[1] FREY G, CHEETHAM A K. Prospects for giant pores[J]. Science,1999, 283(5405): 1 125-1 126 . [2] LIN R H, DING Y J. A review on the synthesis and applications of mesostructured transition metal phosphates[J]. Materials, 2013, 6(1): 217-243. [3] CHEETHAM A K, FREY G, LOISEAU T. Open-framework inorganic materials[J]. Angewandte Chemie International Edition,1999, 38(22):3 268-3 292. [4] FORSTER P M, ECKERT J, CHANG J S, et al. Hydrogen adsorption in nanoporous nickel(II) phosphates[J]. Journal of the American Chemical Society ,2003,125(5): 1 309-1 312. [5] GUILLOU N, GAO Q M, NOGUES M, et al. Zeolitic and magnetic properties of a 24-membered ring porousnickel(ll) phosphate, VSB-1[J]. Comptes Rendus de lAcadémie des Sciences-Series II C - Chemistry,1999,2(7/8): 387-392. [6] CHANG J S, PARK S E, GAO Q M, et al. Catalytic conversion of butadiene to ethylbenzene over the nanoporous nickel(II) phosphate, VSB-1[J]. Chemical Communications,2001, 9(9): 859-860. [7] TIMOFEEVA M N, PANCHENKO V N, HASAN Z, et al. Catalytic potential of the wonderful chameleons: Nickel phosphate molecular sieves[J]. Applied Catalysis A: General,2013, 455: 71-85. [8] NIE S B, ZHANG C, PENG C, et al. Study of the synergistic effect of nanoporous nickel phosphates on novel intumescent flame retardant polypropylene composites[J]. Journal of Spectroscopy,2015, 2015:289298. [9] NIE S B, HU Y, SONG L, et al. Study on a novel and efficient flame retardant synergist-nanoporous nickel phosphates VSB-1 with intumescent flame retardants in polypropylene[J]. Polymers for Advanced Technologies,2008, 19(6): 489-495. [10] WU H Y, LIU M, TAN W, et al. Effect of ZSM-5 zeolite morphology on the catalytic performance of the alkylation of toluene with methanol[J]. Journal of Energy Chemistry,2014, 23(4): 491-497. [11] LEE H J, KIM S H, KIM J H, et al.Synthesis and characterization of zeolites MTT and MFI, with controlled morphologies using mixed structure directing agents[J]. Microporous and Mesoporous Materials,2014, 195: 205-215. [12] JHUNG S H, YOON J W, HWANG Y K, et al. Morphology control of the nanoporous nickel phosphate VSB-5 from large crystals to nanocrystals[J]. Microporous and Mesoporous Materials,2006, 89: 9-15.
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[2] CHEN C, LIU G. Effects of axial guiding magnetic field on microwave power of backward-wave oscillators[J]. High Power Laser and Particle Beams, 2000, 12: 745-748. [3] CHEN C, LIU G, HUANG W, et al. A repetitive X-band relativistic backward-wave oscillator[J]. IEEE Trans Plasma Sci, 2000, 25: 1 108-1 111. [4] REN Y, WANG F, CHEN W, et al. Development of a superconducting magnet system for microwave application[J]. IEEE Trans Appl Supercond, 2010, 20(3): 1 912-1 915. [5] LVOVSKY Y, STAUTNER W, ZHANG T. Novel technologies and configurations of superconducting magnets for MRI[J]. Supercond Sci Technol, 2013, 26(9): 093001. [6] HIROSE R, KAMIKADO T, OKUI Y, et al. Development of 7 T cryogen-free superconducting magnet for gyrotron[J]. IEEE Trans Appl Supercond, 2008, 12: 920-923. [7] WANG Q, DAI Y, ZHAO B, et al. Design of superconducting magnet for background magnetic field[J]. IEEE Trans Appl Supercond, 2008, 18(2): 548-551. [8] CHOI Y S, KIM D L, LEE B S, et al. Conduction-cooled superconducting magnet for material control application[J]. IEEE Trans Appl Supercond, 2009, 19(3): 2 190-2 193. [9] ZHANG X, REN Y, WANG F, et al. Development of a superconducting magnet system with zero liquid helium boil-off[J]. J Supercond Novel Magn, 2014, 27(4): 1 027-1 030. [10] YAMASHITA T, NISHIJIMA S, TAKAHATA K, et al. Instability of impregnated windings induced by epoxy cracking[J]. IEEE Trans Magn, 1989, 25(2): 1 524-1 527. [11] WANG Q, DAI Y, ZHAO B, et al. Development of large-bore superconducting magnet with zero-vapor liquid helium[J]. IEEE Trans Appl Supercond, 2008, 18: 787-790. [12] CHEN P, DAI Y, WANG Q, et al. Mechanical behavior analysis of a 1 MJ SEMS magnet[J]. IEEE Trans Appl Supercond, 2010, 20(3): 1 916-1 919. |