[1] [1] ZHOU W. Numerical Study of Multi-phase Combustion: Ignition and Combustion of An Isolated Boron Particle in Fluorinated Environments ［D］. Princeton: Princeton University, 1998.

[2] [2] DREIZIN E L. Metal-based reactive nanomaterials ［J］. Prog. Energ. Combust. Sci., 2009, 35(2): 141-167.

[3] [3] ZHUK A Z, SHEINDLIN A E, KLEYMENOV B V, et al.. Use of low-cost aluminum in electric energy production ［J］. J.Power Sources, 2006,157 (2): 921-926.

[4] [4] VLASKIN M S, SHKOLNIKOV E I, BERSH A V, et al. An experimental aluminum-fueled power plant ［J］. J.Power Sources, 2011, 196 (20): 8828-8835.

[5] [5] GALFETTI L, DE LUCA L T, SEVERINI F, et al.. Nanoparticles for solid rocket propulsion ［J］. J. Phys.: Condens. Matter, 2006, 18 (33SI): 1991-2005.

[6] [6] WAN J, CAI SH ZH, LIU Y, et al.. Study on reaction characteristic of aluminum powder with water applied to propellant［J］. Journal of Solid Rocket Technology, 2012(2): 207-211.

[7] [7] BAZYN T, KRIER H, GLUMAC N. Combustion of nanoaluminum at elevated pressure and temperature behind reflected shock waves ［J］. Combust. Flame, 2006, 145: 703-713.

[8] [8] KRIER H, BURTON R L, SPALDING M J, et al.. Ignition Dynamics of Boron Particles in a Shock Tube ［J］. J. Propul.Power, 1998, 14(2): 166-172.

[9] [9] SPALDING M J, KRIER H, BURTON R L. Boron suboxides measured during ignition and combustion of boron in shocked Ar/F/O2 and Ar/N2/O2 mixtures ［J］. Combust. Flame, 2000(120): 200-210.

[10] [10] FOELSCHE R O, BURTON R L, KRIER H. Boron particle ignition and combustion at 30-150 atm ［J］. Combust. Flame, 1999(117): 32-58.

[11] [11] JAIN A, ANTHONYSAMY S, ANANTHASIVAN K, et al.. Studies on the ignition behavior of boron powder ［J］. Termochimica Acta, 2010,(500): 63-68.

[12] [12] TRUNOV M A, SCHOENITZ M, DREIZIN E L. Effect of polymorphic phase transformations in alumina layer on ignition of aluminum particles ［J］. Combust. Theor. Model., 2006(10): 603-623.

[13] [13] TRUNOV M A, SCHOENITZ M, ZHU X, et al.. Effect of polymorphic phase transformations in Al2O3 film on oxidation kinetics of aluminum powders ［J］. Combust. Flame, 2005(140): 310-318.

[14] [14] FAN Y P, JI S, ZHANG Y S, et al.. Activity and exothermic behavior of nano-aluminum powder ［J］. Ordnance Material Science and Engineering, 2011(2): 93-95. (in Chinese)

[15] [15] YUASA S, ISODA H. Ignition and combustion of small boron lumps in an oxygen stream ［J］. Combust. Flame, 1991(86): 216-222.

[16] [16] GILL R J, BADIOLA C,DREIZIN E L. Combustion times and emission profiles of micron-sized aluminum particles burning in different environments ［J］. Combust. Flame, 2010(157): 2015-2023.

[17] [17] MOHAN S, FURET L, DREIZIN E L. Aluminum particle ignition in different oxidizing environments ［J］. Combust. Flame, 2010(157): 1356-1363.

[18] [18] LI X, ZHAO F Q, HAO H X, et al.. Research on ignition and combustion properties of different micro/nano-aluminum powders［J］. Acta Armamentarii, 2014, 35(5): 640-647. (In Chinese)

[19] [19] YEH C L, KUO K K. Ignition and combustion of boron particles ［J］. Prog. Energy Combust. Sci., 1996, 22: 511-541.

[20] [20] ULAS A, KUO K K, GOTZMER C. Ignition and combustion of boron particles in fluorine-containing environments ［J］. Combust. Flame, 2001, 127: 1935-1957.

[21] [21] YOUNG G, SULLIVAN K, ZACHARIAH M R, et al.. Combustion characteristics of boron nanoparticles ［J］. Combust. Flame, 2009(156): 322-333.

[22] [22] KONG C, YAO Q, YU D, et al.. Combustion characteristics of well-dispersed aluminum nanoparticle streams in post flame environment ［J］. P. Combust. Inst., 2015, 35(2): 2479-2486.

[23] [23] BRISCOE B J, OZKAN N. Compaction behavior of agglomerated alumina Powders ［J］. Powder Technol., 1997, 90: 195-203.

[24] [24] KUHN P B, MA B, CONNELLY B C, et al.. Soot and thin-filament pyrometry using a color digital camera ［J］. P. Combust. Inst., 2011(33): 743-750.

[25] [25] RAI A, PARK K, ZHOU L, et al.. Understanding the mechanism of aluminum nanoparticle oxidation ［J］. Combust. Theory and Model., 2006, 10(5): 843-859.

[26] [26] TRUNOV M A, UMBRAJKAR S M, SCHOENITZ M, et al.. Oxidation and melting of aluminum nanoparticles ［J］. J.Phys. Chem. B, 2006 (110): 13094-13099.