| 1 |
Aluminum particle reactivity as a function of alumina shell structure: Amorphous versus crystalline
Walzel RK, Levitas VI, Pantoya ML
Powder Technology, 374, 33, 2020 |
| 2 |
Effective dispersion of multi-walled carbon nanotubes in aqueous solution using an ionic-gemini dispersant
Hou JT, Du WB, Meng FJ, Zhao CC, Du X
Journal of Colloid and Interface Science, 512, 750, 2018 |
| 3 |
On the dispersion of lithium-sulfur battery cathode materials effected by electrostatic and stereo-chemical factors of binders
Hong XH, Jin J, Wen ZY, Zhang SP, Wang QS, Shen C, Rui K
Journal of Power Sources, 324, 455, 2016 |
| 4 |
A mechanistic perspective of atmospheric oxygen sensitivity on composite energetic material reactions
Farley CW, Pantoya ML, Levitas VI
Combustion and Flame, 161(4), 1131, 2014 |
| 5 |
Melt dispersion mechanism for fast reaction of aluminum nano- and micron-scale particles: Flame propagation and SEM studies
Levitas VI, Pantoya ML, Dean S
Combustion and Flame, 161(6), 1668, 2014 |
| 6 |
Toward design of the pre-stressed nano- and microscale aluminum particles covered by oxide shell
Levitas VI, Dikici B, Pantoya ML
Combustion and Flame, 158(7), 1413, 2011 |
| 7 |
Flash ignition of Al nanoparticles: Mechanism and applications
Ohkura Y, Rao PM, Zheng XL
Combustion and Flame, 158(12), 2544, 2011 |
| 8 |
Synthesis of mesoporous CaCO3 particles by a spray drying method from the stable suspensions achieved in a beads mill
Cho K, Suh YJ, Chang H, Kil DS, Kim BG, Jang HD
Advanced Powder Technology, 21(2), 145, 2010 |
| 9 |
Gas-Phase Reaction in Nanoaluminum Combustion
Lynch P, Fiore G, Krier H, Glumac N
Combustion Science and Technology, 182(7), 842, 2010 |
| 10 |
Dry dispersion of fine particles in gaseous phase
Masuda H
Advanced Powder Technology, 20(2), 113, 2009 |
