Potassium efficiency of 10 potato cultivars as related to their capability to use nonexchangeable soil potassium by chemical mobilization

被引:13
作者
Trehan, SP [1 ]
El Dessougi, H [1 ]
Claassen, N [1 ]
机构
[1] Univ Gottingen, Inst Agr Chem, D-3400 Gottingen, Germany
关键词
chemical mobilization; exchangeable K; K influx; nonexchangeable K; root dry matter accumulation ratio; Solanum tuberosum L;
D O I
10.1081/CSS-200062457
中图分类号
S3 [农学(农艺学)];
学科分类号
0901 ;
摘要
Ten potato cultivars were grown in low potassium soil with and without potassium (K) in a pot experiment to test their K efficiency. Two harvests (29 and 83 days after planting) were taken to obtain final dry matter (shoot + tubers) accumulation (DMA) rates of shoot and root growth and K uptake rate per unit root (K influx). Under K deficiency, DMA of different cultivars varied by a factor of more than 2. Based on absolute DMA without K, the cultivars, Linda, Oktan, Ponto, and Maas were more K efficient than Quarta and Belana. Results show that with the same root length, more K efficient cv. Oktan had higher relative shoot growth rate and produced more DMA than less K efficient cv. Quarta in the absence of K by taking up more K per plant from soil and maintaining higher shoot K concentration. The more K efficient cv. Oktan could take up more K per plant due to its higher K influx, and its higher influx was because of its capacity to use higher nonexchangeable soil K. The DMA, K uptake, and K influx in 10 cultivars were more correlated to the quantity of nonexchangeable K depleted (r = 0.850, 0.98 1, and 0.608) than to that of exchangeable K (r = 0.284, 0.363, and 0.315, respectively). Stepwise regression analysis indicated that capacity to use nonexchangeable K is the main factor controlling K efficiency of different cultivars followed by root length to DMA ratio and K influx.
引用
收藏
页码:1809 / 1822
页数:14
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