Simple-efficient cultivation for rapeseed under UAV-sowing: Developing a high-density and high-light-efficiency population via tillage methods and seeding rates

IF 5.6 1区农林科学 Q1 AGRONOMY

Field Crops Research Pub Date : 2025-04-06 DOI:10.1016/j.fcr.2025.109887

Xiaoqiang Tan , Mingqiang Bai , Zongkai Wang , Chunmei Xiang , Yugui Cheng , Yufeng Yin , Jing Wang , Zhenghua Xu , Jie Zhao , Bo Wang , Jie Kuai , Guangsheng Zhou

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引用次数: 0

Abstract

Context

UAV-sowing (Unmanned Aerial Vehicle-sowing) technology is an effective approach to promote yield and economic benefits in the rice-rapeseed rotation system. However, in the pursuit of maximizing annual benefits, soil tillage methods, seeding rates, planting densities, and photosynthetic efficiencies need to be optimally integrated to establish a more efficient system.

Objective

Field experiments were conducted at multiple sites over several years to explore the yield performance, economic benefits, and the mechanisms underlying high productivity under different tillage patterns and seeding rates.

Methods

A two-year field experiment with a split-plot experimental design was carried out at three representative sites in the Yangtze River Basin (YRB) of China: WuHan, YiChang, and XiangYang. Three planting modes, namely CK (tillage with manual sowing, general mode), N (no-tillage with UAV-sowing, potential mode), and T (tillage with UAV-sowing) were set as the main treatments, and three seeding rates S1 (3.75 kg h m⁻²), S2 (5.25 kg h m⁻²), and S3 (6.75 kg h m⁻²) served as the sub-treatments in WuHan, while only N-S3 and CK-S3 were established in Yichang and Xiangyang. The seedling rate, population density, dry matter accumulation dynamics, photosynthetic and physiological indexes, yield, and economic benefits of rapeseed under different cropping patterns were measured and compared.

Results

From all sites and years, we found that: (1) The highest yield was achieved at the seeding rate of S3 in all modes. As the seeding rate increased from S1 to S3, the yield gap between the N mode and CK as well as T gradually decreased. Moreover, the yield of N-S3 could surpass that of CK-S2 by 5.2–7.5 %, reaching a high-yield level. (2) The benefit-cost ratio (BCR) was notably higher in the N mode than in CK by 19.5 % and in T by 11.6 %. (3) The highest seedling number was observed in T-S3, but the highest seedling rate was observed in T-S1. Compared with T-S1, the seedling number in T-S2 and T-S3 increased by 7.2 % and 13.3 %, respectively. Meanwhile, the seedling rate decreased by 14.3 % and 29.5 %, respectively, while the harvest density increased by 46.4 % and 143.1 %, respectively. (4) Through the comparison of various indexes measured in different modes, it was revealed that reasonably dense planting is capable of balancing the conflict between individuals and population and maximizing the greater group productivity. (5) The economic benefits analysis and correlation network analysis indicated that the yield and planting benefits within the high-yield and high-efficiency system showed a significant positive correlation with population density as well as radiation use efficiency (RUE).

Conclusions and significance

Mode N combined with a large seeding rate (S3) effectively reduced planting costs, enhanced seeding quality, and boosted the population's RUE. It also balanced yield and profitability, achieving the highest BCR. These findings emphasize the potential of the no-tillage with UAV-sowing technology as a simple-efficient production technology. Furthermore, the associated technological parameters and mechanisms present extensive prospects for green agriculture.

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无人机播种下油菜籽的简易高效栽培：通过耕作方式和播种量培育高密度高光效群体

无人机播种技术是水稻-油菜轮作系统中提高产量和经济效益的有效途径。然而，为了追求年效益最大化，需要将土壤耕作方式、播种率、种植密度和光合效率进行优化整合，以建立一个更高效的系统。目的通过多年的田间试验，探讨不同耕作方式和播量下玉米的产量表现、经济效益及高产机制。方法采用分块试验设计，在长江流域3个代表性地点武汉、宜昌和襄阳进行为期2年的田间试验。三种种植模式,即CK(耕作与人工播种,通用模式),N(免耕与UAV-sowing潜在模式),和T(耕作UAV-sowing)为主要治疗方法,和三个播种率S1 h m(3.75 公斤−2),S2(5.25 公斤 h m−2),和S3(6.75 公斤 h m−2)担任武汉sub-treatments,只有N-S3和CK-S3建立在宜昌和襄阳。对不同种植模式下油菜籽的出苗率、种群密度、干物质积累动态、光合生理指标、产量和经济效益进行了测定和比较。结果从各立地和年份分析发现：(1)在所有模式下，S3播量均达到最高产量。随着播种量从S1增加到S3， N模式与CK、T模式的产量差距逐渐减小。N-S3的产率比CK-S2高出5.2 ~ 7.5 %，达到高产水平。(2)氮处理的效益成本比（BCR）显著高于对照19.5 %和T 11.6 %。(3) T-S3的出苗率最高，T-S1的出苗率最高。与T-S1相比，T-S2和T-S3处理的幼苗数量分别增加了7.2 %和13.3 %。同时，出苗率分别下降14.3% %和29.5% %，收获密度分别增加46.4% %和143.1 %。(4)通过对不同模式下测量的各项指标的比较，发现合理密植能够平衡个体与种群之间的冲突，最大限度地提高群体生产力。(5)经济效益分析和相关网络分析表明，高产高效体系内的产量和种植效益与人口密度和辐射利用效率（RUE）呈显著正相关。结论及意义N模式配合大播率（S3）有效降低了种植成本，提高了播质，提高了种群的RUE。它还平衡了产量和盈利能力，实现了最高的BCR。这些发现强调了无人机免耕技术作为一种简单高效的生产技术的潜力。此外，相关的技术参数和机制为绿色农业提供了广阔的前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Field Crops Research 农林科学-农艺学

CiteScore

9.60

自引率

12.10%

发文量

307

审稿时长

46 days

期刊介绍： Field Crops Research is an international journal publishing scientific articles on: √ experimental and modelling research at field, farm and landscape levels on temperate and tropical crops and cropping systems, with a focus on crop ecology and physiology, agronomy, and plant genetics and breeding.