Vertical rotary sub‐soiling affects soil moisture characteristics and potato water utilization

Zhang, Xucheng; Ma, Yifan; Yu, Xiaonan; Hou, Haijun; Wang, Hongli; Fang, Yanjie

doi:10.1002/agj2.20454

Cited by 5 publications

(1 citation statement)

References 33 publications

(56 reference statements)

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“…This approach employs a deep vertical rotary tiller to cut the soil vertically, subsequently breaking, lifting, and loosening the soil. It can break the plough pan without changing the vertical layering of the soil, and its working depth is up to 30-50 cm [2,5]. Currently, this farming method has been applied to a number of crops in China, including cassava, sugarcane, cotton, corn, and potato [2,6].…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Spiral Cutter–Soil Interaction in Deep Vertical Rotary Tillage

Yang,

Xiao,

Pan

et al. 2023

Agriculture

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Deep vertical rotary tillage (DVRT) is a new tillage method which combines the advantages of deep tillage and rotary tillage. However, limited research has been conducted on a critical component of the deep vertical rotary tiller, namely the spiral cutter. In clay loam, there are a lot of large clods in the topsoil layer after tillage, and the cutting resistance and vibration of the cutter are substantial. To reveal the reasons behind this, a simulation model of a spiral cutter–soil system was developed using Smoothed Particle Hydrodynamics (SPH). Using this model, the working process and force of a spiral cutter were thoroughly investigated. The results show that soil fragmentation, swelling, and loosening primarily result from the combined effects of the separation cutting, velocity difference cutting, auxiliary cutting, and the spiral blade’s lifting effect on soil. The reasons for the larger clods are that topsoil furrow slices are larger and the velocity difference cutting is insufficient. The substantial resistance of the cutter is mainly due to the greater resistance of the blade and the bottom edge, and too many blades cutting the soil simultaneously. Furthermore, due to the asymmetry of the cutter’s structure, the resistance’s amplitude reaches 1963.5 N, which causes the cutter’s large vibration. These findings would be an important basis for optimal cutter design.

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Section: Introductionmentioning

confidence: 99%

Numerical Simulation of Spiral Cutter–Soil Interaction in Deep Vertical Rotary Tillage

Yang,

Xiao,

Pan

et al. 2023

Agriculture

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Effects of intercropping with Fenlong tillage “145” mode on ratoon sugarcane photosynthesis, growth, and yield

Zeng,

Li,

et al. 2024

Crop Science

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Soil compaction and resource competition are bottlenecks in the improvement of sugarcane productivity in intercropping systems. Fenlong tillage improves crop yields by alleviating soil compaction and ensuring water supply. Wide‐narrow rows are an effective solution for light competition. An efficient intercropping system with Fenlong tillage technology as the core needs to be constructed. A two‐cycle field study was conducted to investigate the effects of planting methods [sole ratoon sugarcane (S) and ratoon sugarcane‐soybean intercropping (I)] combined with tillage [conventional rotary tillage (RT), Fenlong tillage “145” mode (FL145)] on soil physical characteristics, photosynthesis, and growth of ratoon sugarcane, as well as crop yields. For the ratoon sugarcane, compared to RT‐I, FL145‐I decreased bulk density and increased porosity in the 0–40 cm soil layer. Root growth parameters were improved under FL145‐I in the 0–20 cm soil layer. FL145‐I positively affected the stomatal conductance, causing increases in the net photosynthetic and transpiration rates. The increased leaf area index, chlorophyll relative content, and photosynthesis under FL145‐I caused higher dry matter accumulation. The increased single stalk weight under FL145‐I resulted in 17.13%–22.55% higher stalk yield with similar quality. Intercropping under the wide‐narrow row planting pattern had no negative effects on the growth and stalk yield of ratoon sugarcane. For the soybean, compared to RT‐I, the increased 100‐seed weight under FL145‐I resulted in 11.14% higher seed yield with similar quality. Therefore, FL145‐I presents a promising and novel management practice for sustainably increasing ratoon sugarcane productivity in China.

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Vertical rotary sub-soiling under ridge–furrow with plastic mulching system increased crops yield by efficient use of deep soil moisture and rainfall

Yin

Zhang²,

Fan³

et al. 2022

Agricultural Water Management

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Vertical rotary sub‐soiling affects soil moisture characteristics and potato water utilization

Cited by 5 publications

References 33 publications

Numerical Simulation of Spiral Cutter–Soil Interaction in Deep Vertical Rotary Tillage

Numerical Simulation of Spiral Cutter–Soil Interaction in Deep Vertical Rotary Tillage

Effects of intercropping with Fenlong tillage “145” mode on ratoon sugarcane photosynthesis, growth, and yield

Vertical rotary sub-soiling under ridge–furrow with plastic mulching system increased crops yield by efficient use of deep soil moisture and rainfall

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