河南省小麦规模化种植的生产现状及经济效益分析

doi:10.3864/j.issn.0578-1752.2025.22.004

Abstract

Abstract:

【Objective】The smallholder farming model has proven inadequate in meeting the demands of modern agricultural development, with large-scale planting emerging as a crucial pathway for agricultural modernization that facilitates sustainable agriculture development. This study aimed to investigate the current situation of wheat fertilization, irrigation, pest control, yield and economic benefits under different planting scales in Henan Province. Furthermore, it elucidated the impact of scale farming on wheat production, thereby providing a theoretical foundation and practical references for achieving sustainable wheat production. 【Method】A field investigation was conducted in Henan Province to examine the current situation of wheat production and its economic benefits from October 2023 to June 2024. By integrating yield with fertilizer use efficiency, this study systematically analyzed the variations in field management, wheat yield, fertilizer efficiency, and economic performance across different cultivation scales. 【Result】There were significant differences in wheat production among farmers with different cultivation scales. The majority of wheat cultivation areas in Henan Province fell within the range of 6.67-20.00 hm², with the Zhengmai wheat series being the predominant cultivar. The most common seeding rate was 225 kg·hm^-2. The application rates of nitrogen and phosphorus as basal fertilizers were lower in farms with 6.67-20.00 hm² compared with other planting scales. Phosphorus and potassium applied during topdressing were also lower than that of other planting scales ≤33.33 hm². Most surveyed farmers irrigated their fields three times, with the highest irrigation frequency observed in farms ranging from 20.00-33.33 hm². Pesticide use primarily involved insecticides and fungicides, with the highest application frequencies for both observed in the 6.67-20.00 hm² scale. Yields and partial factor productivity of fertilizers were significantly higher in farms sized 6.67-20.00 hm² and 20.00-33.33 hm² than in other scales. Wheat yields in these two groups were significantly increased by 3.57%-20.80%, and by 6.03%-23.67%, respectively, compared with other planting scales. Similarly, partial factor productivity improved by 15.87%-43.02%, and by 10.26%-36.10%, respectively. The output-input ratio was significantly higher in fields ≤6.67 hm² compared with other scales, while the highest net returns were observed at farm sizes ≤33.33 hm². 【Conclusion】Substantial variations in wheat management practices were observed across different farm scales in Henan Province. Comprehensive evaluation of yield, fertilizer partial factor productivity, net returns, and output-input ratio identified 6.67-33.33 hm² as the optimal cultivation scale. Substantial efficiency gaps were observed among large-scale wheat growers, indicating considerable potential for optimization through improved management practices. The adoption of more efficient management measures could significantly enhance the operational efficiency of different planting scales.

Key words: wheat, planting scales, yield, partial fertilizer productivity, net benefits

LIU Huan, WANG GaoFeng, HUANG YuFang, ZHAO YaNan, YANG Xue, YE YouLiang. Analysis of the Production Status and Economic Benefits of Large- Scale Wheat Cultivation in Henan Province[J].Scientia Agricultura Sinica, 2025, 58(22): 4603-4616.

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References 53

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