Ghaley Bhim B, Wösten Henk, Olesen Jørgen E, Schelde Kirsten, Baby Sanmohan, Karki Yubaraj K, Børgesen Christen D, Smith Pete, Yeluripati Jagadeesh, Ferrise Roberto, Bindi Marco, Kuikman Peter, Lesschen Jan-Peter, Porter John R
Department of Plant and Environmental Sciences, University of Copenhagen, Taastrup, Denmark.
Wageningen Environmental Research, Wageningen University and Research, Wageningen, Netherlands.
Front Plant Sci. 2018 Aug 8;9:1158. doi: 10.3389/fpls.2018.01158. eCollection 2018.
Soil organic carbon (SOC) has a vital role to enhance agricultural productivity and for mitigation of climate change. To quantify SOC effects on productivity, process models serve as a robust tool to keep track of multiple plant and soil factors and their interactions affecting SOC dynamics. We used soil-plant-atmospheric model viz. DAISY, to assess effects of SOC on nitrogen (N) supply and plant available water (PAW) under varying N fertilizer rates in winter wheat () in Denmark. The study objective was assessment of SOC effects on winter wheat grain and aboveground biomass accumulation at three SOC levels (low: 0.7% SOC; reference: 1.3% SOC; and high: 2% SOC) with five nitrogen rates (0-200 kg N ha) and PAW at low, reference, and high SOC levels. The three SOC levels had significant effects on grain yields and aboveground biomass accumulation at only 0-100 kg N ha and the SOC effects decreased with increasing N rates until no effects at 150-200 kg N ha. PAW had significant positive correlation with SOC content, with high SOC retaining higher PAW compared to low and reference SOC. The mean PAW and SOC correlation was given by PAW% = 1.0073 × SOC% + 15.641. For the 0.7-2% SOC range, the PAW increase was small with no significant effects on grain yields and aboveground biomass accumulation. The higher winter wheat grain and aboveground biomass was attributed to higher N supply in N deficient wheat production system. Our study suggested that building SOC enhances agronomic productivity at only 0-100 kg N ha. Maintenance of SOC stock will require regular replenishment of SOC, to compensate for the mineralization process degrading SOC over time. Hence, management can maximize realization of SOC benefits by building up SOC and maintaining N rates in the range 0-100 kg N ha, to reduce the off-farm N losses depending on the environmental zones, land use and the production system.
土壤有机碳(SOC)在提高农业生产力和缓解气候变化方面发挥着至关重要的作用。为了量化SOC对生产力的影响,过程模型是一种强大的工具,可用于跟踪影响SOC动态的多种植物和土壤因素及其相互作用。我们使用了土壤-植物-大气模型,即DAISY,来评估在丹麦冬小麦不同氮肥施用量下SOC对氮(N)供应和植物有效水分(PAW)的影响。研究目的是评估在三个SOC水平(低:0.7% SOC;参考:1.3% SOC;高:2% SOC)、五种氮素施用量(0 - 200 kg N/ha)下SOC对冬小麦籽粒和地上生物量积累的影响,以及在低、参考和高SOC水平下的PAW情况。这三个SOC水平仅在0 - 100 kg N/ha时对籽粒产量和地上生物量积累有显著影响,且随着氮素施用量的增加,SOC的影响逐渐减小,直至在150 - 200 kg N/ha时无影响。PAW与SOC含量呈显著正相关,与低SOC和参考SOC相比,高SOC保留的PAW更高。PAW与SOC的平均相关性由PAW% = 1.0073 × SOC% + 15.641给出。在0.7 - 2% SOC范围内,PAW的增加幅度较小,对籽粒产量和地上生物量积累无显著影响。冬小麦较高的籽粒和地上生物量归因于缺氮小麦生产系统中较高的氮供应。我们的研究表明,仅在0 - 100 kg N/ha时,增加SOC可提高农艺生产力。维持SOC储量需要定期补充SOC,以补偿随着时间推移使SOC降解的矿化过程。因此,通过增加SOC并将氮素施用量维持在0 - 100 kg N/ha范围内,管理措施可最大限度地实现SOC的效益,以根据环境区域、土地利用和生产系统减少农田外的氮损失。
