| 1 |
Effect on combustion of oxide coating formed on aluminum nanoparticles burned in steam
Storozhev VB, Yermakov AN
Combustion and Flame, 226, 182, 2021 |
| 2 |
Reaction modeling study on the combustion of aluminum in gas phase: The Al + O-2 and related reactions
Saba M, Kato T, Oguchi T
Combustion and Flame, 225, 535, 2021 |
| 3 |
Enhancing combustion performance of nano-Al/PVDF composites with beta-PVDF
Huang SD, Hong S, Su YC, Jiang Y, Fukushima S, Gill TM, Yilmaz NED, Tiwari S, Nomura K, Kalia RK, Nakano A, Shimojo F, Vashishta P, Chen ML, Zheng XL
Combustion and Flame, 219, 467, 2020 |
| 4 |
A numerical study on heterogeneous aluminum dust combustion including particle surface and gas-phase reaction
Han DH, Sung HG
Combustion and Flame, 206, 112, 2019 |
| 5 |
Effect of suboxides on dynamics of combustion of aluminum nanopowder in water vapor: Numerical estimate
Storozhev VB, Yermakov AN
Combustion and Flame, 190, 103, 2018 |
| 6 |
Tailoring surface conditions for enhanced reactivity of aluminum powders with solid oxidizing agents
Padhye R, Smith DK, Korzeniewski C, Pantoya ML
Applied Surface Science, 402, 225, 2017 |
| 7 |
Synthesis and reactive characterization of aluminum iodate hexahydrate crystals [Al(H2O)(6)](IO3)(3)(HIO3)(2)
Smith DK, Bello MN, Unruh DK, Pantoya ML
Combustion and Flame, 179, 154, 2017 |
| 8 |
On the role of heterogeneous reactions in aluminum combustion
Glorian J, Gallier S, Catoire L
Combustion and Flame, 168, 378, 2016 |
| 9 |
Comments on: "Combustion of nano-sized aluminum particles in steam: Numerical modeling", by VB Storozhev and AN Yermakov
Bergthorson JM, Julien P, Goroshin S, Frost DL
Combustion and Flame, 171, 262, 2016 |
| 10 |
Reactive characterization of anhydrous iodine (v) oxide (I2O5) with aluminum: amorphous versus crystalline microstructures
Smith DK, Hill K, Pantoya ML, Parkey JS, Kesmez M
Thermochimica Acta, 641, 55, 2016 |
