International Journal of Engineering Technology and Scientific Innovation
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Title:
EFFECT OF 1-HEXANOL CO-SURFACTANT ON THE NiFe NANOPARTICLES DENSITY IN REVERSE MICROEMULSION SYSTEMS

Authors:
Mayda Lam Maldonado, Jose Aaron Melo Banda, David Macias Ferrer

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Mayda Lam Maldonado, Jose Aaron Melo Banda, David Macias Ferrer
Centro de Investigacion en Petroquimica Secundaria, Instituto Tecnologico de Cd. Madero, Cd. Madero, Tamaulipas, 89440, Mexico

MLA 8
Maldonado, Mayda L., et al. "EFFECT OF 1-HEXANOL CO-SURFACTANT ON THE NiFe NANOPARTICLES DENSITY IN REVERSE MICROEMULSION SYSTEMS." IJETSI, vol. 3, no. 1, pp. 63-68, ijetsi.org/more2018.php?id=5.
APA
Maldonado, M. L., Banda, J. M., & Ferrer, D. M. (n.d.). EFFECT OF 1-HEXANOL CO-SURFACTANT ON THE NiFe NANOPARTICLES DENSITY IN REVERSE MICROEMULSION SYSTEMS. IJETSI, 3(1), 63-68. Retrieved from http://ijetsi.org/more2018.php?id=5
Chicago
Maldonado, Mayda L., Jose Aaron M. Banda, and David M. Ferrer. "EFFECT OF 1-HEXANOL CO-SURFACTANT ON THE NiFe NANOPARTICLES DENSITY IN REVERSE MICROEMULSION SYSTEMS." IJETSI 3, no. 1 (n.d.), 63-68. http://ijetsi.org/more2018.php?id=5.

References
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Abstract:
In this work, NiFe nanoparticles with molar ratio (1:1) have been synthesized through inverse microemulsion method using water, sodium dodecylbenzenesulfonate as surfactant, toluene as continuous phase, sodium borohydride as reductant agent and citric acid as stabilizing agent, studying the effect on the density of NiFe nanoparticles by the addition of co-surfactant 1- hexanol, thus NiFe (1:1)-A (without 1-hexanol) and NiFe (1:1)-B (with 1-hexanol) were analyzed. The NiFe microemulsion systems was characterized by means atomic absorption (AA), dynamic light scattering (DLS), scanning transmission electron microscopy (STEM) and energy-dispersive x-ray spectroscopy (EDS). The effect of the co-surfactant showed greater stability in the microemulsion, obtaining a higher density of NiFe nanoparticles in comparison with the microemulsion without 1-hexanol. In both microemulsions, nanoparticles with spherical morphology with diameters less than 20 nm were obtained.