利用兩性離子表面塗層探討抗石蓴孢子及藤壺腺介幼蟲附著之研究

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陳司盛(Si-Sheng Chen) 查詢紙本館藏

畢業系所

化學工程與材料工程學系

論文名稱

利用兩性離子表面塗層探討抗石蓴孢子及藤壺腺介幼蟲附著之研究
(Surface coating with zwitterionic materials for anti Ulva zoospores and barnacle cypris larvae settlement studies)

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摘要(中)

過去幾十年研究中，彈性模數、表面自由能及兩性離子材料對海洋抗污塗層的發展有重大的影響。本研究期待結合低彈性模數材料聚二甲基矽氧烷（polydimethylsiloxane, PDMS）和兩性離子材料磺基甜菜鹼矽烷（sulfobetaine silane, SBSi）作為一種新的抗海洋生物汙損（anti-marine biofouling）塗層，並以藤壺（Amphibalanus amphitrite）的腺介幼蟲（cyrpids）和石蓴（Ulva lactuca, Ulva fasciata）的游動孢子（zoospores）作為抗海洋生物污損之研究物種。本研究主要進行腺介幼蟲錄影追蹤觀測、腺介幼蟲附著檢測及石蓴孢子附著檢測，其中使用玻璃、Fluorosilane、PDMS、SBSi四種表面。於腺介幼蟲錄影追蹤觀測中，影像顯示它沒有附著的傾向抑或是無法附著在PDMS-SBSi表面上，同時，PDMS-SBSi表面在兩天的腺介幼蟲附著檢測中只有2%的腺介幼蟲附著率；在石蓴孢子附著檢測中，PDMS-SBSi表面上有最小的游動孢子附著數量以及水流沖擊後的92％孢子去除率。由此可見，PDMS和SBSi的組合確實具有對藤壺幼蟲和石蓴孢子的抗污染性，而且，在對抗石蓴孢子時，這個組合更展現了優異的污損釋放特性。基於這些測定，我們將可以進一步探討PDMS-SBSi對藤壺幼蟲的污損釋放，或是深入研究表面的化學性質，使用表面電漿共振儀（SPR）來檢測附著誘導蛋白複合物（SIPC）是否吸附在PDMS-SBSi上。

摘要(英)

In the past few decades, elastic modulus, surface free energy and zwitterionic materials have been a key element of the development of marine antifouling coatings. This study combines a low elastic modulus material (polydimethylsiloxane, PDMS) and a zwitterionic material (sulfobetaine silane, SBSi) as a new anti-marine biofouling. Barnacle cypris larva (Amphibalanus amphitrite) and Ulva zoospores (Ulva lactuca, Ulva fasciata) are used as research species against marine biofouling. This study mainly carried out video tracking observation of cyprids (barnacle cypris larva), cyprids settlement assay and Ulva zoospores settlement assay, which used glass, fluorosilane, PDMS and SBSi. In the video tracking, the film showed that it had no tendency to adhere or could not adhere to the surface of PDMS-SBSI. At the same time, only 2% of the cyprids settled on the surface of the PDMS-SBSI for two days. In the settlement assay of Ulva zoospores, the attached number of zoospores is lower on the surface of PDMS-SBSI and the 92% of the attached zoospores removed after water flow impact. The study result indicate that the combination of PDMS and SBSI does have anti-contamination against barnacle cypris larva and Ulva zoospores, also, this combination exhibits superior fouling release characteristics when against Ulva zoospores. Based on these measurements, we will further investigate the stain release of PDMS-SBSI on barnacle cypris larva, or in-depth study of surface chemistry, using surface plasma resonator (SPR) to detect adhesion-induced protein complex (SIPC) adsorption on PDMS-SBSI.

關鍵字(中)

★ 藤壺
★ 石蓴
★ 海洋
★ 防污
★ 兩性離子

關鍵字(英)

★ barnacle
★ ulva
★ marine
★ antifouling
★ zwitterion

論文目次

摘要 i
Abstract ii
誌謝 iii
圖目錄 viii
表目錄 x
第一章緒論 1
第二章文獻回顧 3
2.1海洋生物污損 3
2.1.1藤壺 5
2.1.2石蓴 12
2.2防污塗料 14
2.2.1污損阻抗塗層 15
2.2.2污損釋放塗層 16
2.2.3仿生防污塗層 16
2.2.4生物降解高分子塗層 17
2.3錄影追蹤 19
2.4附著檢測 22
第三章實驗藥品、儀器設備與方法 23
3.1實驗藥品 23
3.2儀器設備 24
3.3實驗方法 25
3.3.1聚二甲基矽氧烷PDMS固化 25
3.3.2兩性離子材料SBSi合成 25
3.3.3兩性離子材料SBSi接枝 26
3.3.4腺介幼蟲錄影追蹤觀測Cyprids video tracking 27
3.3.5腺介幼蟲附著檢測Cyprids settlement assay 28
3.3.6石蓴孢子附著檢測Ulva zoospores settlement assay
30
第四章實驗結果與討論 34
4.1表面材料防污測試 34
4.1.1藤壺幼蟲行為觀測 34
4.1.2石蓴孢子附著檢測 39
第五章結論 47
5.1結論 47
5.2未來展望 48
第六章參考文獻 49

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指導教授

陳文逸(Wen-Yih Chen)

審核日期

2019-7-25

推文