福山天然闊葉林25公頃永久樣區土壤性質之空間變異

Wei-Chi Liao; 廖偉志

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33761

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	陳尊賢(Zueng-Sang Chen)
dc.contributor.author	Wei-Chi Liao	en
dc.contributor.author	廖偉志	zh_TW
dc.date.accessioned	2021-06-13T05:45:42Z	-
dc.date.available	2008-07-19
dc.date.copyright	2006-07-19
dc.date.issued	2006
dc.date.submitted	2006-07-12
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Relations of soil properties to topography and vegetation in subtropical rain forest in southern Taiwan. Plant Ecol. 132:229-241. Corre, M. D., R. R. Schnabel, and W. L. Stout. 2002. Spatial and seasonal variation of gross nitrogen transformation and microbial biomass in a Northeastern US grassland. Soil Biol. Biochem. 34:445-457. Donald, R. G., D. W. Anderson, and J. W. B. Stewart. 1993. The distribution of selected soil properties in relation to landscape morphology in forested Gray Luvisol soils. Can. J. Soil Sci. 73:165-172. Finzi, A. C., N. van Breemen, and C. D. Canham. 1998. Canopy tree-soil interactions within temperate forests: species effects on soil carbon and nitrogen. Ecol. Appl. 8:440-446. Hall, G. F. Pedology and geomorphology. 1983. p.117-140. In L. P. Wilding, N. E. Smeck, and G. F. Hall (ed.) Pedogenesis and soil taxonomy I. Concepts and interactions. Elsevier, Amsterdam. Hole, F. D. 1961. A classification of pedoturbation and some other processes and factors of soil formation in relation to isotropism and anisotropism. Soil Sci. 91:375-377. Hsieh, C. F., Z. S. Chen, Y. M. Hsu, K. C. Yang, and T. H. Hsieh. 1998. Altitudinal zonation of evergreen broad-leaved forest on Mount Lopei, Taiwan. J. Veg. Sci. 9:201-212. Huddleston, J. H., and F. F. Riecken. 1973. Local soil-landscape relationships in western Iowa: I. Distribution of selected chemical and physical properties. Soil Sci. Soc. Am. Proc. 37:264-270. Huggett, R. J. 1975. Soil landscape systems: A model of soil genesis. Geoderma 13:1-12. Kaye, J. P., Binkley, X. Zou, and J. A. Parrotta. 2002. Non-labile soil 15N retention beneath three three tree species in a tropical plantation. Soil Sci. Soc. Am. J. 66:612-619. Kaye, J. P., S. C. Resh, M. W. Kaye, and R. A. Chimner. 2000. Nutrient and carbon dynamics in a replacement series of Eucalyptus and Albizia trees. Ecol. 81:3267-3273. Kleiss, H. J. 1970. Hillslope sedimentation and soil formation in northeastern Iowa. Soil Sci. Soc. Am. Proc. 34:287-290. Kubota, D., T. Masunaga, Hermansah, A. Rasyidin, M. Hotta, Y. Shinmura, and T. Wakatsuki. 1998. Soil environment and tree species diversity in tropical rain forest, West Sumatra, Indonesia. P.159-167. In A. Schult and D. Ruhiyat (ed) Soil of tropical forest ecosystems. Springer, Heidelberg, Germany. Malo, D. D., B. K. Worcester, D. K. Cassel, and K. D. Matzdorf. 1974. Soil-landscape relationship in a closed drainage system. Soil Sci. Soc. Am. Proc. 38:813-818. Mellio, J. M., J. D. Aber, A. E. Linkins, A. Ricca, B. Fry, and K. J. Nadelhoffer. 1989. Carbon and nitrogen dynamics along the decay continuum: plant litter to soil organic matter. Plant Soil 115:189-198. Mendham, D. S., A. M. O’Connell, T. S. Grove, and S. J. Rance. 2003. Residue management effects on soil carbon and nutrient contents and growth of second rotation eucalypts. For. Ecol. Manage. 181:357-372. Nizeyimana, E., and T. J. Bicki. 1992. Soil and soil-landscape relationship in the north central region of Rwanda, east-central Africa. Soil Sci. 153:225-236. Partric, J. H. 1976. Soil erosion in the eastern forest. J. For. 74:671-677. Pennock, D. J., B. J. Zebarth, and E. de Jone. 1987. Landform classification and soil distribution in hummocky terrain, Saskatchewan, Canada. Geoderma 40:297-315. Prescott, C. E. 2002. The influence of the forest canopy on nutrient cycling. Tree Physiol. 22:1193-1200. Rothe, A., and D. Binkley. 2001. Nutrient interaction in mixed species forest:a synethesis. Can. J. For. Res. 31:1855-1870. Sollins, p. 1998. Factors influencing species composition in tropical lowland rain forest: does soil matter? Ecol. 79:23-30. Su, S. H., C. H. Chang Yang, C. L. Lu, T. T. Lin, C. L. Lin, W. L. Chiou, I. F. Sun, C. F. Hsieh, H. B. King. 2006. The ecology of tree species in Fushan Forest Dynamics Plot, Taiwan. Taipei: Taiwan Forest Research Institute. (In Press) Tsui, C. C., C. F. Hseih, and Z. S. Chen. 2004. Relationship between soil properties and landscape in a lowland rain forest of southern Taiwan. Geoderma 123:131-142. Veneterea, R. T., Lovett, G. M., Groffman, P. M., Schwarz, P. A., 2003. Landscape patterns of net nitrification in a northern hardwood-conifer forest. Soil Sci Soc. Am. J. 67: 527-539. Webb, L. J. 1969. Edaphic differentiation of some forest types in eastern Australia: II. Soil chemical factors. J. Ecol.. 57:817-830. White, E. M. 1991. Vegetation-soil relationship on thin or shallow range sites in western south Dakota. Soil Sci. Soc. Am. J. 55:1453-1456.
dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/33761	-
dc.description.abstract	土壤之地形與植被因子直接作用於土壤，對土壤生成化育的影響很大。在不同的地形位置所形成的土壤之性質不盡相同，因而化育出不同的植被型態，而樹種的分佈差異對於土壤鹽基含量與養份的補充亦有不同。台灣東北部福山地區設置25公頃天然闊葉林永久樣區之目的之一，在於提供一個可供長期亞熱帶森林動態學研究的大型樣區。本研究的目的在於建立福山天然闊葉林永久樣區基本的土壤資料庫，以探討研究區內土壤性質分布及其變動與地形位置或植群分佈的關係，並試圖說明土壤養分狀況與植群分布間的關聯。研究樣區分為80個土壤採樣網格區，採樣時將每個網格區分為四個相同分區，以土鑽在不同的深度0-5 cm、5-15 cm、15-30 cm進行採樣，並將四分區採集的土壤再混合成採樣網格區之代表性土壤樣品。再依五個不同的地形位置，包括平坦區、山頂區、斜坡區、溪流區及西北方山谷區域，對採樣網格進行數據分組及各種土壤性質之數據統計分析比對，檢視不同地形位置及植群分佈下土壤性質之差異及空間變化。研究結果顯示，在不同的地形位置(平坦區、山頂區、斜坡區、溪流區及山谷區)其土壤的性質間有顯著差異(p<0.05)。地表5 cm的土壤有機碳含量與其他土壤性質具有顯著相關(p<0.05)，指出福山森林表層土壤性質深受土壤有機質含量之影響。有機碳有累積於地勢較低漥的地區的趨勢。此外，植被生育地類型的有機碳含量則顯著高於其他類型。根據地形因子與有機質的相關分析，顯示有機質可能亦受到植被的影響。有效磷與有效鉀含量在西北山谷區顯著較高(p<0.05)。樣區的三種森林生育地類型之分布與樣區不同的地形位置確實有關，顯示林相的分布與地形位置或土壤性質有關，應可進ㄧ步探討分析。	zh_TW
dc.description.abstract	Both landscape and vegetation directly affect the soil formation and soil characteristics. The soils derived from different landscape positions and vegetation types are not exactly resemble on soil physical and chemical characteristics. One of the purposes of establishing Fushan permanent research site is to understand the dynamics of subtropical forest ecosystem. The objective of this study is to examine the relations between the change of soil properties and dominant landscape positions or distribution of main vegetation types. The research site was divided into 80 subplots for sampling. A subplot was divided into 4 equal parts by auger to sample the soil samples at 0-5 cm, 5-15 cm, and 15-30 cm soil depth. The study area was also divided into five different landscape-based regions including Slightly flat region, Summit region, Slope region Creek region, and Northwestern valley, to compare the difference of soil properties at different landscape regions or among different regions of vegetation types. The results of this study showed that there are significant differences of soil properties located at different landscape regions (p<0.05). The soil properties of surface 5cm depth are strongly related to it’s organic carbon content. The organic carbon content is higher in the lowland. Furthermore, the organic carbon content in vegetation Type1 is significantly higher than other vegetation Types. Pearson correlation coefficient between topographic factors and soil properties revealed that the organic carbon content could be related to the vegetation. Available P, available K are relative higher at the Northwestern valley region. The distribution of three vegetation types is related to the distribution of landscapes. Although the relations between soil properties and landscape have been better understood, further studies are required to clarify the relationships between soil nutrient status and the distribution of vegetation types in this permanent site.	en
dc.description.provenance	Made available in DSpace on 2021-06-13T05:45:42Z (GMT). No. of bitstreams: 1 ntu-95-R93623012-1.pdf: 2371895 bytes, checksum: d921a240a648acbe3c3d735ad4ab85d6 (MD5) Previous issue date: 2006	en
dc.description.tableofcontents	目錄中文摘要 ................................................Ι 英文摘要 ...............................................Ⅲ 第一章、前言 ............................................1 一、土壤、地形與植被三者間的關係 ........................1 二、土壤性質與地形的關係 ................................1 三、土壤性質與植被的關係 ................................2 四、研究目的 ............................................2 第二章、研究區概述 ......................................3 一、地理位置 ............................................3 二、氣候 ................................................3 三、植生 ................................................3 四、不同地形位置之土壤剖面特性 ..........................9 第三章、材料與方法 .....................................13 一、土壤性質 ...........................................13 (一)土壤樣品的採集 .....................................13 (二)實驗室分析 .........................................13 二、資料分析 ...........................................16 (一)地形資料 ...........................................16 (二)土壤性質 ...........................................16 (三)土壤性質之分佈 .....................................18 第四章、結果與討論 .....................................19 第一節、地形因子與土壤性質的關係 .......................19 第二節、不同地形位置的土壤性質差異 .....................19 一、各層的土壤性質的差異 ...............................19 二、土壤pH與電導度值 ...................................24 三、有效性氮、磷、鉀 ...................................24 四、有機碳 .............................................33 五、交換性鹽基 .........................................40 六、綜合討論 ...........................................47 第三節、不同植被形式的土壤性質差異 .....................53 一、土壤pH與電導度值 ...................................53 二、有效性氮、磷、鉀 ...................................56 三、有機碳 .............................................56 四、交換性鹽基 .........................................62 五、綜合討論 ...........................................62 第五章、結論 ...........................................67 參考文獻 .............................................. 68 表目錄表一、優勢樹種重要值 ....................................8 表二、福山25公頃永久樣區選擇六個土壤剖面之性質 .........12 表三、表土0-5公分地形因子與土壤性質的相關分析 ..........20 表四、表土5-15公分地形因子與土壤性質的相關分析 .........21 表五、表土15-30公分地形因子與土壤性質的相關分析 ........22 表六、福山永久樣區80個網格不同深度土壤性質之差異 .......23 表七、福山25公頃永久樣區不同地形區域土壤之pH (H2O) .....25 表八、福山25公頃永久樣區不同地形區域土壤之pH (KCl) .....26 表九、福山25公頃永久樣區不同地形區域土壤之電導度 (dS m-1)...27 表十、福山25公頃永久樣區不同地形區域土壤之有效氮含量 (mg kg-1) ......28 表十一、福山25公頃永久樣區不同地形區域土壤之有效磷含量 (mg kg-1) ....34 表十二、福山25公頃永久樣區不同地形區域土壤之有效鉀含量 (mg kg-1) ....35 表十三、福山25公頃永久樣區不同地形區域土壤之有機碳含量 (mg kg-1) ....36 表十四、福山25公頃永久樣區不同地形區域土壤之交換性鈣含量 (cmol(+)/kg) 41 表十五、福山25公頃永久樣區不同地形區域土壤之交換性鎂含量 (cmol(+)/kg) 42 表十六、福山25公頃永久樣區不同地形區域土壤之交換性鉀含量 (cmol(+)/kg) 43 表十七、福山25公頃永久樣區不同地形區域土壤之交換性鈉含量 (cmol(+)/kg) 48 表十八、表土0-5 cm土壤化學性質的相關分析 ...............50 表十九、表土5-15 cm土壤化學性質的相關分析 ..............51 表二十、表土15-30 cm土壤化學性質的相關分析 .............52 表二十一、福山25公頃永久樣區不同植被類型土壤之pH (H2O) ..54 表二十二、福山25公頃永久樣區不同植被類型土壤之pH (KCl) ..55 表二十三、福山25公頃永久樣區不同植被類型土壤之電導度 (dS m-1) ......57 表二十四、福山25公頃永久樣區不同植被類型土壤之有效氮含量 (mg kg-1) ..58 表二十五、福山25公頃永久樣區不同植被類型土壤之有效磷含量 (mg kg-1) ..59 表二十六、福山25公頃永久樣區不同植被類型土壤之有效鉀含量 (mg kg-1) ..60 表二十七、福山25公頃永久樣區不同植被類型土壤之有機碳含量 (g kg-1) ....61 表二十八、福山25公頃永久樣區不同植被類型土壤之交換性鈣含量 (cmol(+)/kg) ..............................................63 表二十九、福山25公頃永久樣區不同植被類型土壤之交換性鎂含量 (cmol(+)/kg) ..............................................64 表三十、福山25公頃永久樣區不同植被形式土壤之交換性鉀含量 (cmol(+)/kg) ..............................................65 表三十一、福山25公頃永久樣區不同植被形式土壤之交換性鈉含量 (cmol(+)/kg) ..............................................66 圖目錄圖一、福山永久樣區地理位置 ..............................4 圖二、福山25公頃永久樣區三度空間地形圖 ..................5 圖三、福山永久樣區1993-2000年氣象資料 ...................6 圖四、福山永久樣區生育地類型分布圖 ......................7 圖五、福山永久樣區土壤剖面採樣位置圖 ...................10 圖六、福山25公頃永久樣區土壤採樣網格分布 ...............14 圖七、福山25公頃永久樣區各地形分區分布(SF：平坦區，S：山頂區， SL：斜坡區，NW：西北山谷區，C：溪流區) .................17 圖八、福山永久樣區土壤pH (H2O)在0-5 cm (a), 5-15 cm (b),與15-30 cm (c) 深度之分布推估 ........................................ 29 圖九、福山永久樣區土壤pH (KCl)在0-5 cm (a), 5-15 cm (b),與15-30 cm (c) 深度之分布推估 ........................................ 30 圖十、福山永久樣區土壤電導度(dS m-1)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 ............................ 31 圖十一、福山永久樣區有效氮(mg kg-1)在0-5 cm (a), 5-15 cm (b),與15-30 cm (c) 深度之分布推估 ........................................ 32 圖十二、福山永久樣區有效磷(mg kg-1)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 ............................ 37 圖十三、福山永久樣區有效鉀(mg kg-1)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 ............................ 38 圖十四、福山永久樣區有機碳(g kg-1)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 ............................ 39 圖十五、福山永久樣區交換性鈣(cmol(+)/kg)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 .............................44 圖十六、福山永久樣區交換性鎂(cmol(+)/kg)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 .............................45 圖十七、福山永久樣區交換性鉀(cmol(+)/kg)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 .............................46 圖十八、福山永久樣區交換性鈉(cmol(+)/kg)在0-5 cm (a), 5-15 cm (b),與 15-30 cm (c)深度之分布推估 .............................49 附表目錄附表一、土壤深度0-5 cm之基本性質 .......................73 附表二、土壤深度5-15 cm之基本性質 ......................75 附表三、土壤深度15-30 cm之基本性質 .....................77 附表四、各樣方的地形資料 ...............................79
dc.language.iso	zh-TW
dc.title	福山天然闊葉林25公頃永久樣區土壤性質之空間變異	zh_TW
dc.title	Spatial variation of soil properties in the Fushan 25 ha Permanent Research Site of Fushan Natural Broadleaf Forest	en
dc.type	Thesis
dc.date.schoolyear	94-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	謝長富(Chang-Fu Hsieh),蔡呈奇(Chen-Chi Tsai)
dc.subject.keyword	福山天然闊葉林,永久樣區,地形位置,植群分佈,土壤性質,空間變異,	zh_TW
dc.subject.keyword	Fushan Natural Broadleaf Forest,permanent site,landscape,vegetation type,soil properties,spatial variation,	en
dc.relation.page	90
dc.rights.note	有償授權
dc.date.accepted	2006-07-14
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	農業化學研究所	zh_TW
顯示於系所單位：	農業化學系

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