以銀粒子修飾之靜電紡絲碳纖維電極進行電容去離子系統抗菌之研究

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郭芷君(Zhi-Jun Guo) 查詢紙本館藏

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論文名稱

以銀粒子修飾之靜電紡絲碳纖維電極進行電容去離子系統抗菌之研究
(Electrospinning carbon fiber electrode modified by silver particles for antimicrobial assay of capacitive deionization system)

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至系統瀏覽論文 (2026-10-19以後開放)

摘要(中)

電容去離子（CDI）是一種低能耗的技術。該技術有利於水的再生，可以減少處理過程中的水資源浪費，甚至減少溫室氣體的排放。然而，水中的微生物可能會附著在電極上並形成生物膜，有造成多孔電極被堵塞並影響電吸附之隱憂。通過銀粒子廣為人知的抗菌能力和靜電紡絲的優越潛力，本研究開發用於CDI系統的修飾電極。在本研究中，0.05 CF-Ag和0.1 CF-Ag具有相似的抗菌性能，推測0.05 M的電鍍液濃度可能已經達到最大抗菌極限，故而選擇0.05 CF-Ag作為最佳電極。CF電極和0.05 CF-Ag電極的重複使用性在不含微生物的100 ppm NaCl中進行重複充電、放電循環，然後將0.05 CF-Ag電極轉移到人工調配的微生物懸浮液中進行抗菌測定。結果顯示0.05 CF-Ag的抗菌能力在多次循環後仍保持在一定水平。藉由觀察使用過後的電極表面形態特徵，證明了電極之間的差異。由於相對較優秀的抗菌能力，0.05 CF-Ag和0.1 CF-Ag上所形成的生物膜最少。結果表明本研究所製備的複合電極限制了微生物的附著。

摘要(英)

Capacitive deionization (CDI) is a low-energy consumption technology. It is a beneficial water regeneration technology to avoid secondary waste and lower the greenhouse gas emission. The microorganism in water might attach to the electrodes and form biofilm. It was concerned that the porous electrodes might be blocked and the electrosorption might be interfered. As silver particles are well-known for their antimicrobial ability, silver particle modified electrospun carbon fiber electrodes were synthesized for the CDI system in this study. It has been found that 0.05 CF-Ag and 0.1 CF-Ag had a similar antimicrobial performance. It was speculated that the electroplate solution concentration of 0.05 M silver nitrate might reach the limit of antimicrobial ability; thus, 0.05 CF-Ag was selected as the optimal electrode. The reusability of the CF electrode and 0.05 CF Ag electrode was examined in 100 ppm NaCl without bacteria. Then the electrodes were transferred to artificial microbial suspension for antimicrobial assay. The antimicrobial ability of 0.05 CF-Ag still remained at a certain level after 16 cycles. The surface morphological characterization of used electrodes had demonstrated the differences among the electrodes. For the relatively higher antimicrobial ability, the biofilm form on the 0.05 CF-Ag and 0.1 CF Ag were the least. The results indicated the prepared silver-carbon fiber electrode limited the attachment of microorganism.

關鍵字(中)

★ 電容去離子
★ 抗菌
★ 靜電紡絲
★ 銀粒子

關鍵字(英)

★ capacitive deionization
★ antimicrobial
★ electrospinning
★ silver particle

論文目次

Content
摘要 iii
Abstract iv
致謝 vi
Content viii
List of Figures xi
List of Tables xiv
Chapter 1 Introduction 1
1.1 Background 1
1.2 Objective 3
Chapter 2 Literature Reviews 5
2.1 Electrospinning 5
2.1.1 Theory 5
2.1.2 Parameters 8
2.1.3 Electrospinning CF for CDI 10
2.2 Capacitive deionization 11
2.2.1 Theory of electrical double layer 12
2.2.2 Operating system 14
2.2.3 Affecting factors in CDI system 16
2.2.4 Disinfection in CDI system 16
2.3 Silver particle 18
2.3.1 Antimicrobial activity 18
2.3.2 Toxicity to biology 19
2.3.3 Application of silver products 21
2.3.4 Fabrication of silver particle 22
Chapter 3 Materials and Methods 25
3.1 Preparation of silver/carbon fiber (CF-Ag) 25
3.1.1 Preparation of carbon fiber by electrospinning 25
3.1.2 Preparation of silver/carbon fiber (CF-Ag) 26
3.2 Characterization of CF and CF-Ag electrodes 27
3.3 Antimicrobial and deionization assays via CDI 30
Chapter 4 Results and Discussions 36
4.1 Preparation of the modified electrodes 36
4.1.1 Optimization of the electroplating conditions 36
4.1.2 Electrochemical characterization of CF and CF-Ag electrodes 41
4.2 Characterization of electrode materials 43
4.2.1 Morphological characterization of CF and CF-Ag 43
4.2.2 Specific surface area and pore size distribution analysis 46
4.2.3 Functional groups on CF and CF-Ag 51
4.2.4 XRD analysis 52
4.2.5 Deionization in CDI 54
4.3 CDI performance in microbial suspension 56
4.3.1 Effects of silver nitrate concentration on antimicrobial ability in CDI 56
4.3.2 Effects of electrical potential on antimicrobial ability in CDI 61
4.3.3 Effects of reusability on antimicrobial ability in CDI 64
4.4 Characterization of used electrode 71
Chapter 5 Conclusion and Suggestions 74
5.1 Conclusion 74
5.2 Suggestion 75
Reference 76

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指導教授

秦靜如(Ching-Ju Chin)

審核日期

2021-10-19

推文