[1] Irifune T, Kurio A, Sakamoto S, et al. Materials: Ultrahard polycrystalline diamond from graphite [J]. Nature, 2003, 421: 599-600.
[2] Qin J Q, He D W, Wang J H, et al. Is Rhenium diboride a superhard material? [J]. Adv Mater, 2008, 20(24): 4780-4783.
[3] Tian Y J, Xu B, Yu D L, et al. Ultrahard nanotwinned cubic boron nitride [J]. Nature, 2013, 493: 385-388.
[4] Xu C, He D W, Wang H K, et al. Nano-polycrystalline diamond formation under ultra-high pressure [J]. Int J Refract Metals Hard Mater, 2013, 36: 232-237.
[5] Oganov A R, Ono S. Theoretical and experimental evidence for a post-perovskitephase of MgSiO3 in Earth's D layer [J]. Nature, 2004, 430: 445-448.
[6] Ma Y M, Eremets M, Oganov A R, et al. Transparent dense sodium [J]. Nature, 2009, 458: 182-185.
[7] Hemley R J, Soos Z G, Hanfland M, et al. Charge-transfer states in dense hydrogen charge-transfer states in dense hydrogen [J]. Nature, 1994, 369: 384-387.
[8] Wang H K, He D W, Xu C, et al. Calibration of pressure to 35 GPa for the cubic press using the diamond-cemented carbide compound anvil [J]. Acta Phys Sin, 2013, 62(18): 180703. (in Chinese).
[9] 王海阔, 贺端威, 许超, 等. 复合型多晶金刚石末级压砧的制备并标定六面顶压机6-8型压腔压力至35 GPa [J]. 物理学报, 2013, 62(18): 180703.
[10] Dubrovinsky L, Dubrovinskaia N, Prakapenka V B, et al. Implementation of micro-ball nanodiamond anvils for high-pressure studies above 6 Mbar [J]. Nat Commun, 2012, 3: 1163.
[11] Jayaraman A. Ultrahigh pressures [J]. Rev Sci Instrum, 1986, 57(6): 1013-1031.
[12] Andrault D, Fiquet G. Synchrotron radiation and laser heating in a diamond anvil cell [J]. Rev Sci Instrum, 2001, 72(2): 1283-1288.
[13] Klotz S, Besson J M, Hamel G, et al. Neutron powder diffraction at pressures beyond 25 GPa [J]. Appl Phys Lett, 1995, 66(14): 1735-1737.
[14] Fan D W, Wei S Y, Xie H S. An in situ high-pressure X-ray diffraction experiment on hydroxyapophyllite [J]. Chinese Physics B, 2013, 22: 010702.
[15] Sung C M. A century of progress in the development of very high pressure apparatus for scientific research and diamond synthesis [J]. High Temp-High Press, 1997, 29: 253-293.
[16] He D W, Wang H K, Tan N, et al. An anvil-preformed gasket apparatus: China, 201010142804. 7 [P]. 2010-08-18. (in Chinese).
[17] 贺端威, 王海阔, 谭宁, 等. 一种顶锤-预密封边高压装置: 中国, 201010142804. 7 [P]. 2010-08-18.
[18] Wang H K, He D W. A new large-volume high pressure apparatus: China, 201110091480. 3 [P]. 2011-09-21. (in Chinese).
[19] 王海阔, 贺端威. 一种新型大腔体高压装置: 中国, 201110091480. 3 [P]. 2011-09-21.
[20] Li Z C, Jia X P, Huang G F, et al. FEM simulations and experimental studies of the temperature field in a large diamond crystal growth cell [J]. Chinese Physics B, 2013, 22: 014701.
[21] Yu G, Han Q G, Li M Z, et al. Finite element analysis of the high-pressure tungsten carbide radius-anvil [J]. Acta Phys Sin, 2012, 61: 040702. ( in Chinese).
[22] 于歌, 韩奇钢, 李明哲, 等. 新型圆角式高压碳化钨硬质合金顶锤的有限元分析 [J]. 物理学报, 2012, 61: 040702.
[23] Khvostantsev L G. A verkh-niz (up-down) toroid device for generation of high pressure [J]. High Temp-High Pressure, 1984, 16: 165-169.
[24] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 8-13. (in Chinese).
[25] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 8-13.
[26] Wang H K, He D W, Tan N, et al. An anvil-preformed gasket system to extend the pressure range for large volume cubic presses [J]. Rev Sci Instrum, 2010, 81: 116101.
[27] Wang H K, He D W, Yan X Z, et al. Quantitative measurements of pressure gradients for the pyrophyllite and magnesium oxide pressure-transmitting mediums to 8 GPa in a large-volume cubic cell [J]. High Press Res, 2011, 31: 581-591.
[28] Wang H K, He D W. A hybrid pressure cell of pyrophyllite and magnesium oxide to extend the pressure range for large volume cubic presses [J]. High Press Res, 2012, 32: 186-194.
[29] Liebermann Robert C, Wang Y B. High-Pressure Research: Application to Earth and Planetary Sciences [M]. Washington DC: AGU. 1992: 19.
[30] Tange Y, Irifune T, Funakoshi K, et al. Pressure generation to 80 GPa using multianvil apparatus with sintered diamond anvils [J]. High Press Res, 2008, 28: 245-254.
[31] Kunimoto T, Irifune T. Pressure generation to 125 GPa using a 6-8-2 type multianvil apparatus with nano-polycrystalline diamond anvils [J]. J Phys: Conf Ser, 2010, 215: 02190.
[32] Wang F L, He D W, Fang L M, et al. Design and assembly of split-sphere high pressure apparatus based on the hinge-type cubic-anvil press [J]. Acta Phys Sin, 2008, 57: 5429-5434. (in Chinese).
[33] 王福龙, 贺端威, 房雷鸣, 等. 基于铰链式六面顶压机的二级6-8型大腔体静高压装置 [J]. 物理学报, 2008, 57: 5429-5434.
[34] Wang W D, He D W, Wang H K, et al. Reaserch on pressure generation efficiency of 6-8 type multianvil high pressure apparatus [J]. Acta Phys Sin, 2010, 59: 3107. (in Chinese).
[35] 王文丹, 贺端威, 王海阔, 等. 二级6-8型大腔体装置的高压发生效率机理研究 [J]. 物理学报, 2010, 59: 3107-3115.
[36] Guan J W, He D W, Wang H K, et al. Influence of mechanical configuration and hardness of last stage anvil on high pressure producing efficiency for octahedral cell [J]. Acta Phys Sin, 2012, 61: 100701. (in Chinese).
[37] 管俊伟, 贺端威, 王海阔, 等. 力学结构及末级压砧硬度对八面体压腔高压发生效率的影响 [J]. 物理学报, 2012, 61: 100701.
[38] Daniels W B, Jones M T. Simple apparatus for the generation of pressures above 100000 atmospheres simultaneously with temperatures above 3000 ℃ [J]. Rev Sci Instrum, 1961, 32: 885-888.
[39] Xi L, Chen J L, Tang J J, et al. A large volume cubic press with a pressure-generating capability up to about 10 GPa [J]. High Press Res, 2012, 32: 239-254.
[40] Fang L M, He D W, Chen C, et al. Effect of precompression on pressure-transmitting efficiency of pyrophyllite gaskets [J]. High Press Res, 2007, 27: 367-374.
[41] Andersson G, Sundqvist B, Backstrom G. A high-pressure cell for electrical resistance measurements at hydrostatic pressures up to 8 GPa: Results for Bi, Ba, and Si [J]. J Appl Phys, 1989, 65(10): 3943.
[42] Ma H A, Jia X P, Chen L X, et al. High-pressure pyrolysis study of C3N6H6: A route to preparing bulk C3N4 [J]. J Phys Condens Matter, 2002, 14: 11269-11273.
[43] Wentorff R H, Bundy F P. Modern Very High Pressure Techniques [M]. London: Butterworths, 1962: 1-24.
[44] Duffy T S, Hemley R J, Mao H K. Equation of state and shear strength at multimegabar pressures: Magnesium oxide to 227 GPa [J]. Phys Rev Lett, 1995, 74: 1371-1374.
[45] Perez-Albuerne E A, Drickamer H G. Effect of high pressures on the compressibilities of seven crystals having the NaCl or CsCl structure [J]. J Chem Phys, 1965, 43: 1381-1386.
[46] Lloyd E C. Accurate Characterization of the High Pressure Environment: Proceedings of a Symposium Held at the National Bureau of Standards [M]. Washington, DC: NBS Special Publication, 1971: 189.
[47] Mao H K, Bell P M. Equations of state of MgO and -Fe under static pressure conditions [J]. J Geophys Res, 1979, 84: 4533-4536.
[48] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 14. (in Chinese).
[49] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 14.
[50] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 87-109. (in Chinese).
[51] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 87-109.
[52] L S J, Luo J T, Shu L, et al. A slide-type multianvil ultrahigh pressure apparatus and calibrations of its pressure and temperature [J]. Acta Phys Sin, 2009, 58: 6852-6857. (in Chinese).
[53] 吕世杰, 罗建太, 苏磊, 等. 滑块式六含八超高压实验装置及其压力温度标定 [J]. 物理学报, 2009, 58: 6852-6857.
[54] Frost D J, Poe B T, Trnnes R G, et al. A new large-volume multianvil system [J]. Phys Earth Planet Int, 2004, 143-144: 507-514.
[55] Getting I C. New determination of the bismuth Ⅰ-Ⅱ equilibrium pressure: A proposed modification to the practical pressure scale [J]. Metrologia, 998, 35: 119.
[56] Lloyd E C. Accurate Characterization of the High-pressure Environment: Proceedings of a Symposium Held at the National Bureau of Standards [M]. Washington, DC: NBS Special Publication, 1971: 326.
[57] Ohtani A, Motobayashi M, Onodera A. Polymorphism of ZnTe at elevated pressure [J] . Phys Lett A, 1980, 75: 435-437.
[58] Ovsyannikov S V, Shchennikov V V. Application of the high-pressure thermoelectric technique for characterization of semiconductor microsamples: PbX-based compounds [J]. Solid State Commun, 2004, 37: 1151.
[59] Jiang J Z, Gerward L, Frost D, et al. Grain-size effect on pressure-induced semiconductor-to-metal transition in ZnS [J]. J Appl Phys, 1999, 86: 6608-6610.
[60] Yagi T, Akimoto S. Direct determination of coesite-stishovite transition by in-situ X-ray measurements [J]. J Appl Phys, 1976, 47: 259-270.
[61] Xu C, He D W, Wang H K, et al. Synthesis of nano-polycrystalline diamond under high pressure and high temperature [J]. Superhard Material Engineering, 2011, 4: 001-003. (in Chinese).
[62] 许超, 贺端威, 王海阔, 等. 纳米聚晶金刚石的高压高温合成 [J]. 超硬材料工程, 2011, 4: 001-003.
[63] Kawazoe T, Nishiyama N, Nishihara Y, et al. Pressure generation to 25 GPa using a cubic anvil apparatus with a multi-anvil 6-6 assembly [J]. High Press Res, 2010, 30: 167-174.
[64] Wang H K, He D W, Xu C, et al. Nanostructured diamond-TiC composites with high fracture toughness [J]. J Appl Phys, 2013, 113: 043505.
[65] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 113-129. (in Chinese).
[66] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 113-129.
[67] Lorenzana H E, Boppart H, Silvera I F. Study of pressure distributions in a megabar diamond indentor cell [J]. Rev Sci Instrum, 1988, 59: 2583-2591.
[68] Tange Y, Takahashi E, Funakoshi K. In situ observation of pressure-induced electrical resistance changes in zirconium: Pressure calibration points for the large volume press at 8 and 35 GPa [J]. High Press Res, 2011, 31: 413-418.
[69] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 131-140. (in Chinese).
[70] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 131-140.
[71] Wang H K. Development and application of pressure generation techniques based on hinge-type cubic press [D]. Chengdu: Institute of Atomic and Molecular Physics, Sichuan University, 2008: 63-84. (in Chinese).
[72] 王海阔. 基于国产六面顶压机增压装置的压力产生极限扩展与应用 [D]. 成都: 四川大学原子分子物理研究所, 2008: 63-84.