本研究的目的乃在於開發具有高通量及低逆溶質擴散量之碳複合薄膜，並應用於正滲透分離系統 (Forward osmosis, FO) 之中，期望能為全球水資源短缺問題做出貢獻。目前正滲透複合膜多以不織布或是高分子作為支撐膜材，本研究移除傳統支撐層材料，而以奈米碳管 (Carbon nanotubes, CNTs) 抽濾成薄膜作為支撐層，製備更薄且擁有更高水通表現之碳管薄膜。研究中透過聚多巴胺 (Polydopamine, PDA) 與聚乙烯醇 (Polyvinyl alcohol, PVA) 之協助，加強了CNT支撐層之親水性質與機械強度，接著使用傳統界面聚合法合成聚醯胺阻鹽層 (Polyamide, PA) ，完成薄膜的製備。研究內容包含表面形貌探討、表面官能基分析、親水性質、元素鍵結、粗糙度分析以及FO性能等測試。
研究結果顯示，PDA與PVA的聚合能使碳管更緊密黏著，加強薄膜在FO系統中之水流承受度，同時提升親水性質；不同抽濾含量可對薄膜厚度進行控制，厚度的降低能有效提升水通量；PVA濃度影響薄膜內部孔洞率，儘管濃度提升有助於機械性質的增加，卻會降低水通表現。本研究開發之碳管複合薄膜中，PVA0.25pCNT3-PA有最佳FO效能，在1M氯化鈉水溶液作為提取液與去離子水作為進流液的FO系統中，水通量為30.16 Lm-2h-1，逆溶質擴散量僅為9.34 gm-2h-1。此水通表現相較於較厚且未改質之碳複合薄膜高出近350%，再加上相對簡單的製程，說明了此研究在正滲透薄膜領域極具發展潛力。

This study aims to fabricate a thin-film composite (TFC) membrane with high water flux and low reverse solute flux in the application of forward osmosis (FO), hoping to make contribution to the global water crisis. Instead of using the traditional non-woven fabric or polymer material, carbon nanotube (CNT) is adopted as the substitutional support layer by the vacuum filtration method. Polydopamine (PDA) and polyvinyl alcohol (PVA) are used not only to increase the mechanical strength but also the hydrophilicity of the CNT membrane. Finally, a polyamide (PA) layer is fabricated by the interfacial polymerization method as the active layer. The characteristics of the membrane include surface morphology, surface functional groups, hydrophilicity, element bonding, surface roughness, and FO performance tests. Results show that PDA and PVA utilization sticks the CNT together, strengthening the tolerance of the membrane under FO testing system, meanwhile increasing the hydrophilicity. Membrane thickness can be controlled by using different CNT suspension filtration amount, and thinner membranes lead to higher water fluxes. The concentration of PVA influences the pores within the membrane and also plays an important role in the FO performance. The best FO properties are performed by PVA0.25pCNT3-PA, with a water flux of 30.16 Lm-2h-1 and reverse solute flux as low as 9.34 gm-2h-1. This water flux is almost 350% higher than that of the thicker CNT composite membrane. Therefore, the good FO performance and the relatively simple process of this study indicate great potential of this work in the application of FO field.

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