臺灣西南地區沖積平原土壤碳酸鈣結核的形成及其在古氣候變遷上的意涵

范惠珍; Hui Zhen Hum

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101405

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	許正一	zh_TW
dc.contributor.advisor	Zeng-Yei Hseu	en
dc.contributor.author	范惠珍	zh_TW
dc.contributor.author	Hui Zhen Hum	en
dc.date.accessioned	2026-01-27T16:35:35Z	-
dc.date.available	2026-01-28	-
dc.date.copyright	2026-01-27	-
dc.date.issued	2025	-
dc.date.submitted	2026-01-15	-
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101405	-
dc.description.abstract	土壤碳酸鈣結核屬於化育型碳酸鹽，其形成是土壤CO2溶解成的可溶解無機碳及母質來源的Ca2+，在土壤中重新分佈後再沉澱的碳酸鈣。過去研究認爲碳酸鈣結核可能富集稀土元素 (rare earth elements, REEs)，而REEs可以作爲化育示蹤劑 (pedogenic tracer)。碳酸鈣結核的穩定碳同位素受到土壤CO2影響，土壤CO2則是由植物代謝所產生的，包含C3及C4植物。碳酸鈣結核的穩定氧同位素受到土壤中水及溫度的影響，因此可以藉由穩定氧同位素推估碳酸鈣結核形成時的溫度。碳酸鈣結核在形成後能穩定存在於土壤中，因而適合作爲推估古氣候的化育特徵。化育型碳酸鹽常見於蒸發散量大的地區，然而在臺灣西南地區沖積平原上卻有碳酸鈣結核的出現。現代濕潤的氣候條件可能不利於碳酸鈣結核的生成。因此，本研究目的為探討臺灣西南地區沖積平原上碳酸鈣結核的形成及土壤形成過程中REEs的分化，並利用碳酸鈣結核中的穩定碳與氧同位素來推估植被種類及溫度，以進一步瞭解過去的氣候條件變化。過去西南地區沖積平原在全新世時受到海進及海退影響造成的海岸線變化，可能形成了不同化育程度的土壤，為時間序列土壤。研究假設土壤在海退後開始穩定化育。研究依據海進及海退期間，於高雄採集五個同爲砂頁岩母質但不同可化育時間的土壤剖面，包括10000 years Before Present (yr BP)、8000 yr BP、5000 yr BP、3000 yr BP及2000 yr BP。除了2000 yr BP的土壤剖面 (分類為Dystrustept) 外，其他土壤剖面 (分類為Haplustalfs) 皆具有黏粒膜及碳酸鈣結核。碳酸鈣結核具有較總體土壤低的REEs (12.7-108 v.s. 132-315 mg kg-1)。REEs會相對富集於黏聚層，且在碳酸鈣結核形成的過程中REEs會產生分化 (fractionation)，並會相對富集重稀土元素 (heavy REEs, HREEs)，這表示土壤中REEs的分化主要受到淋洗作用及鈣化作用的影響。碳酸鈣結核之放射性碳定年的介於4063 yr BP 至690 yr BP之間。穩定碳同位素顯示，碳酸鈣結核形成時的植被同時具有C3及C4植物，並以C4植物爲主。穩定氧同位素顯示平均年溫度為12.3-14.0°C；地球化學氣候函數顯示當時的平均年雨量介於1036至1342 mm之間，顯示碳酸鈣結核的生成環境較現代涼 (cool) 且乾，這可能是受到當時較微弱的東亞夏季季風影響。碳酸鈣結核中穩定碳與氧同位素的分析表明，其形成時的氣候條件與土壤鈣化作用的條件相符。	zh_TW
dc.description.abstract	Soil calcium carbonate nodules are pedogenic carbonates formed by the dissolution of inorganic carbon from soil CO2 and calcium from parent materials, followed by the redistribution and reprecipitation as calcium carbonates. The enrichment of rare earth elements (REEs) in calcium carbonate nodules has been identified in previous studies, and REEs can serve as a pedogenic tracer. The main source of stable carbon isotopes in calcium carbonate nodules is the carbonate ions from the dissolution of soil CO2. The CO2 mainly originates from the metabolism of higher plants, including C3 and C4 plants. The stable oxygen isotopes in calcium carbonate nodules are mainly controlled by soil water and temperature. Hence, the temperature for the formation of calcium carbonate nodules can be estimated by the stable oxygen composition. Calcium carbonate nodules can be preserved in the soils after formation, and thus can be used for paleoclimate interpretation as a pedogenic feature. Pedogenic carbonates are commonly found in regions with high evapotranspiration rates, but can be found in the alluvial soils in southwestern Taiwan. However, the modern humid climate may be unfavorable for the formation of calcium carbonate nodules. Therefore, this study aimed to elucidate the formation of calcium carbonate nodules in alluvial plains from southwestern Taiwan, the fractionation of REEs during soil formation, and to interpret the types of vegetation and temperature using stable carbon and oxygen isotopes in calcium carbonate nodules, in order to evaluate past climatic conditions. The alluvial plains in the southwestern part were impacted by marine transgressive and regressive processes associated with shoreline changes during the Holocene, resulting in chronosequence soils with varying degrees of pedogenesis. This study hypothesized that the soils formed stably after marine regression. This study sampled five soil profiles with similar parent materials, namely sandstone and shale, and varying ages of shoreline changes from Kaohsiung, including 10000 years before present (yr BP), 8000 yr BP, 5000 yr BP, 3000 yr BP, and 2000 yr BP, according to the marine transgression and regression phases. Except for the pedon with an age of 2000 yr BP (classified as Inceptisol), clay coatings and calcium carbonate nodules were present in other pedons (classified as Alfisols). REEs contents were lower in calcium carbonate nodules than in the bulk soils (12.7-108 v.s. 132-315 mg kg-1), implying that REEs would not be concentrated in calcium carbonate nodules. The relative enrichment of REEs was found in the argillic horizon. The fractionation of REEs and relative enrichment of HREEs occurred during the formation of calcium carbonate nodules. This implied that the fractionation of REEs was influenced by leaching and calcification in the soils. The radiocarbon dating of the calcium carbonate nodules were between 4063 yr BP to 690 yr BP. The stable carbon isotopes revealed the coexistence of C3 and C4 plants, with a predominance of C4 plants. The stable oxygen isotopes indicated a mean annual temperature of 12.3 to 14.0°C, and the mean annual precipitation was estimated to be 1036 to 1342 mm using the geochemical climofunction. This study suggested that the climatic conditions during the formation of calcium carbonate nodules were cooler and drier than those of the present, and were likely due to a weaker East Asian Summer Monsoon (EASM). The stable carbon and oxygen isotopes of calcium carbonate nodules further demonstrate that the climatic conditions during their formation are consistent with the pedogenic conditions for calcification.	en
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dc.description.provenance	Made available in DSpace on 2026-01-27T16:35:35Z (GMT). No. of bitstreams: 0	en
dc.description.tableofcontents	謝辭 I 摘要 II Abstract IV 目次 VI 圖次 VIII 表次 X 第 1 章前言 1 第 2 章文獻回顧 4 2.1 何謂土壤碳酸鈣結核 4 2.2 碳酸鈣結核的形成及影響因子 7 2.3 碳酸鈣結核的元素特徵 9 2.4 臺灣的土壤碳酸鈣結核分佈 11 2.5 同位素分析技術在碳酸鈣結核之應用 13 2.6 土壤碳酸鈣結核與氣候變遷的關係 15 第 3 章材料與方法 18 3.1 研究區域及環境概況 18 3.2 土壤剖面調查與野外形態特徵描述 19 3.3 土壤薄切片及微形態觀察 24 3.4 元素空間分析 24 1. 高解析電子微探儀 24 2. 雷射剝蝕感應耦合電漿質譜儀 24 3.5 土壤物理化學性質分析 25 1. 水分含量 25 2. 總體密度 25 4. 土壤反應 (pH值) 25 5. 質地分析 26 6. 電導度 27 7. 有機碳及無機碳 27 8. 陽離子交換容量 28 9. 鹽基飽和度 28 10. 無定形金屬含量 29 11. 游離性金屬含量 29 12. 碳酸鈣當量 30 3.6 土壤礦物組成 30 3.7 土壤元素組成 33 3.8 碳酸鈣結核之分析 34 1. 結核之量化 34 2. 元素組成 34 3. 礦物組成 35 4. 穩定碳及氧同位素 35 5. 放射性碳定年 36 3.9 稀土元素之分化指標 36 3.10 推估溫度及降雨之函數 37 第 4 章結果與討論 39 4.1 土壤野外形態特徵 39 4.2 土壤微形態特徵 45 4.3 土壤物理化學性質 56 4.4 土壤礦物組成 64 4.5 土壤之元素組成 71 4.6 碳酸鈣結核之形態及含量 76 4.7 碳酸鈣結核之礦物及元素組成 83 4.8 碳酸鈣結核之穩定碳與氧同位素特徵 91 4.9 碳酸鈣結核之放射性碳定年 95 4.10 土壤分類及化育作用 97 4.11 稀土元素分化與土壤海退年代之關係 100 4.12 碳酸鈣結核與古環境之推估 111 第 5 章結論 114 第 6 章參考文獻 115	-
dc.language.iso	zh_TW	-
dc.subject	古氣候	-
dc.subject	化育作用	-
dc.subject	化育型碳酸鹽	-
dc.subject	稀土元素	-
dc.subject	穩定碳同位素	-
dc.subject	穩定氧同位素	-
dc.subject	paleoclimate	-
dc.subject	pedogenesis	-
dc.subject	pedogenic carbonate	-
dc.subject	rare earth elements	-
dc.subject	stable carbon isotopes	-
dc.subject	stable oxygen isotopes	-
dc.title	臺灣西南地區沖積平原土壤碳酸鈣結核的形成及其在古氣候變遷上的意涵	zh_TW
dc.title	Formation and paleoclimatic change implications of calcium carbonate nodules in the soils of alluvial plains in southwestern Taiwan	en
dc.type	Thesis	-
dc.date.schoolyear	114-1	-
dc.description.degree	博士	-
dc.contributor.oralexamcommittee	王尚禮;陳尊賢;王珮玲;簡士濠;黃國芳	zh_TW
dc.contributor.oralexamcommittee	Shan-Li Wang;Zueng-Sang Chen;Pei-Ling Wang;Shih-Hao Jien;Kuo-Fang Huang	en
dc.subject.keyword	古氣候,化育作用化育型碳酸鹽稀土元素穩定碳同位素穩定氧同位素	zh_TW
dc.subject.keyword	paleoclimate,pedogenesispedogenic carbonaterare earth elementsstable carbon isotopesstable oxygen isotopes	en
dc.relation.page	135	-
dc.identifier.doi	10.6342/NTU202600116	-
dc.rights.note	同意授權(限校園內公開)	-
dc.date.accepted	2026-01-16	-
dc.contributor.author-college	生物資源暨農學院	-
dc.contributor.author-dept	農業化學系	-
dc.date.embargo-lift	2026-01-28	-
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