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最终单株总干物分配(%),麻骨40.2、叶片19.4、花器16.4、原麻14.0、麻壳8.1、叶柄1.8;各器官干物量对单株总干物量的直接通径系数,花器>麻壳>麻骨>叶柄>原麻>叶片。在生育后期,叶片、叶柄和花器含K率降低,麻骨中则升高,高产品种原麻含K率也升高;各器官最终含K率,麻壳>叶柄>麻骨>花器>原麻>叶片;麻壳、麻骨和原麻含K率与原麻产量呈显著正相关。K回报系数生育后期降低。高生物量、高产量、高耗K品种(如细叶青)在K肥充足条件下具有生产优势;中、低生物量和原麻产量、低耗K类型(如黄壳铜、竹子麻等)品种可作为耐低K资源利用
Total dry matter distribution of the final plant (%), Scutellaria biloba 40.2, leaf 19.4, flower 16.4, the original hemp 14.0, hemp 8.1, petiole 1.8; Direct path coefficient of total dry matter, flowers> Ma> Mau bone> petiole> the original hemp> leaves. In the late growth period, the K content of leaves, petioles and flowers decreased, while the content of K in high-yielding varieties also increased, while the K content in the high-yielding varieties also increased. Hemp> leaf; K contain rate of hemp, hemp bone and original hemp was significantly and positively correlated with the yield of raw hemp. K coefficient of return lower late childbirth. High biomass, high yield, high consumption of K varieties (such as fine leaf green) in the K adequate conditions have production advantages; middle and low biomass and crude output, low consumption K type (such as yellow shell copper, bamboo hemp, etc. ) Varieties can be used as low-K-resistant resources