Department of Environmental Sciences, Faculty of Biological Sciences, Quaid-I-Azam University, Islamabad, 45320, Pakistan.
Land Resources Research Institute, National Agricultural Research Center, Islamabad, 45500, Pakistan.
Environ Geochem Health. 2024 Mar 14;46(4):128. doi: 10.1007/s10653-024-01899-3.
Extreme climates and the unpredictability of the weather are significant obstacles to agricultural productivity. This study is the first attempt to explore the capacity of nanobonechar (NBC) for promoting climate-smart agriculture. A pot experiment was performed on maize (Zea mays L.) under a deficit irrigation system (40, 70, and 100% irrigation rates) using different soil application rates of the NBC (0, 0.5, 1, and 2% wt/wt). Additionally, the CO-C efflux rate and cumulative CO-C were measured in an incubation experiment. The results indicated the best performance of the 1% NBC treatment under a 70% irrigation rate in terms of the fresh and dry weights of maize plants. Total PO and Ca were significantly higher in the plants grown in the NBC-amended soil as compared to the control, showing a gradual increase with an increase in the NBC application rate. The improved productivity of maize plants under a deficit irrigation system was associated with enhanced water-holding capacity, organic matter, and bioavailability of cations (Ca, K, and Na) and anions (PO and NO) in the soils amended with NBC. The CO-C efflux rate and cumulative CO-C emissions remain higher in the NBC-amended soil than in the un-amended soil, pertaining to the high contents of soil organic matter emanating from the NBC. We conclude that NBC could potentially be used as a soil amendment for promoting maize growth under a water stress condition.
极端气候和天气的不可预测性是农业生产力的重大障碍。本研究首次尝试探索纳米骨炭 (NBC) 在促进气候智能农业方面的能力。在亏缺灌溉系统(灌溉率分别为 40%、70%和 100%)下,对玉米(Zea mays L.)进行了盆栽试验,使用了不同的 NBC 土壤施用量(0、0.5、1 和 2%wt/wt)。此外,还在一个培养实验中测量了 CO-C 排放率和累积 CO-C。结果表明,在 70%灌溉率下,1% NBC 处理的玉米植株鲜重和干重表现最佳。与对照相比,NBC 改良土壤中种植的植物的总磷和钙含量显著提高,随着 NBC 施用量的增加而逐渐增加。在亏缺灌溉系统下,玉米植株的生产力提高与 NBC 改良土壤中持水能力、有机质以及阳离子(Ca、K 和 Na)和阴离子(PO 和 NO)的生物有效性增强有关。与未改良土壤相比,NBC 改良土壤中的 CO-C 排放率和累积 CO-C 排放仍较高,这与 NBC 产生的高土壤有机质含量有关。我们得出结论,NBC 可能可被用作土壤改良剂,以促进在水分胁迫条件下玉米的生长。