A distinctive HPHT platform with different types of large-volume press subsystems at SECUF

A distinctive HPHT platform with different types of large-volume press subsystems at SECUF

Large-volume presses (LVPs) providing large volumes, liquid media, deformation capability, jump compression, and in situ measurements are in great demand for high-pressure research, particularly in the fields of geoscience, condensed matter physics, material science, chemistry, and biology. A high-p...

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Veröffentlicht in:Matter and radiation at extremes 2024-11, Vol.9 (6), p.063801-063801-15
Hauptverfasser: Ge, Yufei, Ma, Shuailing, You, Cun, Hu, Kuo, Liu, Chuang, Wang, Yixuan, Wang, Xinglin, Li, Xinyang, Li, Hongyu, Tao, Qiang, Jiang, Shuqing, Wang, Lu, Tang, Hu, Yao, Di, He, Zhi, Yang, Xinyi, Liu, Zhaodong, Zhou, Qiang, Zhu, Pinwen, Zou, Bo, Liu, Bingbing, Cui, Tian
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container_issue 6
container_start_page 063801
container_title Matter and radiation at extremes
container_volume 9
creator Ge, Yufei
Ma, Shuailing
You, Cun
Hu, Kuo
Liu, Chuang
Wang, Yixuan
Wang, Xinglin
Li, Xinyang
Li, Hongyu
Tao, Qiang
Jiang, Shuqing
Wang, Lu
Tang, Hu
Yao, Di
He, Zhi
Yang, Xinyi
Liu, Zhaodong
Zhou, Qiang
Zhu, Pinwen
Zou, Bo
Liu, Bingbing
Cui, Tian
description Large-volume presses (LVPs) providing large volumes, liquid media, deformation capability, jump compression, and in situ measurements are in great demand for high-pressure research, particularly in the fields of geoscience, condensed matter physics, material science, chemistry, and biology. A high-pressure and high-temperature (HPHT) platform with different LVP subsystems, both solid-state and liquid environments, and nonequilibrium subsystems, has been constructed at the Synergetic Extreme Condition User Facility, Jilin University. This article describes the construction of the different subsystems and provides an overview of the capabilities and characteristics of the different HPHT subsystems. A large sample volume (1000 mm3) at 20 GPa is achieved through the use of a belt-type apparatus in the solid-state subsystem. HPHT conditions (1.8 GPa and 1000 K) are realized in the liquid subsystem through the use of a piston–cylinder-type LVP with optical diamond windows for in situ spectroscopic measurements. A maximum pressure jump to 10.2 GPa can be reached within 20 ms in the nonequilibrium subsystem with the use of an improved bladder-pressurization jump press. Some typical results obtained with different LVPs are briefly reviewed to illustrate the applications and advantages of these presses. In summary, the platform described here has the potential to contribute greatly to high-pressure research and to innovations in high-pressure technology.
doi_str_mv 10.1063/5.0205477
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title A distinctive HPHT platform with different types of large-volume press subsystems at SECUF
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