Bukowinski M S T. Effect of pressure on bonding in MgO [J]. J Geophys Res: Solid Earth, 1980, 85(B1): 285-292.
[2]
Chang K J, Cohen M L. High-pressure behavior of MgO: Structural and electronic properties [J]. Phys Rev B, 1984, 30(8): 4774-4781.
[3]
Fang Y, Yang G R, He L, et al. Analysis of the causes for abrupt drop of electronic conductivity of MgO under high pressure using first principle calculation [J]. Journal of Southwest University (Natural Science Edition), 2009, 31(9): 93-96. (in Chinese)
Bukowinski M S T, Hauser J. Pressure induced metallization of SrO and BaO: Theoretical estimate of transtion pressures [J]. Geophys Res Lett, 1980, 7(9): 689-692.
[6]
Gaffney E S, Ahrens T J. Optical absorption spectra of ruby and periclase at high shock pressures [J]. J Geophyis Res, 1973, 78(26): 5942-5953.
[7]
Schmitt D R, Ahrens T J. Emission spectra of shock compressed solids [C]//Asay J R, Graham R A, Struab G K. Shock Waves in Condensed Matter 1983. Amsterdam: Elsevier Science Publishers B V, 1984: 313-316.
[8]
Schmitt D R, Svendsen B, Ahrens T J. Shock induced radiation from minerals [C]//Gupta Y M. Shock Waves in Condensed Matter-1985. New York and London: Plenum Press, 1986: 261-265.
[9]
Svendsen B, Ahrens T J. Shock-induced temperatures of MgO [J]. Geophys J Int, 1987, 91(3): 667-691.
[10]
Gager W B, Klein M J, Jones W H. The generation of vacancies in MgO single crystals by explosive shock [J]. Appl Phys Lett, 1964, 5(7): 131-132.
[11]
Wang Q S, Holzwarth N A W. Electronic structure of vacancy defects in MgO crystals [J]. Phys Rev B, 1990, 41(5): 3211-3225.
[12]
Gibson A, Haydock R, Lapemina J P. Stability of vacancy defects in MgO: The role of charge neutrality [J]. Phys Rev B, 1994, 50(4): 2582-2592.
[13]
Meyers M A, Chawla K K. Mechanical Behavior of Materials [M]. 2nd ed. New York: Cambridge University Press, 2009: 259.
[14]
Klein M J, Gager W B. Generation of vacancies in MgO by deformation [J]. J Appl Phys, 1966, 37(11): 4112-4116.
[15]
Li J, Zhou X M, Li J B. A time-resolved single-pass technique for measuring optical absorption coefficients of window materials under 100 GPa shock pressures [J]. Rev Sci Instrum, 2008, 79(12): 123107.
[16]
Goto T, Ahrens T J, Rossman G R, et al. Absorption spectrum of shock-compressed Fe2+-bearing MgO and the radiative conductivity of the lower mantle [J]. Phys Earth Planet Inter, 1980, 22(3/4): 277-288.
[17]
McQueen R G, Hopson J W, Fritz J N. Optical technique for determining rarefaction wave velocities at very high pressures [J]. Rev Sci Instrum, 1982, 53(2): 245-250.
[18]
Gogulya M F. Temperatures of Shock Compression of Condensed Matter [M]. Moscow: MIFI, 1988: 3-10.
[19]
Weng J D, Tan H, Wang X, et al. Optical-fiber interferometer for velocity measurements with picosecond resolution [J]. Appl Phys Lett, 2006, 89(11): 111101.
[20]
Cao X X, Lu T C, Zhou X M. Optical scattering extinction in shocked sapphire by theoretical calculation [J]. Journal of Atomic and Molecular Physics, 2011, 28(3): 485-493. (in Chinese)
Monge M A, Popov A I, Ballesteros C, et al. Formation of anion-vacancy clusters and nanocavities in thermochemically reduced MgO single crystals [J]. Phys Rev B, 2000, 62(14): 9299-9304.
[23]
Gonzalez R, Vergara I, CaceresD, et al. Role of hydrogen and lithium impurities in radiation damage in neutron-irradiated MgO single crystals [J]. Phys Rev B, 2002, 65(22): 224108.
[24]
Caceres D, Vergara I, Gonzalez R, et al. Effect of neutron irradiation on hardening in MgO Crystals [J]. Phys Rev B, 2002, 66(2): 024111.
[25]
Kvatchadze V, Kalabegishvili T, Vylet V, et al. Ceramic MgO: LiF: promising material for selective detector [J]. Radiat Effect Defect Solid, 2006, 151(5): 305-311.
[26]
Henderson B. Anion vacancy centers in alkaline earth oxides [J]. Critic Revn Solid State Mater Sci, 1980, 9(1): 1-60.
[27]
Kappers L A, Kroes R L, Hensley E B. F+ and F' centers in magnesium oxide [J]. Phys Rev B, 1970, 1(10): 4151-4157.
[28]
Ueda A, Mu R, Tung Y S, et al. Optically measured diffusion constants of oxygen vacancies in MgO [J]. J Phys: Conden Matt, 2001, 13(23): 5535-5544.
[29]
Turner T J, Murphy C, Schultheiss T. A study of the effect of deformation on optical absorption of MgO single crystals [J]. Phys Stat Solid (b), 1973, 58(2): 843-857.
[30]
Underhill P R, Gallon T E. The surface defect peak in the electron energy loss spectrum of MgO (100) [J]. Solid State Commun, 1982, 43(1): 9-11.
[31]
Liu J, Ruan Y F, Ma P F, et al. Radiation damage and recovery of neutron irradiated MgO crystal [J]. Journal of Synthetic Crystals, 2005, 34(3): 496-499. (in Chinese)
Umemoto K, Wentzcovitch R M, Allen P B. Dissociation of MgSiO3 in the cores of gas giants and terrestrial exoplanets [J]. Science, 2006, 311(5763): 983-986.
[34]
McWilliams R S, Spaulding D K, Eggert J H, et al. Phase transformations and metallization of magnesium oxide at high pressure and temperature [J]. Science, 2012, 38(6112): 1330-1333.
[35]
Stevens G D, Veeser L R, Rigg P A, et al. Suitability of magnesium oxide as a VISAR window [C]//Shock Compression of Condensed Matter-2005. Atlanta: American Institute of Physics, 2006: 1353-1356.
[36]
Liberman D A. Self-consistent field electronic structure calculations for compressed magnesium oxide [J]. J Phys Chem Solids, 1978, 39(3): 255-257.
