The effect of organic and inorganic fertilizers on cucurbita moschata.
Table Of Contents
Chapter ONE
INTRODUCTION
- 1.1Introduction
- 1.2Background of Study
- 1.3Problem Statement
- 1.4Objective of Study
- 1.5Limitation of Study
- 1.6Scope of Study
- 1.7Significance of Study
- 1.8Structure of the Research
- 1.9Definition of Terms
Chapter TWO
LITERATURE REVIEW
- 2.1Overview of Organic Fertilizers
- 2.2Types of Organic Fertilizers
- 2.3Benefits of Organic Fertilizers
- 2.4Overview of Inorganic Fertilizers
- 2.5Types of Inorganic Fertilizers
- 2.6Benefits of Inorganic Fertilizers
- 2.7Comparison of Organic and Inorganic Fertilizers
- 2.8Studies on Fertilizer Effects on Cucurbita Moschata
- 2.9Role of Nutrients in Plant Growth
- 2.10Sustainable Agriculture Practices
Chapter THREE
RESEARCH METHODOLOGY
- 3.1Research Design
- 3.2Sampling Techniques
- 3.3Data Collection Methods
- 3.4Data Analysis Procedures
- 3.5Experimental Setup
- 3.6Variables Identification
- 3.7Research Ethics
- 3.8Quality Control Measures
Chapter FOUR
DATA PRESENTATION AND ANALYSIS
- 4.1Effects of Organic Fertilizers on Cucurbita Moschata
- 4.2Effects of Inorganic Fertilizers on Cucurbita Moschata
- 4.3Comparative Analysis of Fertilizer Effects
- 4.4Plant Growth Parameters
- 4.5Nutrient Uptake Efficiency
- 4.6Soil Health Implications
- 4.7Environmental Impact Assessment
- 4.8Recommendations for Fertilizer Use
Chapter FIVE
SUMMARY, CONCLUSION AND RECOMMENDATIONS
- 5.1Conclusion and Summary
- 5.2Key Findings Recap
- 5.3Implications for Future Research
- 5.4Practical Applications
- 5.5Recommendations for Farmers
Project Abstract
Cucurbita moschata, commonly known as butternut squash, is a highly nutritious and economically important vegetable crop. The use of fertilizers, both organic and inorganic, plays a crucial role in enhancing the growth, development, and yield of C. moschata. This study aimed to investigate and compare the effects of organic (compost) and inorganic (chemical) fertilizers on the growth parameters, fruit yield, and nutrient content of C. moschata. A randomized complete block design (RCBD) was employed with three replicates for each treatment. The treatments included control (no fertilizer), chemical fertilizer (NPK 151515), and organic compost. Parameters such as plant height, number of leaves, vine length, number of fruits per plant, fruit weight, and nutrient content (nitrogen, phosphorus, and potassium) were measured and analyzed. The results indicated that the application of both organic compost and chemical fertilizer significantly influenced the growth and yield components of C. moschata compared to the control. Plants treated with organic compost showed improved growth parameters such as increased plant height, number of leaves, and vine length compared to those treated with chemical fertilizer and the control. However, the number of fruits per plant and fruit weight were higher in plants treated with chemical fertilizer. Furthermore, the nutrient analysis revealed that organic compost application led to higher nitrogen content in the leaves, while the phosphorus and potassium content did not show significant differences between the treatments. In contrast, plants treated with chemical fertilizer had higher phosphorus and potassium content compared to the organic compost and control treatments. Overall, the results suggest that both organic and inorganic fertilizers have positive effects on the growth and yield of C. moschata. Organic compost enhances the vegetative growth of the plants, while chemical fertilizer promotes higher fruit yield. The choice of fertilizer type may depend on specific objectives, such as maximizing vegetative growth or fruit production. Further research is needed to explore the long-term effects of these fertilizers on soil health and sustainability in C. moschata cultivation.
Project Overview
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</p><p><em>Cucurbita moschata</em> was discovered in southern Mexico around 5000 BCE and along the coast of Peru around 3000 BCE South America, is thought to be the secondary site of domestication. This species spread to northeastern Mexico by 1400 BCE and to the southwest U.S. by 900 CE. <em>Cucurbita moschata</em> made its way to the Gulf coast and Caribbean by way of early Spanish explorers. Crooknecks and cheese pumpkins, original to North America, were cultivated by colonists in the 1600s and variations can be found in India, southeastern Asia, Asia Minor and in Japan. By the 19th century <em>Cucurbita moschata</em> was established in northern Africa as well.</p><p><em>Cucurbitaceae</em> is one of the largest families in vegetable kingdom consisting of largest number of edible type species. Pumpkin (<em>Cucurbita moschata</em> Poir.) is one such important vegetable belongs to family <em>Cucurbitaceae</em>. Pumpkin fruits are extensively used as vegetables both in immature and mature stage. The yellow and orange fleshed fruits are very rich in carotene, which is precursor of Vitamin-A with fair quantities of vitamins B and C (Prem Nath <em>et al</em>., 1973). In modern agriculture, chemical fertilizers constitute the major portion of total cost of seed production. As the cultivation of pumpkin is fast expanding, the growers often come across one or the other problems that limit its fullest expressions of growth and productivity. Hence, these problems could be overcome partially or completely by using different agrochemicals like mineral nutrients and growth regulators. The optimum doses of nitrogen, phosphorus and potassium vary greatly with the length of growing season, fertility status of soil, soil type, cultivar, geographical location and the environmental factors. These factors will have marked effect on the growth and yield parameters of pumpkin.</p><ol><li>To find out the effect of organic and inorganic fertilizers on <em>Cucurbita moschata.</em></li><li>To ascertain the proper concentration of this organic and inorganic fertilizer that is required by <em>Cucurbita moschata </em>for it proper growth and best method of application of the fertilizer either ring method or broadcasting method..</li><li>To give possible recommendations on what to do for a proper growth and development of <em>Cucurbita moschata.</em></li></ol><p><em> </em></p><p>Plant growth regulators, a new generation of agrochemicals, when added in small amounts, modify the natural growth right from seed germination to senescence in crop plants. Among them, the use of GA3, is of considerable interest in different fields of agriculture and horticulture. Studies conducted elsewhere indicated the beneficial effects of chemical fertilizers and growth regulators on crop growth, fruit yield, seed yield and seed quality aspects in <em>cucurbitaceous</em> crops. Therefore, there is a urgent need to generate precise information with regard to requirement of optimum doses of chemical fertilizers and appropriate stage of spray with suitable growth regulators which help in better growth habit, fruiting and seed yield combined with better quality. Considering all these points in view an attempt has been made to find out the effect of chemical fertilizers and organic manure on seed yield and quality of musk pumpkin( <em>Curcubita moschata</em>).</p><p>A tropical hybrid of <em>Cucurbita moschata </em>reaches 90 ton.ha-1 grown under drip irrigation and plastic mulch. In another work with <em>Cucurbita moschata</em>, a high yield of 85 ton.ha-1 was obtained for tropical hybrid C-42 x La Segunda by transplanting and using mulching and row cover in a favorable year, the yield decreased to 43 ton.ha-1 by direct seeding without mulching and row cover in the same year. The previous year (1998) was humid and the yield under the last method was 28 ton.ha-1 . Experimental yields of <em>Cucurbit moschata</em> landraces obtained in the Department of Agriculture and Animal Science of the University of Sonora (DAG) during the summer-fall season under furrow irrigation, changed from 7.9 to 17.8 ton.ha-1, and from 1.2 to 24.6 ton.ha-1 for the winter-spring season. The yield was improved by increasing the plant population reaching 30.3 ton.ha-1 for the summer-fall season of 1988 using 0.33 plants per square meter.</p><p>The family <em>Cucurbitaceae</em> consists of about 117 genera and 825 species out of which about 15 different species of <em>Cucurbitaceae</em> are being cultivated in Bangladesh since long time. They have numerous resemblances in gourd development and similarities of root habit. They are also quite similar in their internal anatomy and development (Whitaker & Davis, 1962).The need to use renewable forms of energy and reduce costs of inorganic fertilizer has revived the use of organic fertilizers worldwide. Improvement of environmental conditions and public health are important reasons for advocating increased use of organic materials (Seifritz, 1982; Ojeniyi, 2000; Maritus <em>et al</em>, 2001). They thus, ensure a longer residual effect (Sherma and Mittra, 1991), support better root development and this leads to higher crop yields (Abou el Magd <em>et al</em>., 2005). The study, therefore, seeks to determine the effects of organic manure (poultry manure) and inorganic fertilizer application on the nutrient uptake and yield of <em>Cucurbita moschata.</em></p><ul><li><strong>Effect Of Urea And Nitrogen Inorganic Fertilizers On Some Plants</strong></li></ul><p>Sustainable crop production requires judicial use of inputs such as fertilizers, the use of inorganic fertilizers has drastically declined following the energy crisis, which has immensely affected most of the developing countries (Hauck, 1981). Urea is one of the synthetic organic fertilizers containing 46% of nitrogen. It is readily soluble and leachable when it is first applied to the soil but when it changes to ammonium it is held by clay and humus in the adsorbed forms that is readily available to plants. Under favorable temperature and moisture conditions urea hydrolyses to ammonium carbonate and then to nitrate within less than a week. The synthesis of ammonium carbonate is dependent on the influence of enzymes produced by numerous soil microorganisms.</p><p>Sharma (1993) found that urea, thiourea and citric acid have stimulatory effect on sprouting and growth performance in the stem cuttings of <em>Commiphora wightii</em> and <em>Commiphora</em> <em>agallocha</em>. Ghos and Chattopadhyay (1999) showed effect of foliar application of urea on yield of mango fruits. It was demonstrated that three application of 4% urea resulted in highest fruit yield per tree and maximum fruit weight was recorded from 3% urea. Myers (1998) observed the effect of Nitrogen-fertilizer on Amaranthus species grain yield, yield components and growth and development investigated in three Missouri environments with 5-levels of Nitrogen-fertilizer and 3 cultivars. Averaged across cultivars and environments, N fertilizer act and top rate of 180 kg/ha produced a yield increase of 42% relative to plots receiving no fertilizer. Although amaranth yield is responsive to Nitrogen -application, high rates of Nitrogen fertilizer can negatively affect grain harvest in terms of excessive plant height, increased lodging and delayed crop maturity. Cai<em> et al</em> (2003) found that highest yield and best quality of tobacco were obtained by applying 75 kg/ha nitrogen. Inorganic nitrogenous fertilizer could significantly improve the yield and quality of tobacco, compared with organic nitrogenous fertilizer. Study of Zhang et al., (2002) reveals that the strong immobilization of nitrogen by microorganisms was always followed by a net N mineralization, which was mostly favorable for the growth and development of plant and improved the efficiency of plants for nitrogen fertilizer. Increasing concentration of urea showed enhancing effect in both roots and shoot growth. The root and shoot biomass gradually increased in the control, as well as in the treated plants after every period i.e. 15 days. The initial weight (i.e. 0.04g) of the roots of control plants is least whereas in the soil amended with 0.05g /kg of urea was just the double.</p>
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