Valorización del Bagazo de Caña de Azúcar en Nanosílice: Ruta Optimizada para Mejorar la Resistencia y la Sostenibilidad en Morteros de Cemento

Valorización del Bagazo de Caña de Azúcar en Nanosílice: Ruta Optimizada para Mejorar la Resistencia y la Sostenibilidad en Morteros de Cemento

The present research aims to evaluate the influence of adding silica nanoparticles derived from sugarcane bagasse, synthesized in the laboratory using the sol-gel method, on the properties of cement mortar in both its fresh and hardened states. In the fresh state, the study examines workability, co...

Full description

Saved in:
Bibliographic Details
Main Authors: Mohammadfarid Alvansazyazdi, Jenny Estefany Chandi Paucar, Fausto Enrique Fausto Enrique, Pablo Mauricio Bonilla Valladares, Debut Alexis Patrice Martial, Jorge Luis Santamaria Carrera, Hugo Alexander Cadena Perugachi, Andrea Estefania Logacho Morales
Format: Article
Language:Spanish
Published: Universidad Central del Ecuador 2025-07-01
Series:Ingenio
Subjects:
Nanomateriales
partículas de nano-sílice
Morteros de cemento
Propiedades mecánicas
Hidrofobicidad del mortero
Online Access:https://revistadigital.uce.edu.ec/index.php/INGENIO/article/view/8164
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The present research aims to evaluate the influence of adding silica nanoparticles derived from sugarcane bagasse, synthesized in the laboratory using the sol-gel method, on the properties of cement mortar in both its fresh and hardened states. In the fresh state, the study examines workability, consistency, and flow, while in the hardened state, it evaluates compressive strength and hydrophobicity. Specimens were prepared using Type N and Type HS cement, with the addition of nano-silica particles at 0.25%, 0.50%, 0.75%, 1.00%, and 1.50% by weight as a replacement for cement in the control mortar. The results revealed that 0.25% nano-silica was the optimal addition percentage for both mortars. Moreover, it was found that both fresh and hardened properties were negatively affected as the percentage of nano-silica increased. The compressive strength increased by 9% at 28 days and 12% at 56 days for the Type N cement mortar, while for the Type HS cement mortar, the strength increase was 9% at 28 days, 10% at 56 days, and 5% at 90 days. The contact angle test indicated that nano-silica particles reduce the permeability of the mortars, with specimens made with Type N cement exhibiting greater impermeability compared to those made with Type HS cement.
ISSN:2588-0829
2697-3243

Similar Items