SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH

Antony A. Neciosup-Puican; José A. Castañeda-Vía; Carlos V. Landauro; Justiniano Quispe-Marcatoma; Ilanit Samolski; Gretty K. Villena

doi:10.15446/mo.n67.103549

Publicado

2023-07-04

SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH

SÍNTESIS DE NANOCELULOSA COMO REFUERZO MECÁNICO DE ALMIDÓN TERMOPLÁSTICO

DOI:

https://doi.org/10.15446/mo.n67.103549

Palabras clave:

thermoplastic, nanocellulose, mechanical properties (en)
termoplástico, nanocelulosa, propiedades mecánicas (es)

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Autores/as

Antony A. Neciosup-Puican Universidad Nacional Mayor de San Marcos https://orcid.org/0000-0002-1481-2523
José A. Castañeda-Vía Universidad Peruana Cayetano Heredia
Carlos V. Landauro Universidad Nacional Mayor de San Marcos. Centro de Investigaciones, Tecnol´ogicas, Biom´edicas y Medioambientales (CITBM)
Justiniano Quispe-Marcatoma Universidad Nacional Mayor de San Marcos. Centro de Investigaciones, Tecnol´ogicas, Biom´edicas y Medioambientales (CITBM)
Ilanit Samolski Universidad Nacional Agraria La Molina.
Gretty K. Villena Universidad Nacional Agraria La Molina

Resumen (en)
Resumen (es)

Nanocellulose was successfully synthetized from microcrystalline cellulose by an acid hydrolysis process. The sample characterization was performed employing X-ray diffraction, zeta potential and confocal Raman microscopy. Nanocellulose-reinforced thermoplastic starch (TPS) composites were prepared by solution casting method, in which a small concentration of nanocellulose improved the elastic modulus of TPS. This property was calculated using the atomic force microscopy nanoindentation method. We conclude that nanocellulose is a good mechanical reinforcement for composites from commercial sources as starch.

Se sintetizó exitosamente nanocelulosa a partir de celulosa microcristalina mediante un proceso de hidrólisis ácida. La caracterización de la muestra se realizó mediante difracción de rayos X, potencial zeta y microscopía Raman confocal. Se prepararon compuestos de almidón termoplástico (TPS, por sus siglas en inglés) reforzados con nanocelulosa mediante el método “casting solution”, en el que una pequeña concentración de nanocelulosa mejoró el módulo de elasticidad del TPS. Esta propiedad se calculó mediante el método de nanoindentación por microscopía de fuerza atómica. Llegamos a la conclusión de que la nanocelulosa es un buen refuerzo mecánico para los compuestos de fuentes comerciales como el almidón.

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Cómo citar

APA

Neciosup-Puican, A. A., Castañeda-Vía, J. A., Landauro, C. V., Quispe-Marcatoma, J., Samolski, I. y Villena, G. K. (2023). SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH. MOMENTO, (67), 55–66. https://doi.org/10.15446/mo.n67.103549

ACM

[1]

Neciosup-Puican, A.A., Castañeda-Vía, J.A., Landauro, C.V., Quispe-Marcatoma, J., Samolski, I. y Villena, G.K. 2023. SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH. MOMENTO. 67 (jul. 2023), 55–66. DOI:https://doi.org/10.15446/mo.n67.103549.

ACS

(1)

Neciosup-Puican, A. A.; Castañeda-Vía, J. A.; Landauro, C. V.; Quispe-Marcatoma, J.; Samolski, I.; Villena, G. K. SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH. Momento 2023, 55-66.

ABNT

NECIOSUP-PUICAN, A. A.; CASTAÑEDA-VÍA, J. A.; LANDAURO, C. V.; QUISPE-MARCATOMA, J.; SAMOLSKI, I.; VILLENA, G. K. SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH. MOMENTO, [S. l.], n. 67, p. 55–66, 2023. DOI: 10.15446/mo.n67.103549. Disponível em: https://revistas.unal.edu.co/index.php/momento/article/view/103549. Acesso em: 21 ene. 2025.

Chicago

Neciosup-Puican, Antony A., José A. Castañeda-Vía, Carlos V. Landauro, Justiniano Quispe-Marcatoma, Ilanit Samolski, y Gretty K. Villena. 2023. «SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH». MOMENTO, n.º 67 (julio):55-66. https://doi.org/10.15446/mo.n67.103549.

Harvard

Neciosup-Puican, A. A., Castañeda-Vía, J. A., Landauro, C. V., Quispe-Marcatoma, J., Samolski, I. y Villena, G. K. (2023) «SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH», MOMENTO, (67), pp. 55–66. doi: 10.15446/mo.n67.103549.

IEEE

[1]

A. A. Neciosup-Puican, J. A. Castañeda-Vía, C. V. Landauro, J. Quispe-Marcatoma, I. Samolski, y G. K. Villena, «SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH», Momento, n.º 67, pp. 55–66, jul. 2023.

MLA

Neciosup-Puican, A. A., J. A. Castañeda-Vía, C. V. Landauro, J. Quispe-Marcatoma, I. Samolski, y G. K. Villena. «SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH». MOMENTO, n.º 67, julio de 2023, pp. 55-66, doi:10.15446/mo.n67.103549.

Turabian

Neciosup-Puican, Antony A., José A. Castañeda-Vía, Carlos V. Landauro, Justiniano Quispe-Marcatoma, Ilanit Samolski, y Gretty K. Villena. «SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH». MOMENTO, no. 67 (julio 4, 2023): 55–66. Accedido enero 21, 2025. https://revistas.unal.edu.co/index.php/momento/article/view/103549.

Vancouver

1.

Neciosup-Puican AA, Castañeda-Vía JA, Landauro CV, Quispe-Marcatoma J, Samolski I, Villena GK. SYNTHESIS OF NANOCELLULOSE AS MECHANICAL REINFORCEMENT OF THERMOPLASTIC STARCH. Momento [Internet]. 4 de julio de 2023 [citado 21 de enero de 2025];(67):55-66. Disponible en: https://revistas.unal.edu.co/index.php/momento/article/view/103549

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