fang Lei-Ming; He Duan-Wei

doi:10.7498/aps.71.20220419

Abstract

Paris-Edinbrugh (PE) press has been widely used in high pressure in-situ neutron diffraction experiments due to its advantages of large sample size, portability and simple structure. However, with the characteristics of uniaxial load of PE press, the weak lateral support makes the gasket and cell assembly continue flowing outward. So, the development of cell assembly of PE press that can simultaneously work under high pressure and high temperature (high P-T) is a great challenge. In this work, we design three-segment high P-T assembly of PE press for neutron diffraction, which can significantly improve the heating efficiency, thermal insulation, and stability of assembly. By using the fanned Cu foil leads of thermocouple, we realize the in-situ measurement of assembly temperature under a high pressure up to 5 GPa. The designed HPT-3 and HPT-3.5 assemblies can arrive at 2034 K and 1515 K respectively, which are measured by thermocouple. The high P-T experiments of HPT-3 assembly are carried out on a high-pressure neutron diffraction spectrometer (Fenghuang) of China Mianyang Research Reactor (CMRR). The results show that the designed assembly can simultaneously achieve high P-T of 8.5 GPa and 1508 K with collecting the high-quality neutron diffraction data of MgO cylindrical sample.

Keywords:

Authors and contacts

1.
Institute of Atomic and Molecular Physics, Sichuan University, Chengdu 610065, China
2.
Key Laboratory for Neutron Physics, Institute of Nuclear Physics and Chemistry, China Academy of Engineering Physics, Mianyang 621999, China
3.
Guangdong Zhengxin Hard Material Technology R & D Co., Ltd, Heyuan 517000, China

Corresponding author: Fang Lei-Ming, flmyaya2008@163.com ; He Duan-Wei, duanweihe@scu.edu.cn

Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 12075215, 11427810), the National Key R&D Program of China (Grant No. 2016YFA0401503), and the Science Challenge Project, China (Grant No. TZ2016001).

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References

[1]	Bundy F P 1963 J. Chem. Phys. 38 631 Google Scholar
[2]	Corrign F R, Bundy F P 1975 J. Chem. Phys. 63 3812 Google Scholar
[3]	Snider E, Dasenbrock-Gammon N, McBride1 R, Debessai M, Vindana H, Vencatasamy K, Lawler K V, Salamat A, Dias R P 2020 Nature 586 373 Google Scholar
[4]	Zeng Q, Sheng H, Ding Y, Wang L, Yang W, Jiang J Z, Mao W L, Mao H K 2011 Science 332 1404 Google Scholar
[5]	Besson J M, Nelmes R J, Hamel G, Loveday J S, Weill G, Hull S 1992 Physica B 180 907 Google Scholar
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[17]	Zhang J, Zhao Y, Wang Y, Daemen L 2008 J. Appl. Phys. 103 093513 Google Scholar
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[19]	Klotz S, Godec Y Le, Strässle T, Stuhr U 2008 Appl. Phys. Lett. 93 091904 Google Scholar
[20]	江明全, 李欣, 房雷鸣, 谢雷, 陈喜平, 胡启威, 李强, 李青泽, 陈波, 贺端威 2020 69 226101 Google Scholar Jiang M Q, Li X, Fang L M, Xie L, Chen X P, Hu Q W, Li Q, Li Q Z, Chen B, He D W 2020 Acta Phys. Sin. 69 226101 Google Scholar
[21]	房雷鸣, 陈喜平, 谢雷, 贺端威, 胡启威, 李欣, 江明全, 孙光爱, 陈波, 彭述明, 李昊, 韩铁鑫 2020 高压 34 15705 Google Scholar Fang L M, Chen X P, Xie L, He D W, Hu Q W, Li X, Jiang M Q, Sun G A, Chen B, Peng S M, Li H, Han T X 2020 Chin. J. High Pressure Phys. 34 15705 Google Scholar
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[23]	Rodríguez-Carvajal J, Roisnel T 2004 Mater. Sci. Forum 443–444 123 Google Scholar
[24]	Martíinez D, Le G Y, Mézouar M, Syfosse G, Itié J P, Besson J M 2000 High Pressure Res. 18 339 Google Scholar
[25]	Li B, Woody K, Kung J 2006 J. Geophys. Res. Solid Earth 111 11206 Google Scholar
[26]	Tange Y, Nishihara Y, Tsuchiya T 2009 J. Geophys. Res. 114 03208 Google Scholar

Cited By

图 1 中子衍射高温高压组装　(a)文献[16, 17]组装, 其中 1铝环, 2聚四氟乙烯环, 3 铝合金封垫, 4磷酸锆, 5电极, 6样品, 7不锈钢锥体, 8热电偶, 9石墨加热管, 10绝缘环; (b)文献[19]组装, 其中1铍铜合金封垫, 2绝缘环, 3 叶腊石, 4电极, 5氧化镁, 6样品, 7钽箔, 8石墨加热管; (c)文献[20, 21]组装, 其中1钛锆合金封垫, 2绝缘环, 3氧化锆, 4电极, 5铼箔, 6样品, 7石墨加热管

Figure 1. Schematic illustrations of high-temperature and high-pressure cell assembly for neutron diffraction. (a) Cell assembly in Ref. [16, 17]. 1 Al ring, 2 teflon ring, 3 alloy steel gasket, 4 zirconium phosphate, 5 electrode, 6 sample, 7 stainless steel cone, 8 thermocouple, 9 carbon furnace, 10 insulating ring. (b) Cell assembly in Ref. [19]. 1 CuBe gasket, 2 insulating ring, 3 pyrophyllite, 4 electrode, 5 MgO, 6 sample, 7 Ta foil, 8 carbon furnace; (c) Cell assembly in Ref. [20, 21]. 1 TiZr gasket, 2 insulating ring, 3 ZrO₂, 4 electrode, 5 Re foil, 6 sample, 7 carbon furnace.

DownLoad: Full-Size Img PowerPoint

图 2 (a) 高温高压组装示意图; (b) 高温高压组装各组装件实物图. 1 封垫, 2 叶腊石绝缘层, 3氧化锆, 4石墨加热管, 5绝缘管, 6样品, 7电极, 8热电偶

Figure 2. (a) Schematic diagram of high-temperature and high-pressure cell assembly; (b) photograph of the assembly parts. 1 gasket, 2 pyrophyllite insulating ring, 3 ZrO₂, 4 carbon furnace, 5 electrical insulation sleeve, 6 sample, 7 electrode, 8 thermocouple.

DownLoad: Full-Size Img PowerPoint

图 3 (a)锯齿形状引线及(b)扇形铜箔引线的示意图

Figure 3. Schematic diagram of (a) jagged and (b) Cu foil thermocouple’s leads.

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图 4 HPT-3.5和HPT-3.5组装在5 GPa压力下的温度与功率对应曲线

Figure 4. Temperature versus electrical-power relationship in HPT-3.5 and HPT-3 at 5 GPa.

DownLoad: Full-Size Img PowerPoint

图 5 HPT-3.5组装内部不同位置和压砧边缘的温度测量

Figure 5. Temperatures at different places of HPT-3.5 assembly and the edge of anvils.

DownLoad: Full-Size Img PowerPoint

图 6 相同功率加载下温度随压力的变化关系

Figure 6. Pressure dependences of temperature with the power fixed at 210 W.

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图 7 高温高压下原位中子衍射实验谱图

Figure 7. Diffraction pattern of MgO at high-temperature and high-pressure.

DownLoad: Full-Size Img PowerPoint

map

[1]	Bundy F P 1963 J. Chem. Phys. 38 631 Google Scholar
[2]	Corrign F R, Bundy F P 1975 J. Chem. Phys. 63 3812 Google Scholar
[3]	Snider E, Dasenbrock-Gammon N, McBride1 R, Debessai M, Vindana H, Vencatasamy K, Lawler K V, Salamat A, Dias R P 2020 Nature 586 373 Google Scholar
[4]	Zeng Q, Sheng H, Ding Y, Wang L, Yang W, Jiang J Z, Mao W L, Mao H K 2011 Science 332 1404 Google Scholar
[5]	Besson J M, Nelmes R J, Hamel G, Loveday J S, Weill G, Hull S 1992 Physica B 180 907 Google Scholar
[6]	Utsumi W, Kagi H, Komatsu K, Arima H, Nagai T, Okuchi T, Kamiyama T, Uwatoko Y, Matsubayashi K, Yagi T 2009 Nucl. Instrum. Methods A 600 50 Google Scholar
[7]	Zhao Y S, Zhang J Z, Xu H W, Lokshin K A, He D W, Qian J, Pantea C, Daemen L L, Vogel S C, Ding Y, Xu J 2010 Appl. Phys. A 99 585 Google Scholar
[8]	Bull C L, Funnell N P, Tucker M G, Hull S, Francis D J, Marshall W G 2016 High Pressure Res. 36 493 Google Scholar
[9]	Calder S, An K, Boehler R, Dela Cruz C R, Frontzek M D, Guthrie M, Haberl B, Huq A, Kimber S A J, Liu J, Molaison J J, Neuefeind J, Page K, Santos A M, Taddei K M, Tulk C, Tucker M G 2018 Rev. Sci. Instrum. 89 092701 Google Scholar
[10]	史钰, 陈喜平, 谢雷, 孙光爱, 房雷鸣 2019 68 116101 Google Scholar Shi Y, Chen X P, Xie L, Sun G A, Fang L M 2019 Acta Phys. Sin. 68 116101 Google Scholar
[11]	Klotz S, Besson J M, Hamel G, Nelmes R J, Loveday J S, Marshalla W G, Wilson R M 1995 Appl. Phys. 66 1735 Google Scholar
[12]	Guthrie M, Boehler R, Tulk C A, Molaison J J, Santos A M, Li K, Hemley R J 2013 Proc. Natl. Acad. Sci. U.S.A. 110 10552 Google Scholar
[13]	Boehler R, Guthrie M, Molaison J J, Santos A M, Sinogeikin S, Machida S, Pradhan N, Tulkn C A 2013 High Pressure Res. 33 546 Google Scholar
[14]	Hattori T, Sano-Furukawa A, Machida S, Abe J, Funakoshi K, Arima H, Okazaki N 2019 High Pressure Res. 39 417 Google Scholar
[15]	Hu Q, Fang L, Li Q, Li X, Chen X, Xie L, Zhang J, Liu F, Lei L, Sun G, He D 2019 High Pressure Res. 39 655 Google Scholar
[16]	Zhao Y, Robert B, Dreele V, Jiaming, Morgan G 1999 High Pressure Res. 16 161 Google Scholar
[17]	Zhang J, Zhao Y, Wang Y, Daemen L 2008 J. Appl. Phys. 103 093513 Google Scholar
[18]	He D, Zhao Y, Daemen L L, Qian J, Lokshin K, Shen T D, Zhang J, Lawson A C 2004 J. Appl. Phys. 95 4645 Google Scholar
[19]	Klotz S, Godec Y Le, Strässle T, Stuhr U 2008 Appl. Phys. Lett. 93 091904 Google Scholar
[20]	江明全, 李欣, 房雷鸣, 谢雷, 陈喜平, 胡启威, 李强, 李青泽, 陈波, 贺端威 2020 69 226101 Google Scholar Jiang M Q, Li X, Fang L M, Xie L, Chen X P, Hu Q W, Li Q, Li Q Z, Chen B, He D W 2020 Acta Phys. Sin. 69 226101 Google Scholar
[21]	房雷鸣, 陈喜平, 谢雷, 贺端威, 胡启威, 李欣, 江明全, 孙光爱, 陈波, 彭述明, 李昊, 韩铁鑫 2020 高压 34 15705 Google Scholar Fang L M, Chen X P, Xie L, He D W, Hu Q W, Li X, Jiang M Q, Sun G A, Chen B, Peng S M, Li H, Han T X 2020 Chin. J. High Pressure Phys. 34 15705 Google Scholar
[22]	Godec Y L, Dove M T, Redfern S, Tucker M G, Marshall W G, Syfosse G, Besson J M 2001 High Pressure Res. 21 263 Google Scholar
[23]	Rodríguez-Carvajal J, Roisnel T 2004 Mater. Sci. Forum 443–444 123 Google Scholar
[24]	Martíinez D, Le G Y, Mézouar M, Syfosse G, Itié J P, Besson J M 2000 High Pressure Res. 18 339 Google Scholar
[25]	Li B, Woody K, Kung J 2006 J. Geophys. Res. Solid Earth 111 11206 Google Scholar
[26]	Tange Y, Nishihara Y, Tsuchiya T 2009 J. Geophys. Res. 114 03208 Google Scholar

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