Effects of Paddy-Upland Rotation Systems on Nutrient Balance and Distribution in Soil Profile

답전윤환(畓田輪換) 체계(體系)에 따른 토양(土壤)의 층위별(層位別) 양분분포(養分分布) 및 양분수지(養分收支)

  • Published : 1994.06.30

Abstract

Effects of paddy-upland rotation system on nutrients distribution in soil profile and nutrient balance were studied in paddy fields from 1989 to 1993. The obtained results are summarized as follows. 1. $NO_3{^-}-N$, Av.$P_2O_5$, Ex.-K, and EC were high by small extent in surface layer of 0~20cm soil depth without the sign of salt movement to deeper layers. On the contrary Ex.-ca, Ex.-Mg, and pH became high with increase of soil depths. 2. $NO_3{^-}-N$, Av.$P_2O_5$, Ex.-K, and EC in surface soil were high in the order of Converted, Paddy-Upland Rotation, Potato-Chinese Cabbage>2 Year, Rotation, Potato-Chinese Cabbage>Converted, Paddy-Upland Rotation, Soybean>Continous Paddy, which responded well to fertilizer application rates. On the other hand Ex.-Ca, Ex.-Mg, and pH in whole layers were high in the order of Converted, Paddy-Upland Rotation, Soybean>Converted, Paddy-Upland Rptation, Potato-Chinese Cabbage>2 Year, Rotation, Potato-Chinese Cabbage>Continuous Paddy, which largely depended on plant absorption. 3. Nutrient balance in upland cropping system cultivating potato and Chinese cabbage showed that the input of chemical fertilizer of nitrogen and potassium was less than the plant uptake, while it was reverse for phosphorus with much gap between fertilizer input and plant uptake. Therefore, phosporous was expected to be accumulated by 27kg/10a every year. 4. Nutrient balance in upland cropping system cultivating soybean showed that nitrogen was not deficient to soybean crops even the chemical fertilizer input was less than plant uptake because of nitrogen fixation by rhizobia. However, there was about 1kg/10a deficit of potassium, which resulted dificiency symptom in the middle stage of soybean growth. For phosphorous there was excess of 4kg/10a, which was expected to be short for maintaining phosphorous fertility of upland soils.

1989~'93년(年)까지 5년(年)동안 답전수환시(畓田輸換時) 작부체계(作付體系)에 따른 토양(土壤) 층위별(層位別) 양분분포(養分分布)와 양분수지(養分收支)를 검토(檢討)한 결과(結果)는 아래와 같았다. 1. 질산태질소(窒酸態室素), 치환성가리(置換性加里) 및 유효인산(有效燐酸) 함량(含量)과 EC는 표층(表層) 0~20cm에서 약간 높았을뿐 토층하부(土層下部)로 이동집적(移動集積)이 적었고, 작부체계(作付體系)에 따른 표토중(表土中) 함량은 전이환(田轉換) 감자-배추>2년 수환(輸換) 감자-배추>전전환(田轉換) 대두(大豆)>수도연작구(水稻連作區) 순(順)으로 높아 처리별(處理別) 시비량을 반영(反影)하였다. 2. 치환성(置換性) 석회(石灰)와 고토(苦土) 함량 및 pH는 심토(深土)로 갈수록 높아졌고, 이러한 경향은 특히, 수도연작구(水稻連作區)에서 현저(顯著)하였다. 작부체계(作付體系)에 따라서는 전(全) 토층(土層)에서 전전환(田轉換) 대두(大豆)>전전환(田轉換) 감자배추>2년(年) 윤환(輪換) 감자-배추>수도연작구(水稻連作區) 순(順)이었고 처리별 식물체 흡수량(吸收量) 차이가 크게 영향하였다. 3. 전전환(田轉換) 감자-배추구(區)에서 질소(窒素), 인산(燐酸), 가리(加里)의 양분수지(養分收支)는 투입량(投入量)보다 탈취량(奪取量)(흡수량)이 각각(各各) 21.5, 26.8, 9.2kg/10a 많았으나 투입량(投入量)중 화학비료량(化學肥料量)은 질소(室素)와 가리(加里)의 경우 탈취량(奪取量)에 비해 적었던 반면 인산(燐酸)은 많았다. 4. 전전환(田轉換) 대두구(大豆區)의 양분수지(養分收支)는 질소(窒素), 인산(燐酸), 가리(加里) 각각(各各) -12.8, 4.1, -1.0kg/10a로 질소(窒素)와 가리(加里)의 투입량(投入量)이 탈취량(奪取量)보다 적었으나 질소(窒素)는 근류균(根瘤菌)의 질소고정(窒素固定)으로 결핍되지 않았던 반면 가리(加里)는 생육중기(生育中期)에 결핍증상(缺乏症狀)을 나타내었다.

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