← Volver a resultados
Ficha bibliográfica · Consulta y acceso
Artículo

Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite

Ahmed Aboalhamayie et al · KeAi Communications Co. Ltd · 2026

Acceso abierto disponible
Lectura rápida. Revisá los datos básicos del recurso y luego accedé al contenido desde el botón principal. En esta ficha solo se muestra la información necesaria para identificar la obra, citarla y abrirla.

Acceso al recurso

Entrá al contenido desde la opción principal o elegí otra fuente disponible.

Acceso principal

Acceso abierto disponible

Recurso identificado como acceso abierto, sin confirmar automáticamente si es texto completo directo.
Abrir recurso

Resumen

Descripción general del contenido del recurso.

The combustion dynamics and characteristics of dense iron–ethanol slurry droplets containing 30 wt% Fe (in both micron- and nano-sized forms) and Fe-doped Al/Fe2O3 thermites containing 5 wt% Fe (in both micron- and nano-sized forms) are investigated as a function of iron particle size. Single droplet experiments with high-speed imaging and in-situ thermocouple measurements are combined with TGA–DSC and SEM/EDS to link burning behavior to aggregate morphology. In ethanol, micron Fe (10 µm) settles toward the droplet periphery (terminal velocity ∼0.06 mm/s), forming a porous shell that improves O2 access, raises the peak internal temperature to ∼326 °C, and increases the d²-law burning rate to 0.76 mm²/s (+10%) while shortening the total burn time. Nano Fe (40 nm) remains more uniformly dispersed (terminal velocity ∼0.04 mm/s) and forms smoother, less-porous aggregates; despite a higher peak temperature (∼266.5 °C) and frequent small disruptive events, the burning rate decreases to 0.63 mm²/s (–9%) and the total burn time contracts through secondary atomization. These outcomes show that aggregate architecture and settling, not surface area alone, govern heat/mass transfer and apparent burning rate in highly loaded metal fuel droplets. Translating these insights to thermites, adding 5 wt% nano-Fe triggers earlier ignition and rapid energy release, whereas 5 wt% micron-Fe yields more completely reduced, Fe-rich, semi-spherical residues, indicating locally more complete conversion. The work establishes a transport-to-morphology-to-combustion framework for designing metalized fuels and tailoring ignition and energy release in aluminothermic composites.

Cómo citar

Elegí el formato que necesitás y copiá la referencia al portapapeles.

APA 7

al, A. A. E. (2026). Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite. https://doi.org/10.1016/j.fpc.2026.01.006

MLA

al, Ahmed Aboalhamayie et. "Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite." 2026. https://doi.org/10.1016/j.fpc.2026.01.006.

Chicago

al, Ahmed Aboalhamayie et. 2026. "Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite.". https://doi.org/10.1016/j.fpc.2026.01.006.

Harvard

al, A. A. E. 2026, Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite, KeAi Communications Co. Ltd, available at: https://doi.org/10.1016/j.fpc.2026.01.006 [Accessed 29 Jun. 2026].

Compartir e imprimir

Guardá la ficha, copiá su enlace permanente o imprimila como PDF.

Exportar referencia

Si usás un gestor bibliográfico, podés exportar el registro en los formatos más comunes.

Detalles del recurso

Información bibliográfica útil para confirmar que se trata del material correcto.

Título
Micron and nano iron particles: Experimental investigation of size dependent combustion in ethanol slurries and bimetallic thermite
Autor / colaboradores
Ahmed Aboalhamayie et al
Editorial
KeAi Communications Co. Ltd
Año de publicación
2026
ISSN
2667-1344
ISSN
2667-1344
Idioma
eng

Materias

Explorá otros recursos relacionados a partir de estas materias.

Copiado