利用可持续碳纳米材料开发整体疏水水泥砂浆复合材料:润湿性与表面能

IF 1.7 4区 工程技术 Q3 ENGINEERING, CIVIL
N. K. Karthikeyan, S. Elavenil
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引用次数: 0

摘要

各种形式的超疏水碳基纳米材料已被广泛吸引到先进领域。虽然它已被广泛应用,但其潜在的环境影响和不经济性限制了它的使用。为了克服这些缺点,本文旨在提供从轮胎废弃物热解中获得的碳基可持续超疏水(CSS)纳米颗粒。首先,通过显微镜、光谱和疏水性测量对 CSS 纳米颗粒进行了表征。随后,文章研究了利用 CSS 纳米颗粒开发疏水性水泥复合材料的情况,并回顾了利用随时间变化的接触角测量技术研究表面润湿性和表面能的最新进展。此外,还通过机械强度和微观结构表征研究了 CSS 纳米粒子在水泥复合材料中的作用。水接触角结果表明,含有 CSS 纳米粒子的水泥复合材料具有疏水性,3wt% 的接触角最高,为 132.15º(过疏水)。CM-3 混合物的总能(γS)、分散能(({\gamma }_{s}^{d})和极性表面能(({\gamma }_{s}^{p})值最低,分别为 11.95 mJ/m2、11.63 mJ/m2 和 0.324 mJ/m2。此外,添加 CSS 纳米粒子后,抗压和抗折强度显著提高,最大强度分别达到 55.65 兆帕(CM-2)和 7.8 兆帕(CM-1.5)。3wt%的 CSS 纳米粒子在 10%的 SF 中成功扩散,相对较高地降低了毛细吸收率。微观结构研究表明,CSS 纳米粒子在 SF 中缠结良好,从而形成了致密和紧密的基体结构。因此,CSS 颗粒将成为一种先进的、可持续的纳米材料,用于开发整体憎水水泥复合材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Developing Integral Hydrophobic Cement Mortar Composite Using Sustainable Carbon Nanomaterial: Wettability and Surface Energy

Developing Integral Hydrophobic Cement Mortar Composite Using Sustainable Carbon Nanomaterial: Wettability and Surface Energy

Various forms of superhydrophobic carbon-based nanomaterials have been extensively attracted to advanced fields. Although it is widely implemented, its potential environmental impact and uneconomical has limited its utilization. To overcome these shortcomings, this article aimed to provide Carbon-based Sustainable Superhydrophobic (CSS) nanoparticles obtained from the pyrolysis of tyre waste. Firstly, CSS nanoparticles were characterized with microscopic, spectroscopic, and hydrophobic measurements. This article subsequently studied the development of hydrophobic cement composites using CSS nanoparticles and reviewed the advanced progress in the research of surface wettability and surface energy using a time-dependent contact angle measurement technique. Further, the role of CSS nanoparticles in cement composites is examined through mechanical strength and microstructure characterization. The water contact angle results showed that the cement composites with CSS nanoparticles achieved hydrophobic and exhibited the highest contact angle of 132.15º (over-hydrophobic) for 3wt%. The CM-3 mix has the lowest value of total (γS), dispersive (\({\gamma }_{s}^{d})\), and polar surface energy (\({\gamma }_{s}^{p})\) of 11.95 mJ/m2, 11.63 mJ/m2, and 0.324 mJ/m2 respectively. Moreover, the compressive and flexural strength improved significantly with the addition of CSS nanoparticles, attaining maximum strength of 55.65 MPa (CM-2) and 7.8 MPa (CM-1.5), respectively. The 3wt% CSS nanoparticles are successfully disseminated with 10% SF, exhibiting a relatively high reduction of capillary absorption. Microstructure investigation shows that CSS nanoparticles are well entangled in SF, resulting in a dense and compacted matrix structure. Therefore, CSS particles will be an advanced and sustainable nanomaterial for developing an integral hydrophobic cement composite.

Graphical Abstract

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来源期刊
CiteScore
3.30
自引率
11.80%
发文量
203
期刊介绍: The aim of the Iranian Journal of Science and Technology is to foster the growth of scientific research among Iranian engineers and scientists and to provide a medium by means of which the fruits of these researches may be brought to the attention of the world’s civil Engineering communities. This transaction focuses on all aspects of Civil Engineering and will accept the original research contributions (previously unpublished) from all areas of established engineering disciplines. The papers may be theoretical, experimental or both. The journal publishes original papers within the broad field of civil engineering which include, but are not limited to, the following: -Structural engineering- Earthquake engineering- Concrete engineering- Construction management- Steel structures- Engineering mechanics- Water resources engineering- Hydraulic engineering- Hydraulic structures- Environmental engineering- Soil mechanics- Foundation engineering- Geotechnical engineering- Transportation engineering- Surveying and geomatics.
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