Concrete Performance Attenuation of Mix Nano-SiO2 and Nano-CaCO3 under High Temperature: A Comprehensive Review

Syamsunur, Deprizon; Li, Wei; Memon, Zubair Ahmed; Surol, Salihah; Yusoff, Nur Izzi Md.

doi:10.3390/ma15207073

Cited by 9 publications

(3 citation statements)

References 121 publications

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“…It is evident from these results that adding nanoparticles to the concrete mixture produced less k coefficient composite. This is consistent with the results of previous studies (Saleh et al, 2021;Nazari and Riahi, 2011;Oh et al, 2023;Ren et al, 2018;Khaloo et al, 2016;Syamsunur et al, 2022). It can be concluded that adding some of the nano-SiO 2 as a cement substitute has positive economic effects due to its merits; nano-SiO 2 is a desirable, reliable, and inexpensive substitute compared to other nanomaterials.…”

Section: Thermal Conductivity (K Coefficient) Resultssupporting

confidence: 91%

Combined Effect of Silicon Dioxide and Titanium Dioxide Nanoparticles on Concrete Properties

Al-Rbaihat,

Al-Marafi

2023

J. Ecol. Eng.

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Nanoconcrete is an attractive research area because of its recent practical applications in building materials technologies. This study investigates the individual and combined effects of using nanoparticles in concrete mixtures as a cement substitute. Microscopic images are also used to determine changes in the microstructure of modified concrete in the present study. Concrete's thermal and mechanical properties, including thermal conductivity (k), specific heat capacity (C), thermal diffusivity (α), and compressive strength (σ), are the leading concrete characteristics examined. The current study used different percentages (0%, 1%, 3%, and 5%) of nano-SiO 2 , nano-TiO 2, and combined nano-SiO 2 /TiO 2 particles as cement substitutes for 7 and 28 days of curing to examine the characteristics of nanoconcrete compared to conventional concrete (CC). The results indicated that adding individual nanoparticles to CC could improve concrete's thermal and mechanical properties. Among the investigated nanomaterials (nano-SiO 2 , nano-TiO 2, and combined nano-SiO 2 /TiO 2 particles), nano-SiO 2 was superior in that context. The optimal thermal properties of nanoconcrete were achieved when 5% nano-SiO 2 (C-S5 specimen) was added. The k and α coefficients of sample C-S5 compared to the CC specimen were reduced by 65.6% and 80.3%, respectively, while the C coefficient was increased by 12.8%. Meanwhile, the optimal compressive strength coefficient of nanoconcrete was achieved when 3% nano-SiO 2 (C-S3 specimen) was added, where the compressive strength coefficient of sample C-S3 compared to sample CC was increased by 19.6%. In contrast, for the combined effect, the thermal properties of concrete were improved, but the compressive strength coefficient of concrete was reduced. Overall, the present experimental findings offer valuable information about the impact of nanotechnology on highperformance concrete to save energy in buildings.

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Section: Thermal Conductivity (K Coefficient) Resultssupporting

confidence: 91%

Combined Effect of Silicon Dioxide and Titanium Dioxide Nanoparticles on Concrete Properties

Al-Rbaihat,

Al-Marafi

2023

J. Ecol. Eng.

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“…It is essential to accurately and promptly predict the durability of HPC (Pengcheng et al 2020). Over the past few decades, nanotechnology has proven to be a competitive means of increasing the durability and strength of construction materials (Syamsunur et al 2022). The term nanotechnology describes the process of creating, assembling and applying functional structures that have a minimum of one feature dimension expressed in nanoscale units.…”

Section: Introductionmentioning

confidence: 99%

Nanotechnology and high-performance concrete: Evaluating mechanical transformations

Jakhar,

Kumar,

Nagappan

et al. 2024

Multidiscip. Rev.

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The High-performance concrete (HPC) is defined by the attained strength and durability that are superior to conservative techniques. The features of ordinary concrete that are achieved at certain times and locations, used to establish the standards for HPC. The use of nanotechnology in HPC is attracted significant attention globally because of its small particle sizes, filling capacities, enormous surface areas and strong macro quantum tunnel property. By adding nanotechnology to HPC, it increases the whole diameters of the cementations matrix, improves cement hydration and raises matrix density. This study provides a review of current developments in HPC and assesses the effects of different nanotechnology on HPC characteristics, to provide an in-depth understanding of the potential of nanotechnology reinforced in HPC. This review evaluates the mechanical characteristics of HPC containing compressive strength (CS) by applying nano calcium carbonate, nano silicon dioxide, nano titanium dioxide and carbon nano tubes. According to findings in this review, introducing different nanotechnology enhances HPC's mechanical properties while decreasing its flexibility. While integrating nanotechnology into HPC for the greatest possible outcomes in construction, review contributes to expand the collection of information in the area of building materials. To provide a low-impact construction material and an ecologically friendly solution, more consideration is required given to nanoparticles' antibacterial, self-cleaning, air depolluting and air-cooling properties. By increasing the reactivity of various fillers, including nanoparticles with other mineral admixtures reduces the quantity of cement needed in concrete.

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“…The nanocracks then grow into micro-and macrocracks, which adversely affect the mechanical and durability properties [24]. Graphene oxide, silica, titanium oxide (TiO 2 ), iron (Fe 2 O 3 ), alumina oxide (Al 2 O 3 ), CuO, calcium carbonate, ZnO 2 , and ZrO 2 have been used during the last years in cement and concrete [25][26][27][28][29].…”

Section: Introductionmentioning

confidence: 99%

Development of Mortars That Use Recycled Aggregates from a Sodium Silicate Process and the Influence of Graphene Oxide as a Nano-Addition

Ruiz Martinez,

Cifuentes,

Rios

et al. 2023

Materials

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This research analyses how different cement mortars behave in terms of their physical and mechanical properties. Several components were necessary to make seven mixes of mortars, such as Portland cement, standard sand, and solid waste from a factory of sodium silicate, in addition to graphene oxide. Furthermore, graphene oxide (GO) was selected to reduce the micropores and increase the nanopores in the cement mortar. Hence, some tests were carried out to determine their density, humidity content, water absorption capacity, open void porosity, the alkali–silica reaction, as well as flexural and mechanical strength and acid resistance. Thus, standard-sand-manufactured mortars’ mechanical properties were proved to be slightly better than those manufactured with recycled waste; the mortars with this recycled aggregate presented problems of alkali–silica reaction. In addition, GO (in a ratio GO/cement = 0.0003) performed as a filler, improving the mechanical properties (30%), alkali–silica (80%), and acid resistance

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Concrete Performance Attenuation of Mix Nano-SiO2 and Nano-CaCO3 under High Temperature: A Comprehensive Review

Cited by 9 publications

References 121 publications

Combined Effect of Silicon Dioxide and Titanium Dioxide Nanoparticles on Concrete Properties

Combined Effect of Silicon Dioxide and Titanium Dioxide Nanoparticles on Concrete Properties

Nanotechnology and high-performance concrete: Evaluating mechanical transformations

Development of Mortars That Use Recycled Aggregates from a Sodium Silicate Process and the Influence of Graphene Oxide as a Nano-Addition

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