臺灣博碩士論文加值系統

本研究之目的為評估台灣七大商港表層沉積物中金屬濃度分布、化學型態、潛在風險、生物可利用性及潛在移動性。每一港區設置3 – 6測站，共26測站。表層沉積物樣本於2021年3 – 4月進行採集，並進行粒徑分析、揮發性固體物、固定性固體物、總氮、總磷、總有機碳、金屬總量(Total metal, TM)及BCR®序列萃取程序(Sequentual Extraction Procedures, SEP)。
研究結果顯示，沉積物中金屬總量濃度範圍為：銅1.81 – 188 mg/kg、鋅37.1 – 643 mg/kg、鎳50.4 – 202 mg/kg、鈷5.50 – 29.8 mg/kg、鉻53.4 – 197 mg/kg及鉛47.3 – 140 mg/kg。其中高雄港金屬總量濃度以銅、鋅及鉛為最高；台中港以鎳為最高；蘇澳港以鈷為最高；花蓮港以鉻為最高。基隆港、台北港及安平港的金屬濃度較無顯著差異。此外，本研究以沉積物品質指標－污染負荷指數(Pollution load index, PLI)進一步評估金屬總量對當地沉積物是否遭受到污染。結果顯示，台北港、台中港、安平港、高雄港及蘇澳港受到金屬污染(PLI值大於1)，代表當地的沉積物有相對較高的人為污染影響。
根據SEP的分析結果顯示，港區沉積物中銅以移動相為主要組成，佔金屬總量的98.8±12.6%；鋅除了蘇澳及花蓮港以殘留態為主要組成以外，其他港區皆以移動相為主要組成，佔金屬總量的61.2±9.63%；鈷在基隆港、台北港、蘇澳港及花蓮港以殘留態為主要組成，而在台中港、安平港及高雄港則以移動相為主要組成，佔金屬總量的58.5±5.27%；鉻除了安平港以移動相為主要組成，其他港區皆以殘留態為主要組成，佔金屬總量的82.7±13.1%；鎳及鉛則皆以殘留態為主要組成，分別佔總量的88.7±16.8%及71.2±15.3%。另外，經計算生物可利用性指數(bioavailability index of metals, BIM)及潛在移動性指數(potential mobility index of metals, PMIM)結果顯示，七大商港沉積物金屬BIM皆<1 (BIM = 0.004−0.06)，代表其生物可利用性較低；七大商港沉積物金屬PMIM值介於0.02−3.17之間，其中安平港之銅(PMIM=1.53)及鉻(PMIM=1.46)的PMIM>1，高雄港之銅(PMIM=3.17)及鋅(PMIM=1.56)的PMIM>1，蘇澳港及花蓮港之銅(PMIM=1.14及1.19)的PMIM>1，各港區沉積物中部份金屬具有潛在的移動性，但整體而言，七大商港沉積物總金屬PMIT值皆<1，代表港區沉積物中整體金屬潛在移動性低，惟高雄港及安平港沉積物中金屬相較其他港區具有較高的潛在移動性。本研究結果提供了港區沉積物金屬受污染情況之基礎資訊，並可作為後續相關沉積物污染及環境背景調查研究之基礎。

The purpose of this study was to evaluate the concentration distribution, chemical speciations, potential risks, bioavailability, and potential mobility of metals in surface sediments of the seven commercial ports in Taiwan. Each port is set up with 3 – 6 stations, with a total of 26 stations. Surface sediment samples were collected in March – April 2021 and analyzed for particle size, volatile solids, fixed solids, total nitrogen, total phosphorus, total organic carbon, total metals (TM), and the BCR® sequential extraction procedures (SEP). BCR sequential extraction defines metals into four mobile fractions: soluble and exchangeable cations, and carbonate fraction (F1), iron and manganese oxyhydroxides fraction (F2), organic matter and sulfides fraction (F3), and the non-mobile or residual fraction (F4). The results showed the total metal concentrations ranges in sediments as follows: 1.81 – 188 (Cu), 37.1 – 643 (Zn), 50.4 – 202 (Ni), 5.50 – 29.8 (Co), 53.4 – 197 (Cr), and 47.3 – 140 (Pb) mg/kg. Among them, Cu, Zn, and Pb have the highest total metal concentrations in Kaohsiung Port; Taichung Port had the highest Ni concentration; Su’ao Port had the highest Co concentration; and Hualien Port had the highest Cr concentration. In addition, the metal concentrations in Keelung Port, Taipei Port, and Anping Port were not significantly different. This study further assessed the potential risks of total metals in the sediments using pollution load index (PLI). The results exhibited that Taipei Port, Taichung Port, Anping Port, Kaohsiung Port, and Su’ao Port were contaminated by metals (PLI value is greater than 1), which may pose a high potential risk to the local ecology. BCR results showed that Cu is mainly composed of the mobile fraction (F1-F3), accounting for 98.8 ± 12.6% of the total metal; Zn is mainly composed of residual fraction in Su’ao Port and the Hualien Port; while other ports are mainly composed of mobile fraction (61.2±9.63%). Cobalt is mainly composed of residual fraction in the Keelung Port, Taipei Port, Su’ao Port, and Hualien Port; however, the Taichung Port, Anping Port and Kaohsiung Port are mainly composed of mobile fraction (58.5±5.27%). Cr is mainly composed of mobile fraction in Anping Port, other ports are mainly composed of residual fraction (82.7±13.1%). Nickel and lead are mainly composed of residual fraction in all ports, accounting for 88.7±16.8% and 71.2±15.3%, respectively. In addition, bioavailability index of metals (BIM) and potential mobility index of metals (PMIM) were calculated. BIM of sediment metals in the seven commercial ports were all <1 (BIM = 0.004 − 0.06) indicating low metal bioavailability. On the other hand, PMIM values were between 0.02 and 3.17. Values for Cu (PMIM=1.53) and Cr (PMIM=1.46) in Anping Port are >1. Cu (PMIM=3.17) and Zn (PMIM=1.56) in the Kaohsiung Port, and Cu (PMIM=1.14 and 1.19) in the Su’ao Port and Hualien Port, respectively were >1 showing their potential mobility. Overall, the total metal PMIT values in the sediments of the seven commercial ports are all less than 1, indicating a generally low potential mobility. Notably, metals in the sediments of the Kaohsiung Port and Anping Port have higher potential mobility than other ports.

摘要1
Abstract3
目錄5
圖目錄9
表目錄21
第一章 前言23
1.1 研究緣起23
1.1 研究目的25
第二章 文獻回顧27
2.1 研究區域環境背景27
2.2 沉積物中金屬鍵結型態之來源及移動性29
2.3 沉積物中金屬鍵結型態分析方法33
2.4 金屬中鍵結型態分析於環境上的應用35
第三章 材料與方法39
3.1 研究架構39
3.2 沉積物樣品採集41
3.2.1 採樣地點41
3.2.2 採樣時間及方法41
3.3 材料與設備47
3.3.1 實驗藥品47
3.3.2 試劑配製49
3.3.3 試驗設備及儀器51
3.3.4 樣品前處理及分析方法52
3.4 資料分析57
3.4.1 數據分析57
第四章 品保品管61
4.1 檢量線61
4.2 方法空白樣品62
4.3 樣品查核分析63
4.4 重複樣品分析64
4.5 序列萃取各相態金屬加總與總量比值65
4.6 認證參考物質66
第五章 結果與討論70
5.1 基隆港沉積物分析結果70
5.1.1 沉積物基本性質70
5.1.2 沉積物金屬總量濃度分布75
5.1.3 沉積物金屬鍵結型態分布86
5.1.4 沉積物金屬生物可利用性及潛在移動性98
5.2 台北港沉積物分析結果100
5.2.1 沉積物基本性質100
5.2.2 沉積物金屬總量濃度分布105
5.2.3 沉積物金屬鍵結型態分布116
5.2.4 沉積物金屬生物可利用性及潛在移動性128
5.3 台中港沉積物分析結果130
5.3.1 沉積物基本性質130
5.3.2 沉積物金屬總量濃度分布135
5.3.3 沉積物金屬鍵結型態分布146
5.3.4 沉積物金屬生物可利用性及潛在移動性158
5.4 安平港沉積物分析結果161
5.4.1 沉積物基本性質161
5.4.2 沉積物金屬總量濃度分布166
5.4.3 沉積物金屬鍵結型態分布177
5.4.4 沉積物金屬生物可利用性及潛在移動性189
5.5 高雄港沉積物分析結果191
5.5.1 沉積物基本性質191
5.5.2 沉積物金屬總量濃度分布196
5.5.3 沉積物金屬鍵結型態分布207
5.5.4 沉積物金屬生物可利用性及潛在移動性219
5.6 蘇澳港沉積物分析結果222
5.6.1 沉積物基本性質222
5.6.2 沉積物金屬總量濃度分布227
5.6.3 沉積物金屬鍵結型態分布238
5.6.4 沉積物金屬生物可利用性及潛在移動性250
5.7 花蓮港沉積物分析結果253
5.7.1 沉積物基本性質253
5.7.2 沉積物金屬總量濃度分布258
5.7.3 沉積物金屬鍵結型態分布269
5.7.4 沉積物金屬生物可利用性及潛在移動性281
5.8 七大商港沉積物分析結果283
5.8.1 七大商港沉積物性質比較283
5.8.2 七大商港沉積物金屬總量濃度比較290
5.8.3 七大商港沉積物金屬鍵結型態比較302
5.8.4 七大商港沉積物金屬總量污染負荷比較313
5.8.5 七大商港沉積物金屬生物可利用性及潛在移動性比較317
第六章 結論與建議320
6.1 結論320
6.2 建議321
參考文獻322

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