EFFECT OF ORGANIC NUTRIENTS MANAGEMENT ON YIELD OF CUCUMBER (Cucumis sativus) AND ITS RESIDUAL EFFECT ON SOIL B.P. Bhattarai and Bishnu Sapkota Himalayan College of Agricultural Sciences and Technology/PU, Kathmandu, Nepal ABSTRACT The study was conducted in the farmer s field at Setidevi-VDC, Pharping of Kathmandu district to find out the effect of organic nutrient management on yield of cucumber and its residual effect on soil. There were six treatments with different combination of organic nutrient sources. The experiment was laid out on Randomized Complete Block Design (RCBD) with three replications. Yield per plot and per hector was found highest in T5 (½ vermicompost + ½ Poultry manure). The ph value was near to neutral in treatment T2 (Poultry manure @ 5 ton/ha). Similarly, the maximum organic matter percentage and soil available nitrogen were observed with treatment T3 (Vermicompost @ 4 ton/ha) whereas the highest available phosphorus and potassium were found in treatment T2 (Poultry manure @ 5 ton/ha). Keywords: Poultry Manure, Vermicompost, FYM, Soil nutrient INTRODUCTION Cucurbitaceae vegetable is large and increasingly important vegetable. Cucumber (Cucumis sativus L.) is an important vegetable and one of the most popular members of the cucurbitaceae family. It is thought to be one of the oldest vegetables cultivated by man with historical records dating back 5,000 years (Wehner and Guner,2004). The crop is the fourth most important vegetable after tomato, cabbage and onion in Asia, the second most important vegetable crop after tomato in Western Europe (Phu, 1997). China is world s number one producer of cucumber. Though cucumber technically is a fruit, cucumbers are widely considered vegetables. Much like tomatoes and squash, however, their sour-bitter flavor contributes to cucumbers being perceived, prepared and eaten as vegetables and there is no conflict in classifying cucumber as both a fruit and a vegetable. Cucumber is commonly used for salads and pickles. Cucumbers are www.ijaer.in Copyright IJAER 2016, All right reserved Page 1768
high in potassium and fiber with moderate amounts of Vitamins A and C, as well as folic acid, phosphorous, and magnesium. Cucumber is one of the major vegetable produced in Nepal in term of production and cultivated land. The cultivation of this crop is very popular at an altitude 1000 to 1800 m, above mean sea level as a source of income. It has acquires the status of world s most popular vegetable crop due to its wider adaptability to various climatic condition. The productivity of vegetable is slowly declining over the years due to deterioration on soil fertilizer. One of the reasons may be due to decline in use of organic matters in soil. A decline is use of organic matter may lead to nutrient imbalance and may be attributed to inappropriate fertilizer application. Organic manure application sustains cropping system through better nutrient recycling, improved soil structure and increased soil water holding capacity, reduces the leaching loss of nutrients, increases microbial activity, improve porosity and reduces the erosion losses of soil (Jaishy et al. 1998). MATERIAL AND METHODS This study was conducted from May to August 2013 in the farmer s field at Setidevi-VDC, Pharping, Kathmandu Nepal. Experimental plot size was 10m 2. The was laid out in complete randomized design with three replications and six treatments (Table 1). Table 1 Treatment of experiment Treatment T 1 T2 T3 T4 T5 T6 Sources of Nutrient FYM @ 12 ton/ha Poultry manure @ 5 ton/ha Vermicompost @ 4 ton/ha ½ FYM+ ½ vermicompost ½ vermicompost + ½ Poultry manure) Control www.ijaer.in Copyright IJAER 2016, All right reserved Page 1769
Yield per plant The observation on yield per plant was recorded after each harvesting of the fruits. After harvesting the fruits from each plant were weighed and expressed in kg/plant then calculated in yield per/plant, per plot and per hector. Determination of Soil Nutrients Status Collection and preparation of soil sample Soil samples were collected from 0-30 cm depth, regarding each treatment and replication. Three samples from each plot were taken and mixed to form one composite sample. The soil samples thus collected were dried and sieves through 2mm bronze sieve and stored in cloth bags. Digital ph meter was used for ph determination. For this ph meter was calibrates with the help of standard buffer solution for ph 4 and 7. Soil organic matter was determined by Walkey-Black method ( Walkey and Black, 1934). The nitrogen content in soil was determined by alkaline permanganate method as modified by Subbiah and Asiz ( 1956). Phosphorus content in the soil was determined with the help of Modified Olsen method (Olsen et al. 1954). Potassium content in soil was determined by ammonium acetate and detected by flame photometric method (Hamway ad Heidel, 1952). The statistical analysis of the data carried out as per described by Corchan and Cox (1963). The treatments effects were tested at 5 percentage level of significance. RESULTS AND DISCUSSION Effect of organic nutrients on the yield of cucumber (Cucumis sativus) Yield per plant /plot /hectare The maximum yield per plot (17.98) was recorded in T5 (Vermicompost + Poultry manure) which was statistically at par with T3 (Vermicompost), T2 (poultry manure), T4 (Farmyard manure + vermicompost) and T1 (Farmyard manure) ( Table 2). Increase in yield may be due fact that these organic manures supplies direct available nutrients such as nitrogen to the plants and these organic manures improves the proportion of water stable aggregates of the soil. This was attributed to cementing action of polysacchrides and other organic compounds released during the decomposition of organic matters, thus leading to taller plants, increased number of leaves, tillers and inturn the final yield, similar results was found Hendrix et al., (1994) and Martens et al., (1992), Thapa (2012) in Broccoli (Brassica oleraceae Var. italic). www.ijaer.in Copyright IJAER 2016, All right reserved Page 1770
Table 2 Effect of Organic Nutrients Management on Yield (fruits weight, yield/plant/plot/hectare) of Cucumber (Cucumis sativus) Treatment Yield per plot Yield per (kg) hectare (ton/ha) T1 (Farm Yard Manure) 6.97 6.97 T2 (Poultry Manure) 11.21 11.21 T3 (Vermicompost) 15.56 15.56 T4 ( Farm Yard Manure + Vermicompost) 10.92 10.92 T5 (Vermicompost + Poultry Manure) 17.98 17.98 T6 (Control) 5.06 5.06 CD (0.05) 4.8635 4.8635 F-Value 10.1384 10.1384 CV% 23.69 23.69 Effect of oorganic nutrients on soil ph and OM in Soil. Soil ph The ph value range from 6.2 to 7.1 was observed. The perusal of data (Table 3) revealed that the most optimum ph value (7.0) was recorded in T2 (5 ton/ha Poultry manure) which was statistically at par with T1 (12 ton/ha Farmyard manure manure), T4 (1/2 Farmyard manure + ½ Vermicompost), T5 (1/2 Vermicompost + ½ Poultry manure) and T3 (4 ton/ha Vermicompost). The observations show that the optimum ph was recorded whenever Farmyard manures were applied only. This might be due to the fact that the organic manure wound has acted as a liming agent and maintaining the ph of soil. Similar results was recorded by Ray et al. (2005) in which application of chemical fertilizer only, recorded decrease in soil ph, while addition of varying combination of FYM and chemical fertilizer recorded variable increase value similar results was found by Ayuba and Obasi (2005) the cow dung (FYM) and poultry litter rates increased the soil ph. Soil organic matter Organic matter percent revealed that the application of T3 (4 ton/ha Vermicompost) produced maximum organic matter (3.675%) in soil which was statistically at par with T5 (1/2 Vermicompost + ½ Poultry manure), T4 (1/2 Farmyard manure + ½ Vermicompost), T1 (12 www.ijaer.in Copyright IJAER 2016, All right reserved Page 1771
ton/ha Farmyard manure) and T2 (5 ton/ha Poultry manure) (Table 3). The result indicated that the vermicompost with a relatively high content of humus like compound, active microorganism and enzymes, greatly contribute to the enhancement of the biochemical fertility of soils. Bhattarai et al.(2011) reported that in tomato, the ph value was found near to neutral and the maximum organic matter percentage with the application of 10 mt/ha Vermicompsot. Table 3 Effect of organic nutrients management on soil chemical properties Treatment ph Organic Matter (%) T1 (Farm Yard Manure) 7.1 3.334 T2 (Poultry Manure) 7.0 3.532 T3 (Vermicompost) 6.4 3.675 T4 ( Farm Yard Manure + Vermicompost) 6.6 3.619 T5 (Vermicompost + Poultry Manure) 6.5 3.630 T6 (Control) 6.2 2.330 CD (0.05) 0.5779 0.5034 F-Value 3.4449 10.3636 CV% 4.78 8.25 Effect of organic nutrients on the Soil nutrients Available Nitrogen The nitrogen content available in the soil (341.54 kg/ha) was found higher in T3 (Vermicompost 4 ton/ha), which is statistically at par with T5 (1/2 vermicompost + ½ poultry manure), T2 (5 ton/ha poultry manure), T4 (1/2 vermicompost + ½ Farmyard manure) and T1 (12 ton/ha Farmyard manure) (Table 4).This may be attributed due to that the organic like vermicompost holds nutrients and retained from losses. So the higher value of total nitrogen in vermicompost treated soil is due to release of nitrogen slowly and continuously rather than loss incurred through leaching and volatilization. This result was similar with the finding of Khatri (2009), reported N content was higher with vermicompost in cauliflower. In spite of using chemical fertilizers, the nitrogen was found low in NPK treated soil. Which might be due to leaching and volatization loss. In the same way mineralization of chemical fertilizer is faster than that of vermicompost. Chemical fertilizer must have been leached away whereas in vermicompost applied soil the applied vermicompost holda the nutrients and retained www.ijaer.in Copyright IJAER 2016, All right reserved Page 1772
from losses. So, higher value of total nitrogen in vermicompost treated soil is due to the slow but continuous release of nitrogen from vermicompost. A similar result was found by Tripathi et al. (1978). Available phosphorus Maximum available soil phosphorus (121.47 kg/ha) was observed in T2 (5 ton/ha Poultry manure), which was statistically at par with T4 (½ Farmyard manure + ½ Vermicompost), T3 (4 ton/ha Vermicompost), T5 (1/2 vermicompost + ½ poultry manure) and T1 (12 ton/ha Farmyard manure) (Table 4). The organic manure increases the fixation of phosphorus and increase the available phosphorus concentration in soil for absorption resulting in increased content of phosphorus in all vegetable. The total N and P content of poultry manures and litters are among the highest due to its rapid mineralization. So, poultry manure was recognized as a valuable source of plant nutrients for crops (Somners and Sutton, 1980). Thapa (2012) reported that highest available phosphorus(p) was recorded in plot treated with poultry manure @ 2ton/ha. Worthington (2010) reported that application of poultry manure in tomato crops registered significantly higher phosphorus content among all the organic manures applied. Similar higher phosphorus content was reported in organically grown beetroot, spinach, tomato, turnip, cabbage, lettuce, spinach, carrots, apples and pears. Available potassium The available potassium (388.76 kg/ha) was found higher in T2 (5 ton/ha poultry manure) which was statistically at par with T4 (1/2 farmyard manure + ½ vermicompost), T3 (4 ton/ha vermicompost), T5 (1/2 vermicompost + ½ poultry manure) and T1 (12 ton/ha Farmyard manure) ( Table 4). The requirement of potassium content is quite essential for the proper growth and development of crops. The crop roots take of K actively from the soil. The present material and use of organic manure affects the potassium content of soil. The Nepalese soil in average is rich in the content of available potassium In this study the potassium content was found higher in Poultry manure treated soil than that other treatment. In the present study higher value of potassium was recorded with poultry manure. This study is similar with the results given by Bhattarai and Kuwor (2011) that reported the potassium content is quite higher in the treatment with poultry manure. www.ijaer.in Copyright IJAER 2016, All right reserved Page 1773
Table 0. Effect of organic nutrients management on soil nutrients status Treatment Available N Available P Available K (Kg/ha) (Kg/ha) (Kg/ha) T1 (Farm Yard Manure) 288.37 106.58 301.94 T2 (Poultry Manure) 328.65 121.47 388.76 T3 (Vermicompost) 341.54 113.72 343.33 T4 (Farm Yard Manure + Vermicompost) 327.31 116.20 371.24 T5 (Vermicompost + Poultry Manure) 336.00 111.93 324.41 T6 (Control) 286.49 96.96 290.41 CD (0.05) 49.1226 9.6731 21.8778 F-Value 2.4265 7.6718 30.9175 CV% 8.49 4.78 3.57 CONCLUSION It is concluded that, the yield per plot and yield per hectare were observed with the treatment ½ vermicompost + ½ poultry manure (T5). The ph value was near to neutral in treatment 5ton/ha poultry manure (T2). Similarly, the maximum organic matter percentage and soil available nitrogen were observed with treatment 4ton/ha vermicompost (T3). The highest available phosphorus and potassium were found in treatment 5ton/ha poultry manure (T2). REFERENCES Ayuba, S.A., John, C., Obasi, M.O. 2005. Effect of organic manure on soil chemical properties and yield of ginger- research note. Nigerian Journal of Soil Science. 15. Bhattarai, B.P. and K.C. Prativa. 2011. Effect of Integrated Nutrient Management on the Growth, Yield and Soil Nutrient Status in Tomato. Nepal Journal of Science and Technolog. 12: 23-28. Bhattarai, B.P. and Kuwor, P. 2012. Effect of organic nutrients management on Growth, and soil Nutrients status of Cabbage (B.oleracear var. capitata). Nepalese Journal of Agriculture Science. 9: 37-43. www.ijaer.in Copyright IJAER 2016, All right reserved Page 1774
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Tripathi, B.P. and Tuladhar, J.K. 1978. Effect of different quality organic materials on the performamce of wheat and soil properties in maize-wheat system. NARC Seminar Paper 97/19. Lumle Agricultural Research Center, Pokhara, Kaski, Gandaki zone, Nepal. Walkey, A. and Black, I.A. 1934. An examination of the degtjareff method for determination soil organic matter and prepared modification of the organic matter and prepared modification of the chronic and titration method. Soil Science. 34 (29-38): 335-340. Wehner, T. C. and Guner, N. 2004. Growth stage, flowering pattern, yield and harvest date prediction of four types of cucumber tested at 10 planting dates. Proc. xxvi IHC. Advances in Vegetable Breeding (Eds) J.D McCreight and E.J Ryder Acta Hort :637. Worthingrom, V. 2010. Nutritional quality of organic verses conventional fruits, vegetable and grains. The Journal of Alternative and complementary medicine. 7: 161-173. www.ijaer.in Copyright IJAER 2016, All right reserved Page 1776