不同施肥管理對經八年水旱田輪作系統的玉米與水稻產量及養分吸收的影響

Mei-Hua Huang; 黃美華

請用此 Handle URI 來引用此文件： http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35865

完整後設資料紀錄

DC 欄位	值	語言
dc.contributor.advisor	鍾仁賜
dc.contributor.author	Mei-Hua Huang	en
dc.contributor.author	黃美華	zh_TW
dc.date.accessioned	2021-06-13T07:47:40Z	-
dc.date.available	2005-07-30
dc.date.copyright	2005-07-30
dc.date.issued	2005
dc.date.submitted	2005-07-26
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dc.identifier.uri	http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/35865	-
dc.description.abstract	本研究目的在於探討經八年長期玉米－水稻輪作系統下之土壤，施用不同量與不同種類氮肥對不同生長時期玉米與水稻生長及養分吸收，和土壤中養分有效性的影響。試驗共有七種處理，分別為，1. 對照區 (CK)，2. 化學氮肥區 (Chem-N)，3. 堆肥區 (Comp)，4. 堆肥額外添加化學氮肥區之化學氮肥量之三分之一(Comp + 1/3 N)，5. 堆肥額外添加化學氮肥區之化學氮肥量之三分之二 (Comp + 2/3 N)，6. 綠肥額外添加化學氮肥區之化學氮肥量之三分之一(GM + 1/3 N)，7. 泥炭額外添加化學氮肥區之化學氮肥量之三分之一 (Peat + 1/3 N)。除對照組外，其餘處理皆施相同量的磷肥與鉀肥。每處理四重複，採逢機完全區集排列。分別採玉米膝高期、雄穗抽出期、成熟期及水稻分蘗盛期、幼穗形成期、開花期、成熟期的植株，分析植體中總氮、硝酸態氮、銨態氮、不溶性氮、磷、鉀、鈣、鎂、鐵、錳、銅、鋅含量，和土壤基本理化性質。　　結果顯示，玉米成熟期乾物質產量以Comp + 2/3 N處理者最高，水稻則以Chem-N處理者之乾物質產量最高。玉米及水稻的氮吸收量皆以Chem-N與Comp + 2/3 N處理者顯著高於其他處理者。與Chem-N處理比較，種植玉米添加有機資材的施肥處理，在成熟期皆增加作物對磷的吸收量，其中以Comp + 1/3 N處理者最高，可能是因添加堆肥使得土壤中的有效磷含量增加。在成熟期水稻磷的吸收量則是以Chem-N處理者最多，除了對照組外，其餘各處理間差異不顯著。在施加堆肥的不同化學氮肥處理下，隨化學氮肥增加，玉米的鉀吸收量也增加，而水稻則在生長後期之效應較顯著。一般而言，不同處理對於玉米及水稻不同生長時期之鈣、鎂、鐵、錳、銅與鋅吸收量的影響，在統計上並不顯著。關鍵字：玉米、水稻、輪作系統。	zh_TW
dc.description.abstract	The purpose of this study was to study the effects of nitrogen (N) fertilization management on the growth and nutrient uptake of rice and corn plants under corn-rice rotation system for eight years. There were seven treatments, which included: 1. check (CK); 2. chemical nitrogen fertilizer treated-plot (Chem-N); 3. compost treated-plot (Comp); 4. compost combined with additional one-third amount of N fertilizer as Chem-N treatment (Comp + 1/3 N); 5. compost combined with additional two-thirds amount of N fertilizer as Chem-N treatment (Comp + 2/3 N); 6. green manure combined with additional one-third amount of N fertilizer as Chem-N treatment (GM + 1/3 N); 7. peat combined with additional one-third amount of N fertilizer as Chem-N treatment (Comp + 1/3 N). The application rates of chemical fertilizer treated plot for corn and rice plants, were 140-80-80 kg ha-1 and 120-60-60 kg ha-1 for N, P2O5, and K2O, respectively. The same amount of superphosphate and potassium chloride as Chem-N plot were applied in all organic fertilizer treated plots. The treatments were replicated four time and arranged in randomized complete block design. Corn plants were sampled at knee high, tasseling, and maturity stage and rice plants were harvested at the most active tillering, primordial initiation, heading, and ripening stages, respectively. The concentrations of total N, ammonium N, nitrate N (for corn plants), insoluble N, phosphorus (P), potassium (K), calcium (Ca), magnesium (Mg), iron (Fe), manganese (Mn), copper (Cu), and zinc (Zn) in the various parts of the plants were determined. Some selected soil chemical properties before and after the harvest of the plants were also determined. The results showed that the dry matter yield of corn plants at maturity stage of the Comp + 2/3 N treatment was the highest among the all treatments. However, the dry matter yield of rice plants of Chem-N treatment was the highest at maturity stage. The amount of N absorption of Chem-N and Comp + 2/3 N treatments for both corn and rice plants were higher than that of the other treatments. Owing to the higher rate of P was applied in organic fertilizer treated plots, the absorption of P of these plots was higher in corn plants at maturity stage as compared with the Chem-N treatment and the highest amount of P uptake occurred in Comp + 1/3 N treatment. The Chem-N treated rice plant had the highest amount of P uptake at maturity stage. There was no significant difference in P uptake among the fertilized rice plants. The K uptake of corn plant increased with the rate of N applied in the compost treated plots. This also occurred in rice plant significantly at the maturity stage. In general, the effect of treatments on the uptake of Ca, Mg, Fe, Mn, Cu, and Zn was not statistically significant for both corn and rice plant at different growth stages. Key words: corn, rice, rotation system.	en
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dc.description.tableofcontents	目錄頁次摘要 ------------------------------------------------------------------------- I Abstract --------------------------------------------------------------------- III 目錄 ------------------------------------------------------------------------- V 表目錄 ---------------------------------------------------------------------- VII 圖目錄 ---------------------------------------------------------------------- X 前言 ------------------------------------------------------------------------- 1 前人研究-------------------------------------------------------------------- 3 材料與方法 ---------------------------------------------------------------- 7 結果與討論 ---------------------------------------------------------------- 21 一、不同施肥處理對土壤性質的影響--------------------------------- 21 （一）對土壤酸鹼度之影響--------------------------------------------- 21 （二）對土壤電導度之影響--------------------------------------------- 24 （三）對土壤有機質含量之影響--------------------------------------- 24 （四）對土壤總氮之影響------------------------------------------------ 25 （五）對土壤Bray-1磷含量之影響----------------------------------- 25 （六）對土壤Mehlich III 可萃取性鉀之影響----------------------- 26 （七）對土壤Mehlich III 可萃取性鈣與鎂之影響----------------- 26 （八）對土壤Mehlich III 可萃取性鐵與錳之影響----------------- 27 （九）對土壤Mehlich III 可萃取性銅與鋅之影響----------------- 27 二、玉米與水稻生長、養分吸收與分佈------------------------------ 28 （一）不同肥料處理對玉米與水稻乾物質產量的影響------------ 28 （二）不同肥料處理對氮的吸收與分佈之影響--------------------- 37 1. 不同生長期下作物之氮吸收量與濃度------------------------- 37 2. 不同生長期下作物之無機態氮的濃度------------------------- 48 3. 不同生長期下作物之不溶性氮的濃度------------------------- 55 4. 不同生長期下作物之可溶性有機態氮的濃度---------------- 59 （三）不同肥料處理對磷的吸收與分佈之影響--------------------- 63 （四）不同肥料處理對鉀的吸收與分佈之影響--------------------- 74 （五）不同肥料處理對鈣、鎂的吸收與分佈之影響--------------- 84 （六）不同肥料處理對鐵、錳的吸收與分佈之影響--------------- 97 （七）不同肥料處理對銅、鋅的吸收與分佈之影響--------------- 104 結論-------------------------------------------------------------------------- 111 參考文獻-------------------------------------------------------------------- 113 附錄-------------------------------------------------------------------------- 119 表目錄頁次表一、玉米栽培前試驗田土壤之理化性質------------------------------ 8 表二、玉米栽培期間之田間管理------------------------------------------ 9 表三、水稻栽培期間之田間管理------------------------------------------ 10 表四、玉米試驗所用之有機資材的組成分------------------------------ 11 表五、水稻試驗所用之有機資材的組成分------------------------------ 12 表六、水稻栽培前試驗田土壤之理化性質------------------------------ 22 表七、水稻成熟期試驗田土壤之理化性質------------------------------ 23 表八、不同肥料處理對玉米植體各部位乾物質產量的影響　　　（克�株）------------------------------------------------------------ 29 表九、不同肥料處理對水稻植體各部位乾物質產量的影響　　　（克�叢) ------------------------------------------------------------ 33 表十、不同肥料處理對玉米植體氮吸收及在各部位分佈的影響　　　（毫克�株）--------------------------------------------------------- 38 表十一、不同肥料處理對玉米植體各部位總氮濃度的影響　　　（克�千克)----------------------------------------------------------- 40 表十二、不同肥料處理對水稻植體氮吸收及在各部位分佈的影響　　　（毫克�叢)----------------------------------------------------------- 43 表十三、不同肥料處理對水稻植體各部位總氮濃度的影響　　　（克�千克)----------------------------------------------------------- 45 表十四、不同肥料處理對玉米植體各部位硝酸態氮濃度的影響　　　（毫克�千克)-------------------------------------------------------- 49 表十五、不同肥料處理對玉米植體各部位銨態氮濃度的影響　　　（毫克�千克)-------------------------------------------------------- 51 表十六、不同肥料處理對水稻植體各部位銨態氮濃度的影響　　　（毫克�千克）------------------------------------------------------ 53 表十七、不同肥料處理對玉米植體各部位不溶性氮濃度的影響　　　（克�千克）--------------------------------------------------------- 56 表十八、不同肥料處理對水稻植體各部位不溶性氮濃度的影響　　　（克�千克）--------------------------------------------------------- 58 表十九、不同肥料處理對玉米植體各部位可溶性有機態氮濃度　　　　的影響（克�千克）--------------------------------------------- 60 表二十、不同肥料處理對水稻植體各部位可溶性有機態氮　　　　的影響（克�千克）--------------------------------------------- 62 表二十一、不同肥料處理對玉米植體磷吸收及在各部位分佈　　　　　的影響（克�株）------------------------------------------------ 64 表二十二、不同肥料處理對玉米植體各部位磷濃度的影響　　　　（克�千克）------------------------------------------------------ 66 表二十三、不同肥料處理對水稻植體磷吸收及在各部位分佈　　　　　的影響（毫克�叢）------------------------------------------ 70 表二十四、不同肥料處理對水稻植體各部位磷濃度的影響　　　　（克�千克）------------------------------------------------------ 72 表二十五、不同肥料處理對玉米植體鉀吸收及在各部位分佈　　　　　的影響（毫克�株）------------------------------------------ 75 表二十六、不同肥料處理對玉米植體各部位鉀濃度的影響　　　　（克�千克）------------------------------------------------------ 77 表二十七、不同肥料處理對水稻植體鉀吸收及在各部位分佈　　　　　的影響（毫克�叢）------------------------------------------ 80 表二十八、不同肥料處理對水稻植體各部位鉀濃度的影響　　　　（克�千克）------------------------------------------------------ 82 表二十九、不同肥料處理對玉米植體鈣吸收及在各部位分佈　　　　　的影響（毫克�株）------------------------------------------ 85 表三十、不同肥料處理對玉米植體各部位鈣濃度的影響　　　（克�千克）--------------------------------------------------------- 86 表三十一、不同肥料處理對水稻植體鈣吸收及在各部位分佈　　　　　的影響（毫克�叢）-------------------------------------------- 88 表三十二、不同肥料處理對水稻植體各部位鈣濃度的影響　　　　（克�千克）------------------------------------------------------ 89 表三十三、不同肥料處理對玉米植體鎂吸收及在各部位分佈　　　　　的影響（毫克�株）-------------------------------------------- 92 表三十四、不同肥料處理對玉米植體各部位鎂濃度的影響　　　　（克�千克）------------------------------------------------------ 93 表三十五、不同肥料處理對水稻植體鎂吸收及在各部位分佈　　　　　的影響（毫克�叢）-------------------------------------------- 95 表三十六、不同肥料處理對水稻植體各部位鎂濃度的影響　　　　（克�千克）------------------------------------------------------ 96 表三十七、不同肥料處理對玉米植體各部位鐵濃度的影響　　　　（毫克�千克）--------------------------------------------------- 98 表三十八、不同肥料處理對水稻植體各部位鐵濃度的影響　　　　（毫克�千克）--------------------------------------------------- 99 表三十九、不同肥料處理對玉米植體各部位錳濃度的影響　　　　（毫克�千克）--------------------------------------------------- 102 表四十、不同肥料處理對水稻植體各部位錳濃度的影響　　　（毫克�千克）------------------------------------------------------ 103 表四十一、不同肥料處理對玉米植體各部位銅濃度的影響　　　　（毫克�千克）--------------------------------------------------- 105 表四十二、不同肥料處理對水稻植體各部位銅濃度的影響　　　　（毫克�千克）--------------------------------------------------- 106 表四十三、不同肥料處理對玉米植體各部位鋅濃度的影響　　　　（毫克�千克）--------------------------------------------------- 108 表四十四、不同肥料處理對水稻植體各部位鋅濃度的影響　　　　（毫克�千克）-------------------------------------------------- 109 圖目錄頁次圖一、不同肥料處理對玉米植體總乾物質產量的影響（克�株） 30 圖二、不同肥料處理對水稻植體總乾物質產量的影響（克�叢） 34 圖三、不同肥料處理對玉米氮吸收量的影響（毫克�株）------- 39 圖四、不同肥料處理對水稻氮吸收量的影響（毫克�叢）------- 44 圖五、不同肥料處理對玉米磷吸收量的影響（毫克�株）------- 65 圖六、不同肥料處理對水稻磷吸收量的影響（毫克�叢）------- 71 圖七、不同肥料處理對玉米鉀吸收量的影響（毫克�株）------- 76 圖八、不同肥料處理對水稻鉀吸收量的影響（毫克�叢）------- 81
dc.language.iso	zh-TW
dc.subject	輪作系統	zh_TW
dc.subject	玉米	zh_TW
dc.subject	水稻	zh_TW
dc.subject	rice	en
dc.subject	rotation system	en
dc.subject	corn	en
dc.title	不同施肥管理對經八年水旱田輪作系統的玉米與水稻產量及養分吸收的影響	zh_TW
dc.title	Influence of fertilizer management on the growth and nutrient uptake of corn and rice plants in soil of corn and rice rotation system for eight years	en
dc.type	Thesis
dc.date.schoolyear	93-2
dc.description.degree	碩士
dc.contributor.oralexamcommittee	陳仁炫,黃裕銘,何聖賓,陳建德
dc.subject.keyword	玉米,水稻,輪作系統,	zh_TW
dc.subject.keyword	corn,rice,rotation system,	en
dc.relation.page	126
dc.rights.note	有償授權
dc.date.accepted	2005-07-26
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
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