Impact of Bio-Fertilizers on the Yield and Economics of Chrysanthemum Under real Farming Situation

D. K. Mishra1, Rakesh Jain2, A.K.Shukla3, Alok Deshwal4

1SMS (Horticulture), Krishi Vigyan Kendra, Kasturbagram, Indore, M.P. India.

2Farm Manager, Krishi Vigyan Kendra, Kasturbagram, Indore, M.P. India.

3SMS (Agronomy), Krishi Vigyan Kendra, Kasturbagram, Indore, M.P. India.

4Krishi Vigyan Kendra, Kasturbagram, Indore, M.P. India.

Corresponding author Email: dkmishra.indore@gmail.com

DOI : http://dx.doi.org/10.12944/CARJ.6.1.13

Article Publishing History

Received: 23/11/2017
Accepted: 31/01/2018
Published Online: 01-02-2018

Review Details

Plagiarism Check: Yes
Reviewed by: Dr. Smritikana Sarkar
Final Approval by: Dr. Dawn C.P. Ambrose

Article Metrics

Views     PDF Download PDF Downloads: 1808

Google Scholar

Abstract:

Chrysanthemum (Dendranthema grandiflora Tzvelev.) has earned tremendous popularity as a floral crop in Madhya Pradesh, particularly at Indore, Madhya Pradesh , India where it is being commercially cultivated as loose flowers  in open field condition during June to January. However, lower production and poor quality of flowers were observed due to haphazard and unbalanced use of inorganic fertilizers and non use of biofertilizers. With the objectives to tackle the issue of low productivity and quality of flowers, dissemination of recommended technology was successfully attempted during 2015-16 and 2016-17. The technologies of balanced use of inorganic fertilizer with bioferetilizer (Azotobactor and PSB) were used as technical intervention. The collective effect of scientific intervention revealed an average yield of 113 quintal / ha, which is 14.76 % higher over farmer’s practice. Average net returns from recommended technology were observed to be of Rs. 1, 88,100 as compared to Rs. 1, 54,350 under farmer’s practice (control). Thus, an additional income of Rs 33,750 was realized through imparted technological intervention provided in demonstration plots. Cost-benefit ratio of recommended practice (2.25) was observed to be significantly higher over farmer’s practice (2.17). Enhanced economic benefit and favorable C: B proved the economic feasibility of the technological intervention and was convincing for the farmers, for further future adoption.  At present scenario, organic fertilizers including bio fertilizers are becoming indispensable input to minimise our compulsion on synthetic fertilizers.

Keywords:

Biofertilizers; Chrysanthemum; Economics; Yield

Download this article as: 

Copy the following to cite this article:

Mishra D. K, Jain R, Shukla A. K, Deshwal A. Impact of Bio-Fertilizers on the Yield and Economics of Chrysanthemum Under real Farming Situation. Curr Agri Res 2018;6(1). doi : http://dx.doi.org/10.12944/CARJ.6.1.13

Copy the following to cite this URL:

Mishra D. K, Jain R, Shukla A. K, Deshwal A. Impact of Bio-Fertilizers on the Yield and Economics of Chrysanthemum Under real Farming Situation. Curr Agri Res 2018;6(1). Available from: http://www.agriculturejournal.org/?p=3400


Introduction

Chrysanthemum (Dendranthema grandiflora Tzvelev.) is commonly called as Guldawdi, saventi or Autumn Queen and belongs to the family Asteraceae. It is one of the leading commercial flowers grown throughout the world. In India, Chrysanthemum occupies a prime position as apious cut flower for all traditional uses and also as an ornamental flower for the garden. Its wide popularity is due to its wide variations exhibited with respect to growth, habit, size, shape, and colour of the bloom.  Chrysanthemum has earned tremendous popularity as floral crop in Madhya Pradesh particularly at Indore district where it is being commercially cultivated as loose flowers in about 95 hectare2 in open field condition during June to January. Although, the productivity and quality in the farmers’ fields observed were very low, considerable scope for its improvement exists. It becomes realistic to detect the reason in the wake of low productivity and flower quality by means of survey, farmer’s interaction and problem-solving field visit. The foremost reason of low productivity and poor flower quality as ascertained during regular surveys, farmers meetings and field diagnostic visits was unscientific and unbalanced use of inorganic fertilizers and non implementation of integrated nutrient management practices. At present scenario organic fertilizers including bio fertilizers are becoming inevitable input to minimise our dependency on synthetic fertilizers. Consequently as an intervention on integrated nutrient management practices along with Biofertilizers including Azotobactor and Phosphate solubilising bacteria were used,which are input containing microorganisms, competent of mobilizing nutritive elements from unusable to usable form in the course of biological procedure.  Biofertilizers are inexpensive, eco- friendly, feasible and sustainable inputs. They do not require any renewable supply of energy during production. They are useful as bio-control agents for controlling many plant pathogens and harmful microorganisms of field crops and aid sustainable flower production through protection of soil productivity. Biofertilizers have shown a good promise and have come forward as a vital component of integrated nutrient management system, which are of greater significance of growing chrysanthemum under open field condition, are (i) Biological Nitrogen Fixers. And (ii) Phosphate solubilizers. With the objectives to address the problem of low yield with poor quality produce leading to lower economic returns, Integrated nutrient management with biofertilizer application in chrysanthemum under open field condition were attempted.

Methodology

To improve the yield and income level from chrysanthemum crop, the technology dissemination programme was carried out under real farming situation consecutively for the years 2015-16 &2016-17 at village Mirzapur of Indore district, Madhya Pradesh during June to January.  A total of 20 on farm demonstrations were organized during the period. Area distributed under each demonstration plot was 0.40 hectare (1.0 Acre) with Rajamal (Local) variety of chrysanthemum. The imparted technological intervention was based on the information gathered through surveys, farmer’s interaction and problem solving field visit during the cropping period, which brought out that arbitrary and unbalanced use of inorganic fertilizers and no use of biofertilizers, were the causes of low yield of loose flowers of chrysanthemum. The technologies of balanced use of recommended levels of nitrogen, phosphorus and potash (150-200,200,200)5,15,17,8 coupled with biofertilizer, namely Phosphorus solublizing bacteria (PSB) and azotobacter1 were used as technical intervention during the course of on farm demonstration. 20 percent reduction in nitrogenous and phosphoric fertilizer was made under recommended practice. Local check (control) was comprised of existing farmer’s practice of indiscriminate use of fertilizers (N50-60 P 300-400 and K 100 Kg/ha) without incorporation of biofertilizer.

The yield performance of both, farmer’s practice (FP) and recommended practice (RP) were recorded. Prior to the conducting experimental demonstration, training to the farmers of particular villages were conducted with regard to calculated technical interventions. Further steps like selection of experimental site, layout, farmers’ participation etc. were followed as recommended by Choudhary et al.,6 Plot-wise yield data were recorded from demonstration and farmer’s plots. Information of cost of cultivation was also recorded for economic evaluation in terms of net profit earned and the benefit cast ratio.

Result and Discussion

Table 1: Yield and economic of chrysanthemum (Variety – Rajamal) under real farming situation (data pooled for years (2015-16& 16 -17)

Year

On farm demonstration  (No)

Yield

 (q/ha)

% increase over FP

Expenditure (Rs/ha)

Gross Income (Rs/ha)

Net Income

(Rs/ha)

BC ratio

RP

FP

 

RP

FP

RP

FP

RP

FP

RP

FP

2015-16

10

109

95

14.42

150920

141300

326100

285000

175180

143700

2.16

2,02

2016-17

10

117

102

15.10

151180

141000

352200

306000

201020

165000

2.33

2.17

Mean

113

98.5

14.76

151050

141150

339150

295500

188100

154350

2.25

2.17

RP – Recommended practice, FP –Farmer’s practice, B: C Ratio –Benefit cost ratio.

The data (Table – 1) revealed that under recommended practice, the flower yield was recorded to be considerably higher than under farmer’s practice for the period of field demonstrations. The flower  yield enhancement over farmer’s practice, although varied (14.42 to 15.10 %) from year to year, it was 14.76 per cent on mean basis .Year wise fluctuations in yield and cost of cultivation can be elucidated on the basis of difference in existing social, economical and microclimatic conditions of the particular village. Mukharjee14 has also suggested that depending on recognition and use of farming situation, specific interventions may have larger implications on improving system efficiency. It is generally agreed that there is certain increase in yield, which is possible with the establishment of azotobacter in the rhizosphere of various crop plant. Significant yield increase was recorded with the inoculation of azotobacter in different crops.11,10 According to Mazid et al .,11b Application of bio fertilizer into the soil_ , facilitate fast multiplication of microorganism which accelerate the microbial process in soil and augment availability of plant nutrients, which can be easily assimilated by plants. Khan et al.,9   suggested that Bio- inoculants availability to the plants improve their growth and yield capacity. Yield enhancement at real farming situation in different crops through technology dissemination has amply been recognized by several researchers7,19,20,13.  Technology dissemination programme has demonstrated to the farmers about the use of effective and economical inputs, which are free from environmentally undesirable implications that chemicals inputs have. Likewise, Bio fertilizers can perform as a renewable supplement to inorganic fertilizers as well as organic manures. Bio fertilizers are having special ability to generate natural resistance in plants against pests and soil borne diseases. Due to antibodies development and participation of microorganisms in soil, fertility status get better4 with outcome as yield enhancement.Economic evaluation in terms of expenditure, gross income;, net income and cost benefit ratio obviously revealed that the net income  from the recommended practice were considerably higher over farmers practice (control plots) in both the  years (2015-16 & 16-17) of technology dissemination programme. An average net income from recommended practice were recorded Rs. 1,88,100 while it was Rs 1,54,350 against  farmer’s practice ,  with an average additional income of  Rs 33,750 and can be attributed to the technological intervention provided in demonstration plots. The benefit cost ratio of recommended practice was also substantially higher than farmer’s practice. It worked out to 2.16, and 2.02 for recommended practice as compared to 2.35 and 2.17 for farmer’s practice during 2015-16 and 2016-17, respectively. On mean basis it was 2.25 for recommended practice, whereas 2.17 for farmer’s practice. Thus, favorable cost benefit ratio and higher net income demonstrate the financial feasibility of the intervention organized under recommended practice and persuaded the farmers about the utility of intervention provided at real farming situation. Similar findings were reported by Sharma18 and Mishra13 in different crops. The beneficial use of nitrogen fixing microorganism’s viz., Azotobacter and phosphate solublizing bacteria (PSBs), as a supplementary source of plant nutrition on agricultural crops is well documented.3 These non-conventional sources of fertilizers are not only cost effective but simultaneously boost up the productivity of field crops.16

The figures (Table 1) further indicate that highest increase in yield and cost benefit ratio was during 2016-17. The difference in yield and cost benefit ratio recorded during both the years. This was mainly in consequence of yield performance, input cost and rate of output in that particular year of demonstration. Cost of cultivation or expenditure under recommended practice was observed higher. This was due to expenditure incurred on harvesting and marketing of chrysanthemum

Acknowledgement

Authors are grateful to the Farmers of village Mirjapur, Dist Indore for their support and Cooperation provided during the course of study.

References

  1. Anonymous. Bio-fertilizers for Horticultural Crops, Extension Literature ATIC Series 10 Pub by Director IIHR, Banglore. 2002.
  2. Anonymous. Official data- Department of horticulture & Farm Forestry. (2016). www.mphorticulture.gov.in
  3. Barakart, M.A.S. and Gabr, S.M. Effect of different biofertilizer types and nitrogen fertilizer levels on tomato plants. Alexandria J. Agril. Res. 1998;43:149-60.
  4.  Board, Niir. (2004), The Complete Technology Book On Bio-Fertilizer And Organic Farming. National Institute of Industrial Re. 2004.
  5. Chezhiyan, N., Nanjan K. and Khader, Md. Abdul. Studies on nutrient requirement of chrysanthemum cv CO 1. South Indian Horticulture. 1986;34:173-178.
  6. Choudhary, B. N., “Krishi Vigyan Kendra – A Guide for KVK Managers”, Publication of Division of Agricultural Extension, ICAR. 73-781999.
  7. Haque, M. S. Impact of compact block demonstration on increase in productivity of rice. Maharashtra Journal of Extension Education. 2000;19(1):22-27.
  8. Jankiram, T. and Manjunath Rao T. Chrysanthemum, Published by P. Parratha Reddy Director IIHR. 2001;10.
  9. Khan, T.A., Mazid and  Mohammad M. F.  A review of ascorbic acid potentialities againstoxidative stress induced in plants. Journal of Agro biology. 2011a;28(2):97-111.
  10. Kumaraswamy, D. and Madalageri, B.B. Effect of azotobacter inoculation on tomato. South Indian Horticulture. 1990;38(6):345-346.
  11. Marula, N., Nijhawan, D.C., Laxminarayana, K.L., Kapoor, R.L., and Verma, O.P.S.  Response of Pearlmillet to soil isolates and analogue resistant mutants of Azotobacter chroococcum. Indian J. Agril. Sci. 1991;61((7):484-4.
  12. Mazid, M., Zeba, H.K., Quddusi, S., Khan, T.A., Mohammad, F. Significance of Sulphur nutrition against metal induced oxidative stress in plants. Journal of StressPhysiology & Biochemistry, 2011b;7(3):165-184.
  13. Mishra, D. K., Paliwal D. K., Tailor R. S. and Deshwal, Alok . K. Impact of front line demonstration on yield enhancement of potato. Indian Research Journal of Extension Education. 2009;9(3):26-28.
  14. Mukherjee, N., Participatory, Learning and Action. Concept Publishing Company, New Delhi, India. 2003;63-65.
  15. Patil, S. D., Bhujbal, B. G., Patil,  J. D.,  and Chaughulo, B. B. Maharashtra Journal of Horticulture. 1992;6(2):95-97.
  16. Patra, S.K., Padhi., A.K. and Mishra, S.N. Effect of biofertilizers at graded levels of nitrogen on the yield of wheat and toria in the north-eastern ghat region of Orissa. Environ. Ecol. 1989;7:533-36.
  17. Rao, D. V. R., Balasubramanian., S.A. and Suryanarayana V. Effect of different spacing and nitrogen level on chrysanthemum. South Indian Horticulture. 1992;40(6):323-328.
  18. Sharma, O. P. Moth bean yield improvement through front line demonstrations. Agriculture Extension Review. 2003;15(5):11-13.
  19. Tiwari, K. B and Saxena, A. Economic analysis of FLD of oil seeds in Chindwara. Bhartiya Krishi Anusandhan Patrika. 2001;16(3&4):185-189.
  20. Tiwari, R. B.,  Singh Vinay and Parihar Pushpa,. Role of front line demonstration in transfer of gram production technology. Maharashtra Journal of Extension Education. 2003;22(1): 9.
scroll to top