Intensified cropping reduces soil erosion and improves rainfall partitioning and soil properties in the marginal land of the Indian Himalayas

IF 7.3 1区农林科学 Q1 ENVIRONMENTAL SCIENCES

International Soil and Water Conservation Research Pub Date : 2023-10-29 DOI:10.1016/j.iswcr.2023.10.002

Devideen Yadav , Deepak Singh , Subhash Babu , Madhu Madegowda , Dharamvir Singh , Debashis Mandal , Avinash Chandra Rathore , Vinod Kumar Sharma , Vibha Singhal , Anita Kumawat , Dinesh Kumar Yadav , Rajendra Kumar Yadav , Surender Kumar

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Abstract

Environmental crises, land degradation, declining factor productivity, and farm profitability questioned the sustainability of linear economy-based existing agricultural production model. Hence, there is a dire need to design and develop circular economy-based production systems to meet the twin objectives of environmental sustainability and food security. Therefore, the productive capacity, natural resource conserving ability, and biomass recycling potential of four intensified maize-based systems viz. maize (Zea mays) + sweet potato (Ipomoea batatas)-wheat, maize + colocasia (Colocasia esculenta)-wheat, maize + turmeric (Curcuma longa), and maize + ginger (Zingiber officinale) were tested consecutively for three years (2020, 2021 and 22) in a fixed plot manner at Dehradun region of the Indian Himalaya against the existing maize-wheat systems. The result showed that the maize + sweet potato-wheat system significantly reduced runoff loss (166.3 mm) over the maize-wheat system. The highest through fall (68.12 %) and the lowest stem flow (23.54 %) were recorded with sole maize. On the contrary, the maize + sweet potato system has the highest stem flow (36.15 %) and the lowest through fall. Similarly, the maize + sweet potato system had 5.6 times lesser soil erosion and 0.77 t ha⁻¹ higher maize productivity over the maize-wheat system. Furthermore, the maize + sweet potato system recorded significantly higher soil moisture (19.3%), infiltration rate (0.95 cm h⁻¹), and organic carbon (0.78%) over the rest of the systems. The maize + sweet potato system also recycled the highest nitrogen (299.2 kg ha⁻¹), phosphorus, (31.0 kg ha⁻¹), and potassium (276.2 kg ha⁻¹) into the soil system. Hence, it can be inferred that concurrent cultivation of sweet potato, with maize, is a soil-supportive, resource-conserving, and productive production model and can be recommended for achieving the circular economy targets in the Indian Himalayas.

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在印度喜马拉雅山的贫瘠土地上，强化种植减少了土壤侵蚀，改善了降雨分区和土壤特性

环境危机、土地退化、要素生产率下降和农场盈利能力对以线性经济为基础的现有农业生产模式的可持续性提出了质疑。因此，迫切需要设计和开发以循环经济为基础的生产系统，以实现环境可持续性和粮食安全的双重目标。因此，研究了四种以玉米为基础的强化生产系统的生产能力、自然资源保护能力和生物质循环利用潜力，这四种系统分别是因此，在印度喜马拉雅山脉的德拉敦地区，以固定小区的方式连续三年（2020 年、2021 年和 22 年）测试了四种以玉米为基础的强化系统，即玉米（Zea mays）+甘薯（Ipomoea batatas）-小麦、玉米+芋头（Colocasia esculenta）-小麦、玉米+姜黄（Curcuma longa）和玉米+生姜（Zingiber officinale），与现有的玉米-小麦系统进行对比。结果表明，玉米+甘薯-小麦系统比玉米-小麦系统大大减少了径流损失（166.3 毫米）。单种玉米的径流量最高（68.12%），茎流量最低（23.54%）。相反，玉米+甘薯系统的茎流最高（36.15 %），直落率最低。同样，与玉米-小麦系统相比，玉米+红薯系统的土壤侵蚀减少了 5.6 倍，玉米生产率提高了 0.77 吨/公顷。此外，玉米+红薯系统的土壤湿度（19.3%）、渗透率（0.95 厘米/小时-1）和有机碳（0.78%）均明显高于其他系统。玉米+甘薯系统对土壤氮（299.2 千克/公顷-1）、磷（31.0 千克/公顷-1）和钾（276.2 千克/公顷-1）的循环利用率也最高。因此，可以推断，红薯与玉米同时种植是一种支持土壤、节约资源和高产的生产模式，可推荐用于实现印度喜马拉雅地区的循环经济目标。

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来源期刊

International Soil and Water Conservation Research Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

12.00

自引率

3.10%

发文量

171

审稿时长

49 days

期刊介绍： The International Soil and Water Conservation Research (ISWCR), the official journal of World Association of Soil and Water Conservation (WASWAC) http://www.waswac.org, is a multidisciplinary journal of soil and water conservation research, practice, policy, and perspectives. It aims to disseminate new knowledge and promote the practice of soil and water conservation. The scope of International Soil and Water Conservation Research includes research, strategies, and technologies for prediction, prevention, and protection of soil and water resources. It deals with identification, characterization, and modeling; dynamic monitoring and evaluation; assessment and management of conservation practice and creation and implementation of quality standards. Examples of appropriate topical areas include (but are not limited to): • Conservation models, tools, and technologies • Conservation agricultural • Soil health resources, indicators, assessment, and management • Land degradation • Sustainable development • Soil erosion and its control • Soil erosion processes • Water resources assessment and management • Watershed management • Soil erosion models • Literature review on topics related soil and water conservation research

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