Impacts of biochar and phosphorus application on soil phosphorus availability and soybean phosphorus uptake

doi:10.13287/j.1001-9332.202207.018

Abstract

Abstract: Biochar is beneficial to soil phosphorus (P) availability and crop growth, but the effects vary greatly across different soil types. We investigated the effects of rice straw biochar (4% of total mass) and P application (0, 30, and 90 kg P·hm^-2) on soil P availability, phosphomonoesterase activity, and soybean P uptake by using lateritic red soil (pH 4.91) and cinnamon soil (pH 7.24) as test materials. The results showed that biochar application at different P levels significantly increased available P and total P in both soils. Biochar application with 30 kg P·hm^-2 increased soil available P with maxima at 192.6% and 237.1% in lateritic red soil and cinnamon soil, respectively. Biochar application with 30 kg P·hm^-2 in lateritic red soil significantly increased the activity of alkaline phosphomonoesterase by 78.9%, decreased the content of active organic P by 39.3%, and subsequently stimulated soybean P absorption and growth. Biochar amendment significantly reduced active organic P content in cinnamon soil, but did not affect soil phosphomonoesterase activity and plant growth. The content of active organic P was significantly negatively correlated with soil available P content. In summary, the effect of biochar on soil P availability varied across different soil types (lateritic red soil > cinnamon soil) and P levels (better at 30 kg P·hm^-2). Our results could provide scientific basis for a promising application of biochar in reducing the amount of P fertilizer and increasing soybean P uptake, especially in lateritic red soil.

Key words: soybean, biochar, phosphorus fraction, phosphomonoesterase, phosphorus uptake

KUANG Xi-zhi, DENG Wei-ming, TANG Le-le, HUANG Qi, CAI Kun-zheng, TIAN Ji-hui. Impacts of biochar and phosphorus application on soil phosphorus availability and soybean phosphorus uptake[J]. Chinese Journal of Applied Ecology, 2022, 33(7): 1911-1918.

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