A resistively-heated dynamic diamond anvil cell (RHdDAC) for fast compression x-ray diffraction experiments at high temperatures

被引:16
|
作者
Mendez, A. S. J. [1 ,2 ]
Marquardt, H. [3 ]
Husband, R. J. [1 ]
Schwark, I [1 ]
Mainberger, J. [1 ]
Glazyrin, K. [1 ]
Kurnosov, A. [1 ]
Otzen, C. [1 ]
Satta, N. [2 ]
Bednarcik, J. [4 ]
Liermann, H-P [4 ]
机构
[1] DESY, Photon Sci, D-22607 Hamburg, Germany
[2] Univ Bayreuth, Bayer Geoinst BGI, D-95440 Bayreuth, Germany
[3] Univ Oxford, Dept Earth Sci, Oxford OX1 3AN, England
[4] Safarik Univ, Inst Phys, Dept Condensed Matter Phys, Kosice 04154, Slovakia
来源
REVIEW OF SCIENTIFIC INSTRUMENTS | 2020年 / 91卷 / 07期
关键词
PHASE-TRANSITIONS; HIGH-PRESSURE; ALPHA-QUARTZ; ICE;
D O I
10.1063/5.0007557
中图分类号
TH7 [仪器、仪表];
学科分类号
0804 ; 080401 ; 081102 ;
摘要
A resistively-heated dynamic diamond anvil cell (RHdDAC) setup is presented. The setup enables the dynamic compression of samples at high temperatures by employing a piezoelectric actuator for pressure control and internal heaters for high temperature. The RHdDAC facilitates the precise control of compression rates and was tested in compression experiments at temperatures up to 1400 K and pressures of similar to 130 GPa. The mechanical stability of metallic glass gaskets composed of a FeSiB alloy was examined under simultaneous high-pressure/high-temperature conditions. High-temperature dynamic compression experiments on H2O ice and (Mg, Fe)O ferropericlase were performed in combination with time-resolved x-ray diffraction measurements to characterize crystal structures and compression behaviors. The employment of high brilliance synchrotron radiation combined with two fast GaAs LAMBDA detectors available at the Extreme Conditions Beamline (P02.2) at PETRA III (DESY) facilitates the collection of data with excellent pressure resolution. The pressure-temperature conditions achievable with the RHdDAC combined with its ability to cover a wide range of compression rates and perform tailored compression paths offers perspectives for a variety of future experiments under extreme conditions.
引用
收藏
页数:8
相关论文
共 50 条
  • [1] New dynamic diamond anvil cells for tera-pascal per second fast compression x-ray diffraction experiments
    Jenei, Zs.
    Liermann, H. P.
    Husband, R.
    Mendez, A. S. J.
    Pennicard, D.
    Marquardt, H.
    O'Bannon, 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.
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2019, 90 (06)
  • [2] A MHz X-ray diffraction set-up for dynamic compression experiments in the diamond anvil cell
    Husband, Rachel J.
    Strohm, Cornelius
    Appel, Karen
    Ball, Orianna B.
    Briggs, Richard
    Buchen, Johannes
    Cerantola, Valerio
    Chariton, Stella
    Coleman, Amy L.
    Cynn, Hyunchae
    Dattelbaum, Dana
    Dwivedi, Anand
    Eggert, Jon H.
    Ehm, Lars
    Evans, William J.
    Glazyrin, Konstantin
    Goncharov, Alexander F.
    Graafsma, Heinz
    Howard, Alex
    Huston, Larissa
    Hutchinson, Trevor M.
    Hwang, Huijeong
    Jacob, Sony
    Kaa, Johannes
    Kim, Jaeyong
    Kim, Minseob
    Koemets, Egor
    Konopkova, Zuzana
    Langenhorst, Falko
    Laurus, Torsten
    Li, Xinyang
    Mainberger, Jona
    Marquardt, Hauke
    McBride, Emma E.
    McGuire, Christopher
    McHardy, James D.
    McMahon, Malcolm I.
    McWilliams, R. Stewart
    Mendez, Alba S. J.
    Mondal, Anshuman
    Morard, Guillaume
    O'Bannon, Earl F.
    Otzen, Christoph
    Pepin, Charles M.
    Prakapenka, Vitali B.
    Prescher, Clemens
    Preston, Thomas R.
    Redmer, Ronald
    Roeper, Michael
    Sanchez-Valle, Carmen
    JOURNAL OF SYNCHROTRON RADIATION, 2023, 30 : 671 - 685
  • [3] X-ray diffraction in the pulsed laser heated diamond anvil cell
    Goncharov, Alexander F.
    Prakapenka, Vitali B.
    Struzhkin, Viktor V.
    Kantor, Innokenty
    Rivers, Mark L.
    Dalton, D. Allen
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2010, 81 (11)
  • [4] A novel and simple x-ray slit for diamond anvil cell based x-ray diffraction experiments
    Irshad, K. A.
    Kumar, N. R. Sanjay
    Shekar, N. V. Chandra
    MEASUREMENT SCIENCE AND TECHNOLOGY, 2017, 28 (04)
  • [5] X-ray diffraction measurements in a rotational diamond anvil cell
    Ma, Yanzhang
    Levitas, Valery I.
    Hashemi, Javad
    JOURNAL OF PHYSICS AND CHEMISTRY OF SOLIDS, 2006, 67 (9-10) : 2083 - 2090
  • [6] MHz free electron laser x-ray diffraction and modeling of pulsed laser heated diamond anvil cell
    Jaisle, Nicolas
    Cebron, David
    Konopkova, Zuzana
    Husband, Rachel J.
    Prescher, Clemens
    Cerantola, Valerio
    Dwivedi, Anand
    Kaa, Johannes M.
    Appel, Karen
    Buakor, Khachiwan
    Ball, Orianna B.
    Mcwilliams, Ryan S.
    Strohm, Cornelius
    Nakatsutsumi, Motoaki
    Zastrau, Ulf
    Baehtz, Carsten
    Anna Baron, Marzena
    Edmund, Eric
    Biswas, Joydipa
    Mchardy, James D.
    Sturtevant, Blake T.
    Ehm, Lars
    Goncharov, Alexander F.
    Mcmahon, Malcolm I.
    Buchen, Johannes
    Cynn, Hyunchae
    Pace, Edward J.
    Liermann, Hanns-Peter
    Sneed, Daniel T.
    Cooper, Samantha C.
    Anae, Madison
    Kim, Jaeyong
    Wu, Zhongyan
    Lee, Yongjae
    Hwang, Huijeong J.
    Kim, Taehyun
    Choi, Jinhyuk
    Lee, Jeongmin
    Merkel, Sebastien
    Chantel, Julien
    Koemets, Egor G.
    Marquardt, Hauke
    Prakapenka, Vitali B.
    Chariton, Stella
    Shevchenko, Elena
    Fiquet, Guillaume
    Rosa, Angelika D.
    Mezouar, Mohamed
    Garbarino, Gaston
    Morard, Guillaume
    JOURNAL OF APPLIED PHYSICS, 2023, 134 (09)
  • [7] Synchrotron X-ray diffraction tomography technique using diamond anvil cell
    Liu, Haozhe
    Wang, Luhong
    Yu, Zhanhai
    Kong, Lingping
    Hao, Jinggeng
    Dong, Dawei
    Li, Chunyu
    Liu, Zhiguo
    ACTA CRYSTALLOGRAPHICA A-FOUNDATION AND ADVANCES, 2011, 67 : C113 - C113
  • [8] A novel diamond anvil cell for x-ray diffraction at cryogenic temperatures manufactured by 3D printing
    Jin, H.
    Woodall, C. H.
    Wang, X.
    Parsons, S.
    Kamenev, K. V.
    REVIEW OF SCIENTIFIC INSTRUMENTS, 2017, 88 (03)
  • [9] In-situ X-ray diffraction measurements of the γ-ε transition boundary of iron in an internally-heated diamond anvil cell
    Komabayashi, Tetsuya
    Fei, Yingwei
    Meng, Yue
    Prakapenka, Vitali
    EARTH AND PLANETARY SCIENCE LETTERS, 2009, 282 (1-4) : 252 - 257
  • [10] Development of density measurement for metals at high pressures and high temperatures using X-ray absorption imaging combined with externally heated diamond anvil cell
    Takubo, Yusaku
    Terasaki, Hidenori
    Kondo, Tadashi
    Mitai, Shingo
    Kamada, Seiji
    Kikegawa, Takumi
    Machida, Akihiko
    COMPTES RENDUS GEOSCIENCE, 2019, 351 (2-3) : 182 - 189
12345