| 1 |
Analysis of hematite attrition in a grid jet apparatus
Bayham SC, Galinsky NL, Hughes B, Wei XY
Powder Technology, 380, 377, 2021 |
| 2 |
Hydration-induced reactivation of spent sorbents for fluidized bed calcium looping (double looping)
Coppola A, Salatino P, Montagnaro F, Scala F
Fuel Processing Technology, 120, 71, 2014 |
| 3 |
Primary fragmentation of limestone under oxy-firing conditions in a bubbling fluidized bed
Lupianez C, Scala F, Salatino P, Romeo LM, Diez LI
Fuel Processing Technology, 92(8), 1449, 2011 |
| 4 |
Limestone fragmentation and attrition during fluidized bed oxyfiring
Scala F, Salatino P
Fuel, 89(4), 827, 2010 |
| 5 |
Attrition of limestones by impact loading in fluidized beds: The influence of reaction conditions
Scala F, Salatino P
Fuel Processing Technology, 91(9), 1022, 2010 |
| 6 |
Sulphation of limestones in a fluidized bed combustor: The relationship between particle attrition and microstructure
Scala F, Montagnaro F, Salatino P
Canadian Journal of Chemical Engineering, 86(3), 347, 2008 |
| 7 |
Fluidized bed combustion of pelletized biomass and waste-derived fuels
Chirone R, Salatino P, Scala F, Solimene R, Urciuolo M
Combustion and Flame, 155(1-2), 21, 2008 |
| 8 |
Impact attrition in crystallization processes. Analysis of repeated impacts events of individual crystals
Biscans B
Powder Technology, 143-4, 264, 2004 |
| 9 |
An experimental investigation of particle fragmentation using single particle impact studies
Salman AD, Biggs CA, Fu J, Angyal I, Szabo M, Hounslow MJ
Powder Technology, 128(1), 36, 2002 |
| 10 |
Impact of a single crystal in solution, on an immersed target, in conditions which simulate impact attrition in crystallizers
Marrot B, Biscans B
Powder Technology, 120(3), 141, 2001 |
