Pressure generation under deformation in a large-volume press

doi:10.1088/1674-1056/ad58c6

Abstract Deformation can change the transition pathway of materials under high pressure, thus significantly affects physical and chemical properties of matters. However, accurate pressure calibration under deformation is challenging and thereby causes relatively large pressure uncertainties in deformation experiments, resulting in the synthesis of complex multiphase materials. Here, pressure generations of three types of deformation assemblies were well calibrated in a Walker-type large-volume press (LVP) by electrical resistance measurements combined with finite element simulations (FESs). Hard Al$_{2}$O$_{3}$ or diamond pistons in shear and uniaxial deformation assemblies significantly increase the efficiency of pressure generation compared with the conventional quasi-hydrostatic assembly. The uniaxial deformation assembly using flat diamond pistons possesses the highest efficiency in these deformation assemblies. This finding is further confirmed by stress distribution analysis based on FESs. With this deformation assembly, we found shear can effectively promote the transformation of C$_{60}$ into diamond under high pressure and realized the synthesis of phase-pure diamond at relatively moderate pressure and temperature conditions. The present developed techniques will help improve pressure efficiencies in LVP and explore the new physical and chemical properties of materials under deformation in both science and technology.

Keywords: shear/uniaxial deformation pressure calibration finite element simulations large-volume press high pressure

Received: 18 April 2024
Revised: 06 June 2024
Accepted manuscript online: 17 June 2024

PACS:	81.40.Lm	(Deformation, plasticity, and creep)
	07.35.+k	(High-pressure apparatus; shock tubes; diamond anvil cells)
	62.50.-p	(High-pressure effects in solids and liquids)
	81.40.Vw	(Pressure treatment)

Fund: We acknowledge Yankun Yin for SEM analysis. Project supported by the National Natural Science Foundation of China (Grant Nos. 42272041, 41902034, 52302043, 12304015, 52302043, and 12011530063), the National Major Science Facility Synergetic Extreme Condition User Facility Achievement Transformation Platform Construction (Grant No. 2021FGWCXNLJSKJ01), the China Postdoctoral Science Foundation (Grant Nos. 2022M720054 and 2023T160257), the National Key Research and Development Program of China (Grant No. 2022YFB3706602), and the Jilin University High-level Innovation Team Foundation, China (Grant No. 2021TD-05).

Corresponding Authors: Kuo Hu, Yuchen Shang, Zhaodong Liu
E-mail: hukuo@jlu.edu.cn;shangyc@jlu.edu.cn;liu_zhaodong@jlu.edu.cn

Cite this article:

Saisai Wang(王赛赛), Xinyu Zhao(赵鑫宇), Kuo Hu(胡阔), Bingtao Feng(丰丙涛), Xuyuan Hou(侯旭远), Yiming Zhang(张羿鸣), Shucheng Liu(刘书成), Yuchen Shang(尚宇琛), Zhaodong Liu(刘兆东), Mingguang Yao(姚明光), and Bingbing Liu(刘冰冰) Pressure generation under deformation in a large-volume press 2024 Chin. Phys. B 33 098104

[1] Regueiro M N, Monceau P and Hodeau J L 1992 Nature 355 237
[2] Dong J J, Yao Z, Yao M G, Li R, Hu K, Zhu L Y, Wang Y, Sun H H, Sundqvist B, Yang K and Liu B B 2020 Phys. Rev. Lett. 124 065701
[3] Serebryanaya N R, Blank V D, Ivdenko V A and Chernozatonskii L A 2001 Solid State Commun. 118 183
[4] Gao Y, Ma Y Z, An Q, Levitas V, Zhang Y Y, Feng B, Chaudhuri J and Goddard W A 2019 Carbon 146 364
[5] Tyukalova E, Kulnitskiy B, Perezhogin I, Kirichenko A and Blank V In Society EM ed. European Microscopy Congress 2016: Proceedings Weinheim (Germany: Wiley-VCH Verlag GmbH & Co. KGaA 2016 303)
[6] Zhang S Q, Karato S, Fitz Gerald J, Faul U H and Zhou Y 2000 Tectonophysics 316 133
[7] Karato S, Zhang S Q and Wenk H R 1995 Science 270 458
[8] Levitas V I, Ma Y Z, Hashemi J, Holtz M and Guven N 2006 J. Chem. Phys. 125 044507
[9] Kawazoe T, Karato S, Otsuka K, Jing Z C and Mookherjee M 2009 Physics of the Earth and Planetary Interiors 174 128
[10] Wang Y B, Durham W B, Getting I C and Weidner D J 2003 Rev. Sci. Instrum. 74 3002
[11] Nishiyama N, Wang Y B, Sanehira T, Irifune T and Rivers M 2008 High Pressure Res. 28 307
[12] Ohuchi T, Kawazoe T, Nishiyama N, Yu N and Irifune T 2010 J. Earth Sci. 21 523
[13] Li L B 2018 Chin. J. Polym. Sci. 36 1093
[14] Ves S, Schwarz U, Christensen N E, Syassen K and Cardona M 1990 Phys. Rev. B 42 9113
[15] Wang L, Blaha S, Kawazoe T, Miyajima N and Katsura T 2017 Geophys. Res. Lett. 44 2687
[16] Wang L, Blaha S, Pintér Z, Farla R, Kawazoe T, Miyajima N, Michibayashi K and Katsura T 2016 Earth and Planetary Science Letters 441 81
[17] Karato S and Rubie D C 1997 J. Geophys. Res. 102 20111
[18] Wang L, Chanyshev A, Miyajima N, Kawazoe T, Blaha S, Chang J and Katsura T 2022 Earth and Planetary Science Letters 579 117360
[19] Wang L, Miyajima N, Kawazoe T and Katsura T 2019 American Mineralogist 104 47
[20] Demouchy S, Tommasi A, Barou F, Mainprice D and Cordier P 2012 Physics of the Earth and Planetary Interiors 202-203 56
[21] Katayama I and Karato S 2008 Physics of the Earth and Planetary Interiors 168 125
[22] Holtzman B K, Groebner N J, Zimmerman M E, Ginsberg S B and Kohlstedt D L 2003 Geochem. Geophys. Geosyst. 4 8607
[23] Shang Y C, Shen F R, Hou X Y, Chen L Y, Hu K, Li X, Liu R, Tao Q, Zhu P W, Liu Z D, Yao M G, Zhou Q, Cui T and Liu B B 2020 Chin. Phys. Lett. 37 080701
[24] Zhuang Y K, Dai L D, Li H P, Hu H Y, Liu K X, Yang L F, Pu C and Hong M 2018 Mod. Phys. Lett. B 32 1850342
[25] Shang Y C, Liu Z D, Dong J J, Yao M G, Yang Z X, Li Q Q, Zhai C G, Shen F R, Hou X Y, Wang L, Zhang N Q, Zhang W, Fu R, Ji J F, Zhang X M, Lin H, Fei Y W, Sundqvist B, Wang W H and Liu B B 2021 Nature 599 599
[26] Horikawa T, Suito K, Kobayashi M and Onodera A 2001 Phys. Lett. A 287 143
[27] Wood R A, Lewis M H, Bennington S M, Cain M G, Kitamura N and Fukumi A K 2002 J. Phys.: Condens. Matter 14 11615
[28] Brazhkin V V and Lyapin A G 2012 J. Superhard Mater. 34 400

1. .pdf(699KB)

[1]	First-principles study on stability and superconductivity of ternary hydride LaYH_x (x =2, 3, 6 and 8) Xiao-Zhen Yan(颜小珍), Xing-Zi Zhou(周幸姿), Chao-Fei Liu(刘超飞), Yin-Li Xu(徐寅力), Yi-Bin Huang(黄毅斌), Xiao-Wei Sheng(盛晓伟), and Yang-Mei Chen(陈杨梅). Chin. Phys. B, 2024, 33(8): 086301.
[2]	First-principles study of structural and electronic properties of multiferroic oxide Mn₃TeO₆ under high pressure Xiao-Long Pan(潘小龙), Hao Wang(王豪), Lei Liu(柳雷), Xiang-Rong Chen(陈向荣), and Hua-Yun Geng(耿华运). Chin. Phys. B, 2024, 33(7): 076102.
[3]	Pressure-induced magnetic phase and structural transition in SmSb₂ Tao Li(李涛), Shuyang Wang(王舒阳), Xuliang Chen(陈绪亮), Chunhua Chen(陈春华), Yong Fang(房勇), and Zhaorong Yang(杨昭荣). Chin. Phys. B, 2024, 33(6): 066401.
[4]	Unveiling the pressure-driven metal-semiconductor-metal transition in the doped TiS₂ Jiajun Chen(陈佳骏), Xindeng Lv(吕心邓), Simin Li(李思敏), Yaqian Dan(但雅倩), Yanping Huang(黄艳萍), and Tian Cui(崔田). Chin. Phys. B, 2024, 33(6): 067104.
[5]	High-pressure study on calcium azide (Ca(N₃)₂): Bending of azide ions stabilizes the structure Xiaoxin Wu(武晓鑫), Yingjian Wang(王颖健), Siqi Li(李思琪), Juncheng Lv(吕俊呈), Jingshu Wang(王婧姝), Lihua Yang(杨丽华), Qi Zhang(张旗), Yanqing Liu(刘艳清), Junkai Zhang(张俊凯), and Hongsheng Jia(贾洪声). Chin. Phys. B, 2024, 33(5): 056201.
[6]	Stability and melting behavior of boron phosphide under high pressure Wenjia Liang(梁文嘉), Xiaojun Xiang(向晓君), Qian Li(李倩), Hao Liang(梁浩), and Fang Peng(彭放). Chin. Phys. B, 2024, 33(4): 046201.
[7]	Robust T_c in element molybdenum up to 160 GPa Xinyue Wu(吴新月), Shumin Guo(郭淑敏), Jianning Guo(郭鉴宁), Su Chen(陈诉), Yulong Wang(王煜龙), Kexin Zhang(张可欣), Chengcheng Zhu(朱程程), Chenchen Liu(刘晨晨), Xiaoli Huang(黄晓丽), Defang Duan(段德芳), and Tian Cui(崔田). Chin. Phys. B, 2024, 33(4): 047406.
[8]	Pressure-induced structural, electronic, and superconducting phase transitions in TaSe₃ Yuhang Li(李宇航), Pei Zhou(周佩), Chi Ding(丁驰), Qing Lu(鲁清), Xiaomeng Wang(王晓梦), and Jian Sun(孙建). Chin. Phys. B, 2024, 33(10): 106102.
[9]	Thermal conductivity of iron under the Earth's inner core pressure Cui-E Hu(胡翠娥), Mu-Xin Jiao(焦亩鑫), Xue-Nan Yang(杨学楠), Zhao-Yi Zeng(曾召益), and Jun Chen(陈军). Chin. Phys. B, 2024, 33(10): 106501.
[10]	Recension of boron nitride phase diagram based on high-pressure and high-temperature experiments Ruike Zhang(张瑞柯), Ruiang Guo(郭睿昂), Qian Li(李倩), Shuaiqi Li(李帅琦), Haidong Long(龙海东), and Duanwei He(贺端威). Chin. Phys. B, 2024, 33(10): 108103.
[11]	Ultrafast dynamics in photo-excited Mott insulator Sr₃Ir₂O₇ at high pressure Xia Yin(尹霞), Jianbo Zhang(张建波), Wang Dong(王东), Takeshi Nakagawa, Chunsheng Xia(夏春生), Caoshun Zhang(张曹顺), Weicheng Guo(郭伟程), Jun Chang(昌峻), and Yang Ding(丁阳). Chin. Phys. B, 2024, 33(1): 016103.
[12]	High-pressure and high-temperature sintering of pure cubic silicon carbide: A study on stress-strain and densification Jin-Xin Liu(刘金鑫), Fang Peng(彭放), Guo-Long Ma(马国龙), Wen-Jia Liang(梁文嘉), Rui-Qi He(何瑞琦), Shi-Xue Guan(管诗雪), Yue Tang(唐越), and Xiao-Jun Xiang(向晓君). Chin. Phys. B, 2023, 32(9): 098101.
[13]	New carbon-nitrogen-oxygen compounds as high energy density materials Junyu Shen(沈俊宇), Qingzhuo Duan(段青卓), Junyi Miao(苗俊一), Shi He(何适),Kaihua He(何开华), Wei Dai(戴伟), and Cheng Lu(卢成). Chin. Phys. B, 2023, 32(9): 096302.
[14]	Pressure induced insulator to metal transition in quantum spin liquid candidate NaYbS₂ Yating Jia(贾雅婷), Chunsheng Gong(龚春生), Zhiwen Li(李芷文), Yixuan Liu(刘以轩), Jianfa Zhao(赵建发), Zhe Wang(王哲), Hechang Lei(雷和畅), Runze Yu(于润泽), and Changqing Jin(靳常青). Chin. Phys. B, 2023, 32(9): 096201.
[15]	New MgO-H₂O compounds at extreme conditions Lanci Guo(郭兰慈) and Jurong Zhang(张车荣). Chin. Phys. B, 2023, 32(7): 076201.

No Suggested Reading articles found!

Viewed

Full text

Abstract

Cited

Metrics
Related Articles

Pressure generation under deformation in a large-volume press

Cite this article:

Online attention