Millisecond time-resolved synchrotron radiation X-ray diffraction and high-pressure rapid compression device and its application

Wang Bi-Han; Li Bing; Liu Xu-Qiang; Wang Hao; Jiang Sheng; Lin Chuan-Long; Yang Wen-Ge

doi:10.7498/aps.71.20212360

Abstract

Non-equilibrium transition dynamics under high pressure depends on temperature, pressure and (de)compression rate. The studies require combination of time-resolved probe and rapid compression device on different time scales. Here we report the time-resolved X-ray diffraction (XRD) and dynamic diamond anvil cell (dDAC) system, which were recently developed at the BL15U1 beamline of Shanghai Synchrotron Radiation Facility (SSRF). There are two rapid loading methods for dDAC. One uses membrane control and the other is piezoelectric actuator driven dDAC. Both methods can dynamically compress the DAC sample chamber up to 300 GPa on millisecond scale (20 μm culet is used), and the time-resolved XRD data are obtained correspondingly. A new type of piezoelectric ceramic dDAC is designed with single-side drive or double-side drive, which allows us to realize extremely high pressure (above 300 GPa) with a fast compression rate of 13 TPa/s. During the rapid compression process, the X-ray diffraction spectra are collected continuously and simultaneously. The XRD detector is Pilatus 3X 900K, which has 2-ms resolution with 500 kHz frame rate. The millisecond time-resolved XRD and high pressure rapid compression system developed at BL15U1 of SSRF enrich the high-pressure experimental methods and enable the beamline to carry out ultra-high pressure experiments, non-equilibrium phase transition and relevant scientific researches.

Keywords:

Authors and contacts

1.
Center for High Pressure Science & Technology Advanced Research, Shanghai 201203, China
2.
Shanghai Institute of Applied Physics, Chinese Academy of Sciences, Shanghai 201203, China

Corresponding author: Jiang Sheng, jiangsheng@zjlab.org.cn ; Lin Chuan-Long, chuanlong.lin@hpstar.ac.cn ;

Funds: Project supported by the National Key R&D projects (Grant No. 2017YFA0403401), the National Natural Science Foundation of China (Grant Nos. 11974033, U1930401, 51527801, 51772184) and Science Challenge Topics (Grant No. TZ2016001).

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References

[1]	丁迎春, 徐明, 潘洪哲, 沈益斌, 祝文军, 贺红亮 2007 物理学报 56 117 Google Scholar Ding Y C, Xu M, Pang H Z, Shen Y B, Zhu W J, He H L 2007 Acta Phys. Sin. 56 117 Google Scholar
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[5]	John S T, Li Z, Uehara K, Ma Y, Ahuja R 2004 Phys. Rev. B 69 132101 Google Scholar
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[7]	Levien L, Prewitt C T 1981 Am. Min. 66 324
[8]	Abd-Elmeguid M M, Ni B, Khomskii D I, Pocha R, Johrendt D, Wang X, Syassen K 2004 Phys. Rev. Lett. 93 126403 Google Scholar
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[22]	Zhang L L, Yan S, Jiang S 2015 Nucl. Sci. Tech. 26 060101 Google Scholar
[23]	Biwer C M, Quan A, Huston L Q, Sturtevant B T, Sweeney C M 2021 Rev. Sci. Instrum. 92 103901 Google Scholar
[24]	Kumar M 1995 Phys. Condens. Matter 212 391 Google Scholar
[25]	Anzellini S, Dewaele A, Occelli F, Loubeyre P, Mezouar M 2014 J. Appl. Phys. 115 043511 Google Scholar

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图 1 BL15U1线站束线布局图. 其中IVU25为磁极周期长度25 mm真空波荡器; S1为白光狭缝; FM为聚焦/准直镜; DCM为双晶单色器; S2为水平次级狭缝; KB为KB聚焦镜; Sample为样品点

Figure 1. Beam path layout of BL15U1. Where IVU25 is vacuum undulator with 25 mm period length; S1 is white beam slits; FM is toroidal focusing mirror; DCM is double crystal monochromator; S2 is horizontal secondary beam slits; KB is Kirkpatrick-Baez mirror; Sample is sample point.

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图 2 单、双气膜控制dDAC实验装置　(a)双气膜控制dDAC原理图, 标记1为气膜; 标记2为气膜连接管, 标记3为大垫片, 标记4为卸压顶针, 标记5为样品腔, 标记6为组装罐; (b)单气膜控制dDAC实物图, 左边为气膜, 右边为单气膜控制dDAC实物图, 标记1为气膜, 标记2为气膜连接管, 标记6为组装罐

Figure 2. Single or double membrane controlled dDAC experimental device: (a) Schematic diagram of dual membrane controlled dDAC, mark 1 is gas membrane, mark 2 is gas membrane connecting pipe, mark 3 is large gasket, mark 4 is ejector pin, mark 5 is sample chamber, mark 6 is the assembly can; (b) the photo of single gas membrane control dDAC, the left is the gas membrane, and on the right is the photo of single gas membrane control dDAC, mark 1 is gas membrane, mark 2 is gas membrane connecting pipe, mark 6 is the assembly can.

DownLoad: Full-Size Img PowerPoint

图 3 单、双压电陶瓷控制dDAC实验装置　(a)单压电陶瓷控制dDAC原理图, 标记1为实心圆柱压电陶瓷, 标记3为压电陶瓷顶丝, 标记4为卸压顶针, 标记5为样品腔, 标记6为组装罐; (b)双压电陶瓷控制dDAC原理图, 标记2为圆环压电陶瓷堆片, 标记7为连接钢板; (c)单压电陶瓷控制dDAC实物图; (d)双压电陶瓷控制dDAC实物图

Figure 3. Single and double piezoelectric ceramic control dDAC experimental device: (a) Schematic diagram of single cylinder piezoelectric ceramic control dDAC, mark 1 is solid cylindrical piezoelectric ceramics, mark 3 is piezoelectric ceramic top wire, mark 4 is ejector pin, mark 5 is sample chamber, mark 6 is the assembly can; (b) Schematic diagram of double barrel piezoelectric ceramic control dDAC, mark 2 is ring piezoelectric ceramic stack; mark 7 is perfobond ribs; (c) the photo of single cylinder piezoelectric ceramic control dDAC; (d) the photo of double barrel piezoelectric ceramic control dDAC.

DownLoad: Full-Size Img PowerPoint

图 4 气膜和压电陶瓷联合控制dDAC实验装置　(a)单气膜和单压电陶瓷联合控制dDAC实验装置实物图; (b)单气膜和双压电陶瓷联合控制dDAC实验装置实物图. 标记2为气膜连接管, 标记6为组装罐

Figure 4. Experimental device for joint control of gas membrane and piezoelectric ceramics for dDAC: (a) The photo of the dDAC experimental device for combined control of single gas membrane and single tube piezoelectric ceramics; (b) the photo of the dDAC experimental device for combined control of single gas membrane and double piezoelectric ceramics. Mark 2 is gas membrane connecting pipe, mark 6 is the assembly can.

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图 5 毫秒时间分辨的高压同步辐射X射线衍射和快速加载装置布局示意图

Figure 5. Schematic layout of millisecond time-resolved synchrotron radiation X-ray diffraction and dynamic compression device setup.

DownLoad: Full-Size Img PowerPoint

图 6 动加载下Re的XRD　(a) Re的XRD时间堆叠图; (b)压强随时间变化关系

Figure 6. XRD of Re under dynamic compression: (a) XRD time stacking diagram of Re; (b) the relationship between pressure changes over time.

DownLoad: Full-Size Img PowerPoint

图 7 动加载下Re的XRD　(a) Re的XRD时间堆叠图; (b) Re的XRD积分曲线堆叠图; (c)压力变化随时间的关系

Figure 7. XRD of Re under dynamic compression: (a) XRD time stacking diagram of Re; (b) stacked graph of Re XRD integral curve; (c) the relationship between pressure changes over time.

DownLoad: Full-Size Img PowerPoint

图 8 压力变化随时间的关系

Figure 8. The relationship between pressure changes over time.

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图 9 高压下金属Ge β-Sn相在卸压过程时的相变路径

Figure 9. The phase change path of the metal Ge β-Sn phase during the pressure relief process under high pressure.

DownLoad: Full-Size Img PowerPoint

[1]	丁迎春, 徐明, 潘洪哲, 沈益斌, 祝文军, 贺红亮 2007 物理学报 56 117 Google Scholar Ding Y C, Xu M, Pang H Z, Shen Y B, Zhu W J, He H L 2007 Acta Phys. Sin. 56 117 Google Scholar
[2]	Yamanaka T, Fukuda T, Mimaki J 2002 Phys. Chem. Miner. 29 633 Google Scholar
[3]	Sui Y, Xu D, Zheng F, Su W 1996 J. Appl. Phys. 80 719 Google Scholar
[4]	Yue S, Cheng L, Liao B, Hu M 2018 Phys. Chem. Chem. Phys. 20 27125 Google Scholar
[5]	John S T, Li Z, Uehara K, Ma Y, Ahuja R 2004 Phys. Rev. B 69 132101 Google Scholar
[6]	Nakashima M, Tabata K, Thamizhavel A, Kobayashi T C, Hedo M, Uwatoko Y, Shimizu K, Settai R, Ōnuki Y 2004 J. Phys. Condens. Matter 16 L255 Google Scholar
[7]	Levien L, Prewitt C T 1981 Am. Min. 66 324
[8]	Abd-Elmeguid M M, Ni B, Khomskii D I, Pocha R, Johrendt D, Wang X, Syassen K 2004 Phys. Rev. Lett. 93 126403 Google Scholar
[9]	Brazhkin V V, Lyapin A G, Stalgorova O V, Gromnitskaya E L, Popova S V, Tsiok O B 1997 J. Non. Crys. Solids 212 49 Google Scholar
[10]	Ozoliņš V, Zunger A 1999 Phys. Rev. Lett. 82 767 Google Scholar
[11]	Sterer E, Silvera I F 2006 Rev. Sci. Instrum. 77 115105 Google Scholar
[12]	Schiferl D, Katz A I, Mills R L, Schmidt L C, Vanderborgh C, Skelton E F, Elam W T, Webb A W, QadriM S B, Schaefer M 1986 Physica B + C 139 897
[13]	Shu H, Zhang Y, Wang B, Yang W, Dong H, Tobase T, Ye J, Huang X, Fu S, Zhou Q, Sekine T 2020 Phys. Plasmas 27 030701 Google Scholar
[14]	Smith J S, Sinogeikin S V, Lin C, Rod E, Bai L, Shen G 2015 Rev. Sci. Instrum. 86 072208 Google Scholar
[15]	Sinogeikin S V, Smith J S, Rod E, Lin C, Kenney-Benson C, Shen G 2015 Rev. Sci. Instrum. 86 072209 Google Scholar
[16]	Evans W J, Yoo C S, Lee G W, Cynn H, Lipp M J, Visbeck K 2007 Rev. Sci. Instrum. 78 073904 Google Scholar
[17]	Jenei Z, Liermann H P, Husband R, Méndez A S J, Pennicard D, Marquardt H, O'Bannon1 E F, Pakhomova A, Konopkova Z, Glazyrin K, Wendt M, Wenz S, McBride E E, Morgenroth W, Winkler B, Rothkirch A, Hanfland M, Evans W J 2019 Rev. Sci. Instrum. 90 065114 Google Scholar
[18]	Lin C, Liu X, Yong X, John S T, Smith J S, English N J, Wang B, Li M, Yang W, Mao H K 2020 P. Nation. Acad. Sci. 117 15437 Google Scholar
[19]	Lin C, Liu X, Yang D, Li X, Smith J S, Wang B, Dong H, Li S, Yang W, John, S T 2020 Phys. Rev. Lett. 125 155702 Google Scholar
[20]	Lin C, Tse J S 2021 J. Phys. Chem. Lett. 12 8024 Google Scholar
[21]	Liermann H P, Damker H, Konôpková Z, Appel K, Schropp A, McWiliams S, Alexander G, Baehtz C 2016 Conceptual Design Report for Diamond Anvil Cell Setup (DAC) at the HED instrument of the European XFEL
[22]	Zhang L L, Yan S, Jiang S 2015 Nucl. Sci. Tech. 26 060101 Google Scholar
[23]	Biwer C M, Quan A, Huston L Q, Sturtevant B T, Sweeney C M 2021 Rev. Sci. Instrum. 92 103901 Google Scholar
[24]	Kumar M 1995 Phys. Condens. Matter 212 391 Google Scholar
[25]	Anzellini S, Dewaele A, Occelli F, Loubeyre P, Mezouar M 2014 J. Appl. Phys. 115 043511 Google Scholar

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