بررسی کارآیی انرژی در نظام تولید نخود دیم با اعمال آبیاری تکمیلی

نوع مقاله : مقالات کوتاه

نویسندگان

گروه علمی کشاورزی، دانشگاه پیام نور، ایران

چکیده

انرژی‌­های ورودی و خروجی، اجزای مهمی از کشاورزی پایدار هستند. به بیان دیگر، تولید پایدار بدون توجه به توازن انرژی نظام­‌های تولیدی، قابل حصول نیست. بر این اساس، در این پژوهش که در سال زراعی 1400- 1399 در شهرستان خرم‌­آباد انجام شد، انرژی ورودی و خروجی دو نظام تولید نخود (Cicer arietinum) دیم (نظام تولید نخود دیم بدون آبیاری تکمیلی و نظام تولید نخود دیم با آبیاری تکمیلی در مرحله گل‌دهی) اندازه‌­گیری شد تا بر اساس آن، کارآیی انرژی نظام و اثر آبیاری تکیملی بر آن تعیین شود. بدین منظور، ابتدا با استفاده از فرمول کوکران، حجم نمونه (تعداد کشاورزان) تعیین گردید و سپس در بین کشاورزان پرسش­نامه‌­هایی توزیع شد تا اطلاعات مربوط به نظام کشت خود شامل نوع ماشین‌­آلات، سطح نهایی زمین زیر کشت، روش کاشت و برداشت، عملکرد دانه در واحد سطح، تعداد کارگرها (مرد و زن)، میزان بذر استفاده شده، مقدار کود و آفت­‌کش‌­ها را در آن قید کنند. برای مقایسه دو نظام تولید نخود دیم، علاوه‌بر اندازه­گیری انرژی­‌های ورودی و خروجی، شاخص‌­های نسبت انرژی و انرژی خالص خروجی نیز محاسبه شد. نتایج حاصل از تجزیه و تحلیل داده­های به‌دست آمده از پرسش­نامه‌­ها نشان داد که کل انرژی ورودی به نظام 14589 مگاژول در هکتار بود که 87 درصد آن (12724 مگاژول در هکتار) به مصرف سوخت دیزل اختصاص داشت. عملکرد دانه نخود دیم در شرایط کشت دیم کم (645 کیلوگرم در هکتار) بود، به همین دلیل انرژی خروجی از نظام (11997 مگاژول در هکتار) کمتر از انرژی ورودی به نظام بود که در نتیجه، نسبت انرژی و انرژی خالص خروجی به‌ترتیب کمتر از یک (82/0) و کمتر از صفر (2491- مگاژول در هکتار) به‌دست آمد. اگر چه آبیاری تکمیلی درمرحله گل‌دهی، مصرف انرژی را به‌اندازه 60 مگاژول در هکتار افزایش داد، ولی به‌دلیل افزایش 34 درصدی عملکرد دانه و انرژی خروجی نظام، کارآیی انرژی کل نظام تولید نخود دیم را بهبود بخشید، چرا که باعث افزایش نسبت انرژی و انرژی خروجی به‌ترتیب به 1/1 و 1406 مگاژول در هکتار شد. نتایج پژوهش حاضر نشان داد که آبیاری تکمیلی در مرحله گل‌دهی، علاوه‌بر افزایش عملکرد دانه، کارآیی انرژی را نیز افزایش می­‌دهد.

کلیدواژه‌ها

عنوان مقاله [English]

Evaluation of Energy Efficiency of a Common Pea Dry Land Farming System through Application of Complementary Irrigation

نویسندگان [English]

  • Hamdollah Eskandari
  • Kamyar Kazemi
Department of Agriculture, Payame Noor University, Iran
چکیده [English]

Introduction
Common pea is an annual crop of the legominosae family with the capability of biological nitrogen fixation, and as such it has an important role in increasing productivity of field soil and is commonly used in crop rotation programs. This crop has high nutritional value due to high concentrations of the essential amino acids lysine and tryptophan. Sustainability, in terms of obtaining maximum crop productivity from a system while maintaining conservation of its resources, is one of the most important components of an agricultural system. There is a close relationship between agriculture and energy, so that energy has a direct effect on the efficiency of crop production. Agricultural systems need to be evaluated in terms of input and output energy, so that based on that, the amount of energy consumed for product production per unit area can be determined. In essence, assessing the sustainability of production in agricultural systems involves considering the balance between energy input and output. Consequently, the identification and effective management of input energy become pivotal factors in enhancing the overall energy efficiency of a production system. The current research was carried out to evaluate energy consumption and production in a common pea dry land farming system to reach the best possible improvement of energy balance.
 
Materials and Methods
Evaluation of the energy balance of a common pea dry land farming system and the effect of a complementary irrigation on total energy efficiency was determined from values for energy inputs and outputs including seed, pesticide (liquid herbicide), human labor (men and women), machinery, diesel fuel and grain yield per unit area. Energy inputs were determined from questionnaires completed by farmers. Farmers were asked to provide the information on their cultivation system including technical specifications for type of machinery used, including motor capacity, total land area, planting and harvesting method, crop yield per unit area, number of workers, amount of seed, amounts of fertilizer and pesticides. Energy efficiency of the system was evaluated by calculating the energy ratio and net output energy.
 
Results and Discussion
Results showed that the highest energy input belonged to diesel fuel, followed by seed. Distances between the input of diesel fuel and other inputs were high, where 87% (12724 MJ.ha-1) of total consumed energy was allocated to diesel fuel. Grain yield of the common pea production system with and without complementary irrigation were 863 Kg.ha-1 and 645 Kg.ha-1, produced by consuming 14488 MJ.ha-1 and 14679 MJ.ha-1, respectively. In other words, complementary irrigation resulted in more input energy and grain yield. In the current research, complementary irrigation caused a considerable improvement in grain yield that resulted in higher output energy. Complementary irrigation increased input energy from 14589 MJ.ha-1 to 14679 MJ.ha-1 (60 MJ.ha-1was added) (Figure 2), but evaluations of energy ratio and net output energy revealed the positive effect of complementary irrigation on energy efficiency.
 
Conclusions
The dry land farming system for common peas exhibited low energy efficiency, primarily attributed to diminished grain production. Notably, diesel fuel consumption represented the highest energy input. While some essential production activities inevitably lead to increased input energy, it is recognized that managing inputs may not always guarantee improved energy efficiency. However, the experiment demonstrated that introducing complementary irrigation during the flowering stage of common peas resulted in an enhanced energy efficiency for the system.

کلیدواژه‌ها [English]

  • Energy ration
  • Input energy
  • Net energy
  • Output energy
  • Production sustainability

©2023 The author(s). This is an open access article distributed under Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source.

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