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氮、钾肥施用量对灌溉冬小麦(Triticum aestivum L.)生产力、经济效益和养分利用效率的影响。

Nitrogen and potassium application effects on productivity, profitability and nutrient use efficiency of irrigated wheat (Triticum aestivum L.).

机构信息

Department of Soil Science, Punjab Agricultural University, Ludhiana, India.

Yadvindra Department of Engineering, Punjabi University South Campus, Talwandi Sabo, Bathinda, Punjab, India.

出版信息

PLoS One. 2022 May 24;17(5):e0264210. doi: 10.1371/journal.pone.0264210. eCollection 2022.

DOI:10.1371/journal.pone.0264210
PMID:35609063
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9129015/
Abstract

The development of robust nutrient management strategies have played a crucial role in improving crop productivity, profitability and nutrient use efficiency. Therefore, the implementation of efficient nutrient management stratigies is important for food security and environmental safety. Amongst the essential plant nutrients, managing nitrogen (N) and potassium (K) in wheat (Triticum aestivum L.) based production systems is citically important to maximize profitable production with minimal negative environmental impacts. We investigated the effects of different fertilizer-N (viz. 0-240 kg N ha-1; N0-N240) and fertilizer-K (viz. 0-90 kg K ha-1; K0-K90) application rates on wheat productivity, nutrient (N and K) use efficiency viz. partial factor productivity (PFPN/K), agronomic efficiency (AEN/K), physiological efficiency (PEN/K), reciprocal internal use efficiency (RIUEN/K), and profitability in terms of benefit-cost (B-C) ratio, gross returns above fertilizer cost (GRAFC) and the returns on investment (ROI) on fertilizer application. These results revealed that wheat productivity, plant growth and yield attributes, nutrients uptake and use efficiency increased significantly (p<0.05)with fertilizer-N application, although the interaction effect of N x K application was statistically non-significant (p<0.05). Fertilizer-N application at 120 kg N ha-1 (N120) increased the number of effective tillers (8.7%), grain yield (17.3%), straw yield (15.1%), total N uptake (25.1%) and total K uptake (16.1%) than the N80. Fertilizer-N application significantly increased the SPAD reading by ~4.2-10.6% with fertilizer-N application (N80-N240), compared with N0. The PFPN and PFPK increased significantly with fertilizer-N and K application in wheat. The AEN varied between 12.3 and 22.2 kg kg-1 with significantly higher value of 20.8 kg kg-1 in N120. Fertilizer-N application at higher rate (N160) significantly decreased the AEN by ~16.3% over N120. The N120treatment increased the AEK by ~52.6% than N80 treatment. Similarly the RIUEN varied between 10.6 and 25.6 kg Mg-1 grain yield, and increased significantly by ~80.2% with N120 as compared to N0 treatment. The RIUEK varied between 109 and 15.1 kg Mg-1 grain yield, and was significantly higher in N120 treatment. The significant increase in mean gross returns (MGRs) by ~17.3% and mean net returns (MNRs) by ~24.1% increased the B-C ratio by ~15.1% with N120 than the N80 treatment. Fertilizer-N application in N120 treatment increased the economic efficiency of wheat by ~24.1% and GRAFC by ~16.9%. Grain yield was significantly correlated with total N uptake (r = 0.932**, p<0.01), K uptake (r = 0.851**), SPAD value (r = 0.945**), green seeker reading (r = 0.956**), and the RIUEN (r = 0.910**). The artificial neural networks (ANNs) showed highly satisfactory performance in training and simulation of testing data-set on wheat grain yield. The calculated mean absolute error (MAE), mean absolute percentage error (MAPE) and root mean square error (RMSE) for wheat were 0.0087, 0.834 and 0.052, respectively. The well trained ANNs model was capable of producing consistency for the training and testing correlation (R2 = 0.994**, p<0.01) between the predicted and actual values of wheat grain yield, which implies that ANN model succeeded in wheat grain yield prediction.

摘要

在提高作物生产力、盈利能力和养分利用效率方面,稳健的养分管理策略的发展起到了至关重要的作用。因此,实施高效的养分管理策略对于粮食安全和环境安全都很重要。在必需的植物养分中,管理小麦(Triticum aestivum L.)生产系统中的氮(N)和钾(K)对于实现利润最大化和最小化负环境影响至关重要。我们研究了不同肥料氮(即 0-240 kg N ha-1;N0-N240)和肥料钾(即 0-90 kg K ha-1;K0-K90)施用量对小麦生产力、养分(N 和 K)利用效率(即部分因子生产力(PFPN/K)、农学效率(AEN/K)、生理效率(PEN/K)、内部相对利用效率(RIUEN/K))以及肥料投入的经济效益(B-C 比、总收益高于肥料成本(GRAFC)和投资回报率(ROI))的影响。这些结果表明,小麦生产力、植物生长和产量性状、养分吸收和利用效率随着肥料氮的施用显著提高(p<0.05),尽管氮和钾的交互效应在统计学上并不显著(p<0.05)。与 N80 相比,N120 处理(施氮 120 kg N ha-1)增加了有效分蘖数(8.7%)、籽粒产量(17.3%)、秸秆产量(15.1%)、总氮吸收量(25.1%)和总钾吸收量(16.1%)。与 N0 相比,施氮(N80-N240)处理可使 SPAD 读数增加 4.2-10.6%。随着氮和钾的施用量的增加,PFPN 和 PFPK 显著增加。AEN 变化范围为 12.3-22.2 kg kg-1,N120 处理的 AEN 值为 20.8 kg kg-1,显著较高。与 N120 相比,N160 处理的 AEN 降低了约 16.3%。N120 处理的 AEK 比 N80 处理增加了约 52.6%。同样,RIUEN 变化范围为 10.6-25.6 kg Mg-1 粒产量,与 N0 处理相比,N120 处理增加了约 80.2%。RIUEK 变化范围为 109-15.1 kg Mg-1 粒产量,N120 处理的 RIUEK 显著较高。与 N80 相比,N120 处理的平均总收益(MGRs)增加了约 17.3%,平均净收益(MNRs)增加了约 24.1%,B-C 比增加了约 15.1%。N120 处理增加了小麦的经济效率约 24.1%,GRAFC 增加了约 16.9%。籽粒产量与总氮吸收量(r = 0.932**,p<0.01)、钾吸收量(r = 0.851**)、SPAD 值(r = 0.945**)、绿度读数(r = 0.956**)和 RIUEN(r = 0.910**)显著相关。人工神经网络(ANNs)在训练和测试数据集的小麦籽粒产量模拟方面表现出了非常令人满意的性能。小麦的平均绝对误差(MAE)、平均绝对百分比误差(MAPE)和均方根误差(RMSE)分别为 0.0087、0.834 和 0.052。经过良好训练的 ANN 模型能够产生训练和测试相关性(R2 = 0.994**,p<0.01)的一致性,即预测值和实际值之间的小麦籽粒产量,这意味着 ANN 模型成功地预测了小麦的籽粒产量。

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