Optimizing groundnut sowing for minimizing dry spell risks over Rayalaseema, a rainfed region of India

IF 2 3区农林科学 Q2 AGRONOMY

Agronomy Journal Pub Date : 2025-02-08 DOI:10.1002/agj2.70020

K. Ashok Kumar, S. N. Malleswari, K. V. S. Sudheer, Santanu Kumar Bal, N. Manikandan, A. V. M. Subba Rao, M. A. Sarath Chandran

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引用次数: 0

Abstract

Groundnut productivity in rainfed regions of arid and semi-arid agro-ecosystems in southern India is highly vulnerable to intra-seasonal rainfall variability as well as the timing, duration, frequency, and intensity of dry spells. The Rayalaseema semi-arid region of India, a major groundnut (Arachis hypogaea L.)-growing region, has experienced increasing intra-seasonal rainfall variability, especially over the last few decades. To understand the impacts of dry spells on the growth and development of groundnut, field experiments on groundnut (cultivar K6) were conducted at the Agricultural Research Station, Ananthapuramu, Andhra Pradesh, during 2015–2020. The results indicated that the amount and distribution of rainfall during different phenophases were the most influential parameters on dry matter production, phenology, and pod yield in groundnut and can have either a positive or negative effect depending on whether the rainfall matches the crop's water requirements during specific growth stages. It was found that, in July second fortnight (II-FN) sown crop, the rainfall received was synchronized with pod initiation to maturity stage, resulting in higher dry matter production (456 g m⁻²) and pod yield (1123 kg ha⁻¹). On the other hand, pod initiation-pod maturity stage with August I-FN sown crop received less rainfall, leading to a soil moisture deficit and lower pod yields (815 kg ha⁻¹). The duration of pod initiation-pod maturity stage with August I-FN sown crop was significantly less (47 days) compared to July II-FN (54 days) and July I-FN (50 days) sown crops, resulting in reduced pod filling period that drastically affected pod yield. It can be concluded that the existing sowing time for groundnuts needs to be advanced from August I-FN to July II-FN. This will not only avoid terminal moisture stress during pod initiation-pod maturity stage but also help in enhancing groundnut productivity in rainfed areas of Rayalaseema region.

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优化花生播种，以最大限度地减少印度多雨地区Rayalaseema的干旱风险

在印度南部干旱和半干旱农业生态系统的雨牧区，花生产量极易受到季节内降雨量变化以及干旱期的时间、持续时间、频率和强度的影响。印度的Rayalaseema半干旱区是一个主要的花生（arachhis hypogaea L.）种植区，特别是在过去的几十年里，经历了越来越多的季节性降雨变异。为了解干旱期对花生生长发育的影响，2015-2020年在安得拉邦Ananthapuramu农业研究站对花生（栽培品种K6）进行了田间试验。结果表明，不同物候期的降雨量和分布是影响花生干物质生产、物候和荚果产量的最重要参数，其影响可能是正影响，也可能是负影响，取决于降雨是否与作物特定生长阶段的需水量相匹配。结果表明，在7月第二周播种作物（II-FN），降雨量与荚果形成至成熟期同步，干物质产量（456 g m−2）和荚果产量（1123 kg ha−1）较高。另一方面，8月I-FN播种作物的豆荚萌发-豆荚成熟期降雨量较少，导致土壤水分亏缺，豆荚产量较低（815 kg ha - 1）。与7月I-FN （54 d）和7月I-FN （50 d）相比，8月I-FN播种作物的荚果形成-荚果成熟期显著缩短（47 d），导致结荚期缩短，严重影响了荚果产量。综上所述，花生现有播期需由8月1日提前至7月2日。这不仅可以避免荚果萌发-荚果成熟阶段的末端水分胁迫，而且有助于提高拉雅拉西玛地区旱作区花生的产量。

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来源期刊

Agronomy Journal 农林科学-农艺学

CiteScore

4.70

自引率

9.50%

发文量

265

审稿时长

4.8 months

期刊介绍： After critical review and approval by the editorial board, AJ publishes articles reporting research findings in soil–plant relationships; crop science; soil science; biometry; crop, soil, pasture, and range management; crop, forage, and pasture production and utilization; turfgrass; agroclimatology; agronomic models; integrated pest management; integrated agricultural systems; and various aspects of entomology, weed science, animal science, plant pathology, and agricultural economics as applied to production agriculture. Notes are published about apparatus, observations, and experimental techniques. Observations usually are limited to studies and reports of unrepeatable phenomena or other unique circumstances. Review and interpretation papers are also published, subject to standard review. Contributions to the Forum section deal with current agronomic issues and questions in brief, thought-provoking form. Such papers are reviewed by the editor in consultation with the editorial board.