Change in lumen pore structure of halloysite nanotube membrane coating under varying pressure, time and temperature

IF 2.5 4区 材料科学 Q2 CHEMISTRY, APPLIED
Sarbasree Dutta, Nandini Das
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Abstract

In this article, the suitability of utilization of porous lumen structure of Halloysite (Hal) nanoclay has been studied elaborately. To utilize the lumen structure for membrane development, the effect of temperature, pressure and time on the porous lumen feature and subsequent use of the clay in pristine form as a membrane coating material for separation purposes at specified temperatures shows the importance of this study. The present study investigates structural changes in Halloysite nanoclay's inherent porous tubular morphology. Membranes are prepared by coating clay-alumina porous support tube with Halloysite sol under pressure and temperature of 100 and 160 °C for 24, 48 and 64 h, respectively. XRD and FTIR reveal that the tubular structure remains intact under experimental conditions. In contrast, the morphology of pristine Hal powder treated at the specified temperature and under in situ developed autogenous pressure shows a significant textural change in the nanotubular morphology observed from FESEM. At 100 °C, lumen porosity remains intact, but at 160 °C, under higher pressure, lumen mouth sealing, conjoining and coalescence of the halloysite nanotubes (HNT) result. In addition, for both temperatures under existing operating pressure, the effect of 24 h time duration on morphology is less. For practical viability, a preliminary study for dye removal is carried out with H1 membrane coating, which shows promising %rejection values. This study on powders and membrane coatings might thus help to assign new application fields, such as membrane-based separation utilizing the porous nature of HNT by controlling different process parameters.

在不同压力、时间和温度条件下霍洛石纳米管膜涂层腔孔结构的变化
摘要 本文详细研究了利用纳米霍洛石(Hal)多孔内腔结构的适宜性。为了将内腔结构用于膜开发,温度、压力和时间对多孔内腔特征的影响,以及随后在特定温度下将原始形态的粘土用作分离目的的膜涂层材料,都表明了这项研究的重要性。本研究调查了霍洛石纳米粘土固有多孔管状形态的结构变化。在压力和温度分别为 100 和 160 °C 的条件下,将哈洛来石溶胶涂覆在粘土-氧化铝多孔支撑管上,分别持续 24、48 和 64 小时,制备出膜。XRD 和 FTIR 显示,管状结构在实验条件下保持完好。与此相反,在特定温度和原位自生压力下处理的原始 Hal 粉末的形态显示,从 FESEM 观察到的纳米管形态发生了显著的纹理变化。在 100 °C 时,管腔孔隙率保持不变,但在 160 °C 时,在更高的压力下,管腔口密封、连接和霍洛石纳米管 (HNT) 凝聚。此外,在现有工作压力下的两种温度下,24 小时的持续时间对形态的影响较小。为了切实可行,使用 H1 膜涂层进行了染料去除的初步研究,结果显示了很好的去除率。因此,对粉末和膜涂层的研究可能有助于确定新的应用领域,例如通过控制不同的工艺参数,利用 HNT 的多孔性进行膜分离。
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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来源期刊
Journal of Porous Materials
Journal of Porous Materials 工程技术-材料科学:综合
CiteScore
4.80
自引率
7.70%
发文量
203
审稿时长
2.6 months
期刊介绍: The Journal of Porous Materials is an interdisciplinary and international periodical devoted to all types of porous materials. Its aim is the rapid publication of high quality, peer-reviewed papers focused on the synthesis, processing, characterization and property evaluation of all porous materials. The objective is to establish a unique journal that will serve as a principal means of communication for the growing interdisciplinary field of porous materials. Porous materials include microporous materials with 50 nm pores. Examples of microporous materials are natural and synthetic molecular sieves, cationic and anionic clays, pillared clays, tobermorites, pillared Zr and Ti phosphates, spherosilicates, carbons, porous polymers, xerogels, etc. Mesoporous materials include synthetic molecular sieves, xerogels, aerogels, glasses, glass ceramics, porous polymers, etc.; while macroporous materials include ceramics, glass ceramics, porous polymers, aerogels, cement, etc. The porous materials can be crystalline, semicrystalline or noncrystalline, or combinations thereof. They can also be either organic, inorganic, or their composites. The overall objective of the journal is the establishment of one main forum covering the basic and applied aspects of all porous materials.
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