旨在探明水稻在膜下滴灌下根系形态、构型、氮利用效率变化及其与分形维数的关系。于2021—2022年,以氮高效品种(T-43)和氮低效品种(垦-26)为材料,设置滴灌(drip irrigation,DI)、淹灌(flooding irrigation,FI)2种方式与4种施氮水平(0、...旨在探明水稻在膜下滴灌下根系形态、构型、氮利用效率变化及其与分形维数的关系。于2021—2022年,以氮高效品种(T-43)和氮低效品种(垦-26)为材料,设置滴灌(drip irrigation,DI)、淹灌(flooding irrigation,FI)2种方式与4种施氮水平(0、150、300和450 kg hm^(–2))的盆栽试验。基于盒维数法结合根系图像分形分析程序计算根系形态的分形维数和分形丰度,研究滴灌及施氮对水稻产量、氮素利用效率、根系形态、构型、分形维数、分形丰度的影响。结果表明,(1)在相同施氮水平下,与淹灌相比,滴灌处理下T-43和垦-26细根百分比、根长密度(root length density,RLD)β值、氮肥农学利用效率(nitrogen agronomic efficiency,NAE)显著提高(分别为6.8%~14.5%和9.9%~17.2%、0.65%~5.45%和0.32%~3.43%、12.1%~22.4%和12.2%~20.5%);>0.5 mm RLD、0~40 cm土层表面积密度(surface area density,SAD)和根体积密度(RLD)、分形维数(fractal dimension,FD)、分形丰度(fractal abundance,FA)显著降低,造成产量降低(3.8%~37.4%和7.6%~48.3%)。(2)滴灌模式下,施氮显著提高了水稻根系FD和FA,T-43在施氮量为300 kg hm^(–2)时,FD和FA最高(分别为1.55和14.07);垦-26在施氮量为450 kg hm^(–2)时最高(分别为1.62和14.78)。(3)相关分析表明,FD、FA与直径0.1~0.3 mm RLD、0~10 cm土层根长和根质量密度、产量、氮素稻谷生产效率呈显著正相关,与30~40 cm土层表面积密度呈显著负相关。因此,在滴灌条件下,氮高效品种“T-43”配施300 kg hm^(–2)氮肥,能够增加细根根长密度比例,优化表层根系形态分布,提高根系分形维数和丰度,进而实现滴灌水稻产量和氮肥利用效率协同提高。展开更多
Nine districts covering the main greenhouse vegetable areas in Tianjin Municipality of the North China Plain were selected for the soil investigation in 2010 to survey the current soil nutrient status (soil available ...Nine districts covering the main greenhouse vegetable areas in Tianjin Municipality of the North China Plain were selected for the soil investigation in 2010 to survey the current soil nutrient status (soil available N, P and K), acidification and salinization due to excessive input of fertilizers in greenhouses in Tianjin. The study showed that, in particular, soil available P content increased with the age of greenhouses. In contrast, our results did not reveal higher K accumulation and lowered pH in the greenhouse soils compared with cultivation in open fields. Over-fertilization, causing high NO 3 accumulation, most likely resulted in salinity problems in the greenhouses. Ninety percent of the investigated greenhouse soils had electrical conductivity values of saturated paste extracts of 2-10 d S m-1 , which might affect the yields of vegetable crops like green bean, pepper, cabbage, carrot, eggplant, lettuce, spinach, celery, cucumber and tomato. The findings of our survey of the current fertility and salinity problems in greenhouse soils suggest that there is an urgent need to improve the farmers' practices and strategies in fertilization management in greenhouses of China. Because education and the agricultural technical extension services may play a more important role in avoiding overuse of fertilizers, we suggest that current nutrient management practices should be improved in the near future through training of local farmers in farmers' schools and through strengthening the agricultural extension services with practical techniques.展开更多
文摘旨在探明水稻在膜下滴灌下根系形态、构型、氮利用效率变化及其与分形维数的关系。于2021—2022年,以氮高效品种(T-43)和氮低效品种(垦-26)为材料,设置滴灌(drip irrigation,DI)、淹灌(flooding irrigation,FI)2种方式与4种施氮水平(0、150、300和450 kg hm^(–2))的盆栽试验。基于盒维数法结合根系图像分形分析程序计算根系形态的分形维数和分形丰度,研究滴灌及施氮对水稻产量、氮素利用效率、根系形态、构型、分形维数、分形丰度的影响。结果表明,(1)在相同施氮水平下,与淹灌相比,滴灌处理下T-43和垦-26细根百分比、根长密度(root length density,RLD)β值、氮肥农学利用效率(nitrogen agronomic efficiency,NAE)显著提高(分别为6.8%~14.5%和9.9%~17.2%、0.65%~5.45%和0.32%~3.43%、12.1%~22.4%和12.2%~20.5%);>0.5 mm RLD、0~40 cm土层表面积密度(surface area density,SAD)和根体积密度(RLD)、分形维数(fractal dimension,FD)、分形丰度(fractal abundance,FA)显著降低,造成产量降低(3.8%~37.4%和7.6%~48.3%)。(2)滴灌模式下,施氮显著提高了水稻根系FD和FA,T-43在施氮量为300 kg hm^(–2)时,FD和FA最高(分别为1.55和14.07);垦-26在施氮量为450 kg hm^(–2)时最高(分别为1.62和14.78)。(3)相关分析表明,FD、FA与直径0.1~0.3 mm RLD、0~10 cm土层根长和根质量密度、产量、氮素稻谷生产效率呈显著正相关,与30~40 cm土层表面积密度呈显著负相关。因此,在滴灌条件下,氮高效品种“T-43”配施300 kg hm^(–2)氮肥,能够增加细根根长密度比例,优化表层根系形态分布,提高根系分形维数和丰度,进而实现滴灌水稻产量和氮肥利用效率协同提高。
基金Supported by the German Federal Ministry of Education and Research (BMBF) (No. 00330800A)
文摘Nine districts covering the main greenhouse vegetable areas in Tianjin Municipality of the North China Plain were selected for the soil investigation in 2010 to survey the current soil nutrient status (soil available N, P and K), acidification and salinization due to excessive input of fertilizers in greenhouses in Tianjin. The study showed that, in particular, soil available P content increased with the age of greenhouses. In contrast, our results did not reveal higher K accumulation and lowered pH in the greenhouse soils compared with cultivation in open fields. Over-fertilization, causing high NO 3 accumulation, most likely resulted in salinity problems in the greenhouses. Ninety percent of the investigated greenhouse soils had electrical conductivity values of saturated paste extracts of 2-10 d S m-1 , which might affect the yields of vegetable crops like green bean, pepper, cabbage, carrot, eggplant, lettuce, spinach, celery, cucumber and tomato. The findings of our survey of the current fertility and salinity problems in greenhouse soils suggest that there is an urgent need to improve the farmers' practices and strategies in fertilization management in greenhouses of China. Because education and the agricultural technical extension services may play a more important role in avoiding overuse of fertilizers, we suggest that current nutrient management practices should be improved in the near future through training of local farmers in farmers' schools and through strengthening the agricultural extension services with practical techniques.