溪頭柳杉及紅檜老齡人工林之林木生長量、枯落物量與生態系統碳儲存量

Hung-Ru Lee; 李泓儒

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/8129

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	鄭智馨(Chih-Hsin Cheng)
dc.contributor.author	Hung-Ru Lee	en
dc.contributor.author	李泓儒	zh_TW
dc.date.accessioned	2021-05-20T00:49:07Z	-
dc.date.available	2020-08-25
dc.date.available	2021-05-20T00:49:07Z	-
dc.date.copyright	2020-08-25
dc.date.issued	2020
dc.date.submitted	2020-08-20
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/8129	-
dc.description.abstract	柳杉是台灣造林歷史中，中海拔地區重要的造林樹種之一，根據林務局第四次森林資源調查統計報告，全台灣柳杉林的材積蓄積量已佔全人工林總材積蓄積量的18.4 %，但隨著林業政策變遷，如今的柳杉林已少有伐採和林分更新。因此，本研究選擇溪頭地區6個林齡介於46～97年生之老齡柳杉造林林分及1個林齡88年生的老齡紅檜造林林分，藉由老齡人工林樣區之試驗調查，用以了解現有老齡林分之林分現況和於2017至2019年間之林分生長變化。研究目的主要為 (1)調查溪頭這些不同林齡的老齡柳杉造林地林分之林分特性及生長動態 (2)了解老齡柳杉與紅檜人工林之連年生長量、枯落物量與生態系統碳儲存量。研究結果顯示，各柳杉林2017年度的生長量為0.91～2.65 Mg C ha-1 yr-1，2018年為0.81～2.14 Mg C ha-1 yr-1，2019年為0.88～1.92 Mg C ha-1 yr-1；紅檜林則分別為0.62、1.42、1.53 Mg C ha-1 yr-1。由於枯落物收集進行期間，溪頭地區皆無受到颱風影響，因此所得之柳杉林枯落物量較過去研究來得低，各柳杉林枯落物量2017年為2,191～2,810 kg ha-1 yr-1，2018年為2,134～3,234 kg ha-1 yr-1，2019年為3,507～4,812 kg ha-1 yr-1；紅檜林則分別為6,814、5,248、5,307 kg ha-1 yr-1。各林分之生態系統碳儲存量 (229～343 Mg C ha-1) 皆以生立木為最大宗，佔生態系統碳儲存量70%以上，柳杉林分林木碳量為203～255 Mg C ha-1、紅檜林分為144 Mg C ha-1；表層0～30 cm土壤有機碳量含量次之，土壤有機碳儲存量為53～78 Mg C ha-1，約佔生態系統碳儲存量25%。林木碳量與土壤有機碳量兩者合計佔生態系統碳儲存量95%以上。連年生長量之結果顯示溪頭老齡柳杉仍然在持續生長吸存二氧化碳，即使是林齡97年生的老齡柳杉林分，其生長量也並非停滯，甚至高過一些林齡較為年輕的老齡林分。雖然各林分樹高已接近樹高生長上限，但胸高直徑仍持續增加，使得林分蓄積量隨著胸高直徑的成長增加，這些老齡林分仍可繼續累積碳儲存量。老齡森林也代表了一個巨大的碳庫，將來這些林分如不進行伐採或遭受擾動損毀，仍然可持續吸存大氣中的二氧化碳固定於林木之中，對於減少碳排放有其貢獻存在。	zh_TW
dc.description.abstract	Cryptomeria japonica (Japanese cedar) is an important plantation species in Taiwan. According to the Fourth Forest Resources Survey Report of the Forestry Bureau, the volume stocks of Japanese cedar plantations accounted for 18.4% of the total plantations’ stocks. However, with the change in policies, there is less harvesting and forest regeneration in the Japanese cedar plantations nowadays. In this study, six old Japanese cedar stands with stand age from 46 to 97 years old and one stand of Taiwan red cypress for 88 years old were selected, to investigate their stand characteristics and annual stand growth in 2017 to 2019. The objects of this study are to (1) investigate current stand characteristics and growth dynamics of these old-growth Japanese cedar stands of different ages in Xitou, and (2) understand the annual growth, litterfall mass, ecosystem carbon stocks, and distribution of carbon stocks in these old-growth Japanese cedar and Taiwan red cypress stands. The study results show that the growths of the Japanese cedar stands are 0.91-2.65 Mg C ha-1 yr-1 in 2017, 0.81-2.14 Mg C ha-1 yr-1 in 2018, 0.88-1.92 Mg C ha-1 yr-1 in 2019, and the growth of the Taiwan red cypress is 0.62, 1.42, 1.53 Mg C ha-1 yr-1 in 2017 to 2019, respectively. Because none of the areas in Xitou were affected by typhoons during the experiment, the mass of litterfall in the Japanese cedar stands are lower than in the previous studies. The mass of litterfall in the Japanese cedar stands are 2,191-2,810 kg ha-1 yr-1 in 2017, 2,134-3,234 kg ha-1 yr-1 in 2018, 3,507-4,812 kg ha-1 yr-1 in 2019, and the Taiwan red cypress is 6,814, 5,248, 5,307 kg ha-1 yr-1 in 2017 to 2019, respectively. In each stand, live standing trees has the largest amount of carbon stocks in the ecosystem (229-343 Mg C ha-1), accounting for more than 70 % of the total carbon stocks. 203-255 Mg C ha-1 in Japanese cedar stands and 144 Mg C ha-1 in Taiwan red cypress stand. The amounts of soil organic carbon range between 53 and 78 Mg C ha-1 and rank the second pools for the ecosystem carbon stocks, accounting for 25% of the total carbon stocks. These two C stocks account for more than 95% of the total ecosystem carbon stocks. The annual growth results show that the old-growth Japanese cedar stands in Xitou are still growing. The growth of 97 years old Japanese cedar stand is not stagnant, even higher than some younger stands. Although the tree height of each stand is close to its upper limit, these stands will continue to accumulate carbon stocks as their DBH grows in the future. The old-growth forest also represents a huge carbon stock. If they are not harvested or disturbed, they will continue to absorb and fix atmospheric carbon dioxide to reduce carbon emissions.	en
dc.description.provenance	Made available in DSpace on 2021-05-20T00:49:07Z (GMT). No. of bitstreams: 1 U0001-1808202017480200.pdf: 4960882 bytes, checksum: 238133960e52783e41d5070201b086bb (MD5) Previous issue date: 2020	en
dc.description.tableofcontents	中文摘要 .......... i ABSTRACT .......... iii 目錄 .......... v 圖目錄.......... viii 表目錄 .......... x 一.前言..........1 二.文獻回顧..........4 (一)林木生長量..........4 (二)林分枯落物量..........5 (三)生態系統碳儲存量..........7 三.調查地點、材料與方法..........11 (一)調查地點介紹..........11 (二)調查樣區概況及介紹..........12 (三)調查材料及方法..........14 1.樣區設立、調查項目及時間..........16 2.林分現況調查..........16 2.1林分密度 (Stand density)..........16 2.2胸高直徑 (Diameter at Breast Height, DBH)..........16 2.3樹高、枝下高及後生枝下高 (Tree height, Live clear length and Epicormic branch clear length)..........16 2.4樣區林木座標與樹冠幅半徑之測定 (Tree coordinate and Tree crown width)..........18 2.5葉面積指數 (Leaf Area Index, LAI)..........18 3.林木生長量及枯落物量調查 (Tree growth and Litterfall production)..........19 3.1樹徑生長鐵環 (Dendrometer) 架設及測量..........20 3.2枯落物網 (Litter trap) 架設及採集..........22 4.生態系統碳儲存量計算 (Ecosystem carbon stock)..........23 4.1林分材積量 (Stand volume) 計算..........23 4.2林木碳儲存量 (CT) 計算..........25 4.3地被植物 (Understory and ground vegetation) 採樣及碳儲存量 (CU) 計算..........26 4.4枯立木 (Snags, CD) 調查及測計..........27 4.5枯倒木及木質殘體 (Dead down-timbers and woody debris)之調查、採樣與碳儲存量(CWD) 計算..........27 4.6地表枯枝落葉層 (Forest floor) 採樣及碳儲存量 (CF) 計算..........29 4.7森林土壤採樣、性質測定及碳儲存量 (CS) 計算..........30 (1)土壤總體容積密度 (Bulk density)..........30 (2)土壤採樣、含石率及碳含量測定..........30 (3)土壤有機碳量計算..........31 四.結果..........33 (一)各調查造林地之林分狀態..........33 1.各調查林分之林分概況及各項基本資料..........33 2.調查林分之樹冠特性..........36 3.調查林地之林分葉面積指數..........41 (二)各林分的林木生長量及枯落物量..........41 1.林木單株生長量及林分生長量..........42 2.各林分之年度枯落物量及時間變化..........48 (三)生態系統碳儲存量及各部分碳庫之碳儲存量..........51 1.林木碳儲存量(CT)..........53 2.地被植物碳儲存量(CU)..........53 3.枯立木碳儲存量(CD)..........53 4.枯倒木及木質殘骸、碎片碳儲存量(CWD)..........53 5.地表枯枝落葉層碳儲存量(CF)..........54 6.土壤有機碳儲存量(CS)..........54 五.討論..........55 (一)各項林分狀態隨時間之變化..........55 1.林分狀態隨時間變化之特性與Mistcherlich生長模式比較..........55 2.林分之樹高結構..........58 3.林分之枝下高、樹冠長和樹冠幅..........60 4.林分之後生枝..........62 (二)老齡人工林的生長量及其枯落物量..........64 1.林木生長量..........64 2.枯落物量..........67 (三)老齡人工林的生態系統碳儲存量及其各部分碳儲存量..........71 1.林木碳儲存量 (CT)..........71 2.枯立倒木及木質殘骸、地被植物及地表枯枝落葉層碳儲存量 (CD、CWD、CU ＆ CF)..........74 3.土壤有機碳儲存量 (CS)..........77 4.生態系統碳儲存量及其分佈..........80 六.結論..........81 七.參考文獻..........82 附錄..........89
dc.language.iso	zh-TW
dc.title	溪頭柳杉及紅檜老齡人工林之林木生長量、枯落物量與生態系統碳儲存量	zh_TW
dc.title	Tree Growth, Litterfall Mass and Ecosystem Carbon Stocks of Old Japanese Cedar and Taiwan Red Cypress Plantations in Xitou	en
dc.type	Thesis
dc.date.schoolyear	108-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳秋萍(Chiou-Pin Chen),中井太郎(Taro Nakai)
dc.subject.keyword	柳杉,紅檜,老齡人工林,林分生長量,枯落物量,生態系統碳儲存量,	zh_TW
dc.subject.keyword	Japanese cedar,Taiwan red cypress,old-growth plantations,forest growth,litterfall mass,ecosystem carbon stocks,	en
dc.relation.page	92
dc.identifier.doi	10.6342/NTU202004012
dc.rights.note	同意授權(全球公開)
dc.date.accepted	2020-08-20
dc.contributor.author-college	生物資源暨農學院	zh_TW
dc.contributor.author-dept	森林環境暨資源學研究所	zh_TW
顯示於系所單位：	森林環境暨資源學系

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