Parameters Synthesis of Na-Magadiite Materials for Water Treatment and Removal of Basic Blue-41: Properties and Single-Batch Design Adsorber

Abdulaziz M. Alanazi, Hmoud Al Dmour, Saheed A. Popoola, Hicham Oudghiri Hassani, Souad Rakass, Rawan Al-Faze, Fethi Kooli
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Abstract

Na-magadiite materials were prepared from a gel containing a silica source, sodium hydroxide, and water via hydrothermal treatment at different temperatures (130 °C to 170 °C) and periods of time (1 day to 10 days). In this study, four silica sources were selected (fumed silica, colloidal silica, Ludox HS-40%, and Ludox AS-40%). Variable conditions such as sodium hydroxide and water contents were explored at a specific temperature and reaction time. The obtained materials were characterized by using X-ray diffraction (XRD), thermogravimetry differential thermal analysis TG-DTA, scanning electron microscopy with energy dispersive X-ray spectroscopy (SEM-EDX), Fourier Transform Infrared spectroscopy (FTIR), solid 29Si magic angle spinning magnetic nuclear resonance (MAS MNR, and nitrogen adsorption isotherms. A pure Na-magadiite phase was obtained from the four silica sources at a synthesis temperature of 150 °C after a period of one to two days with a characteristic basal spacing of 1.54 nm. At a longer reaction time of 3 days and a higher temperature of 170 °C, Na-kenyaite with a basal spacing of 2.01 nm was achieved, in addition to a quartz phase. The content of water or sodium hydroxide in the gel affected the nature of the prepared phases. A cauliflower-like morphology was obtained from colloidal silica sources, while a different morphology was achieved using solid fumed silica. The 29Si solid NMR confirmed the presence of Q3 and Q4 silicon sites in the Na-magadiite materials. The optimal Na-magadiite materials at 150 °C for 2 days were assessed for their ability to remove Basic Blue-41 dye from artificially contaminated aqueous solution. The Langmuir equation was used to estimate the maximum removal capacity. A maximum removal capacity of 219 mg/g was achieved using Na-magadiite prepared from a Ludox-HS40% silica source, and a maximum removal capacity of 167 mg/g was observed for Na-magadiite prepared from fumed silica. Basic Blue-4’s removal percentage was enhanced at basic pH levels (8 to 10) to a maximum of 95%. These materials could be regenerated for seven cycles of reuse with a reduction of 27 to 40% of the original values. Therefore, Na-magadiite materials are promising and efficient removal agents for the removal of Basic Blue-41 from effluents.
Na-Magadiite水处理及脱除碱性蓝-41材料的合成:性能及单批设计吸附器
以含硅源、氢氧化钠和水的凝胶为原料,在不同温度(130℃~ 170℃)和不同时间(1天~ 10天)下进行水热处理,制备Na-magadiite材料。在本研究中,选择了四种二氧化硅源(气相二氧化硅,胶体二氧化硅,Ludox HS-40%和Ludox AS-40%)。在特定的温度和反应时间下,探索了氢氧化钠和水含量等不同条件。采用x射线衍射(XRD)、热重差热分析TG-DTA、x射线能谱扫描电镜(SEM-EDX)、傅里叶变换红外光谱(FTIR)、固体29Si魔角自旋核磁共振(MAS MNR)和氮吸附等温线对所得材料进行了表征。在合成温度为150℃的条件下,经过1 ~ 2天的时间,从四种硅源中获得了纯Na-magadiite相,其特征基间距为1.54 nm。在较长的反应时间(3天)和较高的反应温度(170℃)下,得到了基间距为2.01 nm的Na-kenyaite,同时还含有石英相。凝胶中水或氢氧化钠的含量影响所制备相的性质。从胶体二氧化硅源获得了花椰菜状的形态,而使用固体气相二氧化硅获得了不同的形态。29Si固体核磁共振证实了Na-magadiite材料中存在Q3和Q4硅位。在150°C下放置2天,评估了Na-magadiite材料从人工污染的水溶液中去除碱性蓝-41染料的能力。用Langmuir方程估计了最大去除能力。Ludox-HS40%二氧化硅源制备的Na-magadiite的最大去除率为219 mg/g,气相二氧化硅源制备的Na-magadiite的最大去除率为167 mg/g。碱性蓝-4在基本pH值(8 ~ 10)下的去除率最高可达95%。这些材料可以再生七个循环再利用,减少27%至40%的原始价值。因此,钠镁辉石材料是一种很有前途的高效脱除碱性蓝-41的材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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