Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling

Cement-based mortar is recognized as a popular and cost-effective material for the rehabilitation and repair of reinforced concrete structures. However, the development of high-performance cement-based mortar is in high demand in order to not only enhance compressive strength but also to prolong the...

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Main Authors: Salah H.A., Mutalib A.A., Algaifi H.A., Yahya I.B., Yusof M.A.I., Sakib N., Elsayed M.
Other Authors: 58297421600
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Published: MDPI 2024
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spelling my.uniten.dspace-341812024-10-14T11:18:19Z Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling Salah H.A. Mutalib A.A. Algaifi H.A. Yahya I.B. Yusof M.A.I. Sakib N. Elsayed M. 58297421600 55613230213 57203885467 24734132000 58296763500 59099503700 57907974400 cementitious material compressive strength graphene nanoplatelets graphene-based mortar high-strength mortar cement (construction material) compressive strength mechanical property mortar numerical method reinforced concrete response surface methodology scanning electron microscopy silica Cement-based mortar is recognized as a popular and cost-effective material for the rehabilitation and repair of reinforced concrete structures. However, the development of high-performance cement-based mortar is in high demand in order to not only enhance compressive strength but also to prolong the mortar lifespan and minimize maintenance costs as much as possible. In the current study, high-strength mortars incorporating both silica fume and graphene nanoplatelets (GNPs) were investigated and evaluated based on compressive and flexural strength. The graphene powder was added in amounts ranging from 0.5% to 2%, by cement weight, while silica fume was added as a partial replacement for cement (10%). The optimal content of the graphene was determined using response surface methodology (RSM). In addition, field emission scanning electron microscopy (FESEM) was used to assess the proposed mortar at the micro-scale level. The outcome revealed that the graphene-based mortar imparted superior mechanical properties compared to the control mixture. The compressive and flexural strength of the mortars containing 10% silica fume and 1% graphene increased by 33% and 35%, respectively. This positive result was attributed to the refinement of the nanopores and tiny cracks by the inclusion of GNPs, which was supported by microstructure testing. The RSM model was also shown to be capable of optimizing and predicting compressive and flexural strength with less error. It is possible to conclude that graphene-based high-strength mortar will serve as a sustainable material in the near future. � 2023 by the authors. Final 2024-10-14T03:18:19Z 2024-10-14T03:18:19Z 2023 Article 10.3390/su15108054 2-s2.0-85160686387 https://www.scopus.com/inward/record.uri?eid=2-s2.0-85160686387&doi=10.3390%2fsu15108054&partnerID=40&md5=b5c6d6c9a6e8313e204ffe3af9326802 https://irepository.uniten.edu.my/handle/123456789/34181 15 10 8054 All Open Access Gold Open Access MDPI Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic cementitious material
compressive strength
graphene nanoplatelets
graphene-based mortar
high-strength mortar
cement (construction material)
compressive strength
mechanical property
mortar
numerical method
reinforced concrete
response surface methodology
scanning electron microscopy
silica
spellingShingle cementitious material
compressive strength
graphene nanoplatelets
graphene-based mortar
high-strength mortar
cement (construction material)
compressive strength
mechanical property
mortar
numerical method
reinforced concrete
response surface methodology
scanning electron microscopy
silica
Salah H.A.
Mutalib A.A.
Algaifi H.A.
Yahya I.B.
Yusof M.A.I.
Sakib N.
Elsayed M.
Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
description Cement-based mortar is recognized as a popular and cost-effective material for the rehabilitation and repair of reinforced concrete structures. However, the development of high-performance cement-based mortar is in high demand in order to not only enhance compressive strength but also to prolong the mortar lifespan and minimize maintenance costs as much as possible. In the current study, high-strength mortars incorporating both silica fume and graphene nanoplatelets (GNPs) were investigated and evaluated based on compressive and flexural strength. The graphene powder was added in amounts ranging from 0.5% to 2%, by cement weight, while silica fume was added as a partial replacement for cement (10%). The optimal content of the graphene was determined using response surface methodology (RSM). In addition, field emission scanning electron microscopy (FESEM) was used to assess the proposed mortar at the micro-scale level. The outcome revealed that the graphene-based mortar imparted superior mechanical properties compared to the control mixture. The compressive and flexural strength of the mortars containing 10% silica fume and 1% graphene increased by 33% and 35%, respectively. This positive result was attributed to the refinement of the nanopores and tiny cracks by the inclusion of GNPs, which was supported by microstructure testing. The RSM model was also shown to be capable of optimizing and predicting compressive and flexural strength with less error. It is possible to conclude that graphene-based high-strength mortar will serve as a sustainable material in the near future. � 2023 by the authors.
author2 58297421600
author_facet 58297421600
Salah H.A.
Mutalib A.A.
Algaifi H.A.
Yahya I.B.
Yusof M.A.I.
Sakib N.
Elsayed M.
format Article
author Salah H.A.
Mutalib A.A.
Algaifi H.A.
Yahya I.B.
Yusof M.A.I.
Sakib N.
Elsayed M.
author_sort Salah H.A.
title Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
title_short Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
title_full Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
title_fullStr Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
title_full_unstemmed Assessment of the Mechanical Properties of High Strength Mortar Incorporating Silica Fume and Graphene Nanoplatelets: Experimental and Mathematical Modeling
title_sort assessment of the mechanical properties of high strength mortar incorporating silica fume and graphene nanoplatelets: experimental and mathematical modeling
publisher MDPI
publishDate 2024
_version_ 1814061044867268608
score 13.222552