[1] E. Price and R. Sigman, "Combustion of Solid Propellants," in Solid Propellant Chemistry, Combustion, and Motor Ballistics, New York, NY: American Institute of Aeronautics and Astronautics, 2000, pp. 663-687.
[2] C. Rossi, K. Zhang, D. Esteve, P. Alphonse, P. Tailhades and C. Vahlas, "Nanoenergetic materials for MEMS: A Review," Journal of Microelectromechanical Systems, vol. 16, no. 4, pp. 919-932, 2007.
[3] K. Stank and H. Steckel, "Physico-Chemical Characterization of Surface Modified Particles for Inhalation," Int. J. of Pharmaceutics, vol. 448, pp. 9-18, 2013.
[4] D. Sundaram, V. Yang and R. Yetter, "Metal-based nanoenergetic materials: synthesis, properties, and applications," Progress in Energy and Combustion Science, vol. 61, pp. 293-365, 2017.
[5] T. Brzustowski and I. Glassman, "Spectroscopic investigation of metal combustion," in Heterogeneous Combustion, H. Wolfhard, I. Glassman and L. Green, Eds., New York, NY: Academic Press, 1964, pp. 41-74.
[6] K. Brooks and M. Beckstead, "Dynamics of Aluminum Combustion," Journal of Propulsion and Power, vol. 11, no. 4, p. 769, 1995.
[7] M. Beckstead, Y. Liang and K. Pudduppakkam, "Numerical simulation of single aluminum particle combustion (Review)," Combustion, Explosion and Shock Waves, vol. 41, pp. 622-638, 2005.
[8] M. Bedard, T. Fuller, S. Sardeshmukh and W. Anderson, "Chemiluminescence as a diagnostic in studying combustion instability in a practical combustor," Combustion and Flame, vol. 213, pp. 211-225, 2020.
[9] Y. Shoshin and I. Altman, "Integral radiation energy loss during single Mg particle combustion," Combustion Science and Technology, vol. 174, no. 8, pp. 209-219, 2002.
[10] I. Altman, P. Pikhitsa and M. Choi, "Key effects in nanoparticle formation by combustion techniques," in Gas Phase Nanoparticle Synthesis, C. Granqvis and L. Kish, Eds., Dordrecht, Kluwer, 2004, pp. 43-67.
[11] V. Bityukov and V. Petrov, "Absorption coefficient of molten aluminum oxide in semitransparent spectral range," Combustion and Flame, vol. 5, pp. 51-71, 2013.
[12] S. De Iuliis, R. Donde and I. Altman, "On pyrometry in particulate-generating flames," Combustion Science and Technology, 2020.
[13] H. Wang, D. Kline and M. Zachariah, "In-operando high-speed microscopy and thermometry of reaction propagation and sintering in a nanocomposite," Nature Communications, vol. 10, p. 3032, 2019.
[14] I. Altman, A. Demko, K. Hill and M. Pantoya, "On the possible coexistence of two different regimes of metal particle combustion," Combustion and Flame, vol. 221, pp. 416-419, 2020.
[15] K. Hill, M. Pantoya, E. Washburn and J. Kalman, "Single particle combustion of pre-stressed aluminum," Materials, vol. 12, p. 1737, 2019.
[16] H. Wang, H. Ren, T. Yan, Y. Li and W. Zhao, "A latent highly activity energetic fuel: thermal stability and interfacial reaction kinetics of selected fluoropolymer encapsulated sub-micron sized Al particles," Scientific Reports, vol. 11, p. 738, 2021.
[17] Q. Tran, P. Dube, M. Malkoun, I. Altman, R. Koch and M. Pantoya, "Bomb calorimeter advancements for evaluating powder metal fuels," Review of Scientific Instruments, 2021.
[18] I. Valimet, "Aluminum H-Series Data Sheet," Valimet, 2017. [Online]. Available: http://valimet.com/wp-contents/uploads/2017/08/Aluminum-H-Series-Data-Sheet-.pdf. [Accessed 01 12 2021].
[19] K. Hill, N. Tamura, V. Levitas and M. Pantoya, "Impact Ignition and Combustion of Micron-Scale Aluminum Particles Pre-Stressed with Different Quenching Rates," Journal of Applied Physics, p. 115903, 2018.
[20] I. Altman and Y. Vovchuk, "Thermal regime of the vapor-state combustion of magnesium particle," Combustion Explosion Shock Waves, vol. 36, pp. 227-229, 2000.
[21] S. De Iuliis, R. Donde and I. Altman, "On thermal regime of nanoparticles in synthesis flame," Chemical Physics Letters, vol. 769, p. 138424, 2021.
[22] S. Fischer and M. Grubelich, "Theoretical energy release of thermites, intermetallic, and combustible metals," Sandia National Laboratory Technical Report SAND98-1176C, Alburguerque, 1998.