Effect of Plasticulture and Planting Method on Morpho-Physiological Characteristics and Weeds of Pea (Pisum sativum L.)

Document Type : Original Article

Authors

Department of Plant Production and Genetics Engineering, Faculty of Agricultural Science and Engineering, Razi University, Kermanshah, Iran

10.22067/ijpr.2024.89320.1095

Abstract

Introduction
In contemporary agriculture, the monoculture system of cereal crops is prevalent. Legumes are the most important plant family for crop rotation and sustainable agriculture due to their nitrogen fixing capabilities. Rainfed agricultural ecosystems are the largest food-producing biomes globally, with water scarcity and fluctuating rainfall being the most significant limiting factors for crop production. The growing demand for freshwater resources will increase the agricultural sector's vulnerability under future climate conditions, restricting production. Kermanshah province, where 78.4% of the land is arid, faces unique weather conditions and is particularly affected by drought stress. In rainfed farming systems, a suitable solution to conserve water at the farm scale is to create a suitable planting bed. The most common method of seed bed preparation among farmers is the normal flat planting method. The flat planting method, which is easy to prepare, is associated with a series of basic problems, such as reducing the efficiency of water use, reducing the efficiency of nitrogen fertilizer use, reducing plant establishment, and the soil capping. Preparing the planting bed by changing the physical conditions of the seed bed, i.e. the thermal, humidity, ventilation and resistance characteristics of the soil, can affect the seedling emergence and the growth of the plant. By creating a ridge and furrow bed and nylon mulch, the soil moisture can be saved for different stages of plant growth.
 
Materials and Methods
The current research was carried out in the research Farm, Campus of Agriculture and Natural Resources, Razi University during the cropping years of 2019 and 2020 as a factorial design based on randomized complete blocks with three replications. The treatments included nylon mulch (without nylon, nylon on the plant and nylon on the soil) and the method of planting in the bed (flat planting, planting in a 50 cm furrow, planting in a 100 cm furrow). The dimensions of each of the experimental plots were 2 m x 2m. In each plot, there were four rows of cultivation at a distance of half a meter, and the distance between the plants on each row was 10 cm. The distance between the experimental plots was one and a half meters. The traits studied included nitrogen use efficiency, leaf specific weight, leaf area index, stem dry weight, leaf dry weight, number of leaves per plant, plant height, dry weight of broadleaf weed, dry weight of narrow leaf weed, crude protein of green seed, and leaf greenness index. After Bartlett's test, the results showed that the dry weight of broad-leaved weeds, the dry weight of narrow-leaved weeds, seed protein and leaf greenness can be analyzed as a combined analysis of variance over two years, and the rest of the traits can be analyzed separately in each year. The data were analyzed using SAS software version 9.1 and the mean of the treatments were compared with the LSD method at a probability level of 5%.
 
Results and Discussion
According to the results of analysis of variance per year, plant height, number of leaves per plant, leaf area index, specific leaf weight and nitrogen consumption efficiency (first year) and specific weight leaf (second year) were affected by the double interaction of nylon and planting bed. The combined analysis of variance showed that broadleaf weed dry weight and leaf greenness were affected by the triple interaction effect of year, nylon and planting bed. According to the mean comparison results (first year), the highest and lowest leaf area index values were obtained in the treatment of nylon on the plant with planting in a 50 cm furrow (3.82) and treatment without nylon with planting in a 50 cm furrow (3.26), respectively. The highest and lowest efficiency of nitrogen use were related to the treatment of nylon on soil with planting in a 50 cm furrow (152 kg.kg-1) and treatment of without nylon and flat planting (81 kg.kg-1), respectively. According to the comparison of the mean of the combined analysis of variance, the highest dry weight of broadleaf weeds was obtained in the treatment of the first year, nylon on the plant and flat planting (489 kg.ha-1), and the lowest in the treatment of the first year, nylon on soil and planting in a 100 cm furrow (71 kg.ha-1).
 
Conclusions
In this study, the plastic cover on the soil had the highest nitrogen use efficiency and the lowest weed growth due to weed suppresion. These two factors are acceptable reasons for increasing the growth under treatment of plastic cover on the soil. In line with the report of various studies, the treatment of planting in the 50 cm furrow floor reduced the drought stress and increased the growth of the plant by affecting the available water, and this drought stress reduction was more evident in the second year due to the low amount of rainfall.

Keywords

Main Subjects

©2024 The author(s). This is an open access article distributed under Creative Commons Attribution 4.0 International License (CC BY 4.0).

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History

  • Receive Date: 10 August 2024
  • Revise Date: 09 October 2024
  • Accept Date: 10 October 2024
  • First Publish Date: 03 November 2024

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