 |
 |
 |
 |
 |
 |
Sains Malaysiana 47(6)(2018): 1269–1276
http://dx.doi.org/10.17576/jsm-2018-4706-23
Agronomic Biofortification of Fodder Sorghum
with Zinc under Different Levels of Nitrogen
(Biofortifikasi Agronomi Sorgum Foder dengan Zink
pada Tahap Nitrogen Berbeza)
WAQAS AHMAD*, MUHAMMAD TAHIR, RIAZ AHMAD
& RASHID AHMAD
Department
of Agronomy, University of Agriculture, Faisalabad-38040, Pakistan
Diserahkan: 13 Ogos
2017/Diterima: 22 Januari 2018
ABSTRACT
Zinc (Zn) deficient soil prevails throughout
the world and it has become the bottleneck in achieving production
potential and quality of crops. The negligible use of micronutrients
along with irregular use of macronutrients is practised for fodder
production in Pakistan. Varying levels of zinc (0, 5, 10 and 15
kg ha-1)
and nitrogen (0, 60, 120 and 180 kg ha-1) were evaluated for their effect
on yield, quality and zinc uptake on fodder sorghum (variety Hegari)
in a field experiment for two consecutive years (2014 and 2015).
Data were analysed by using Fishers' analysis of variance (at p<0.05)
and response surface methodology (RSM). Correlation between different
parameters was also studied. Application of zinc and nitrogen improved
the plant height, leaf area plant-1,
green fodder yield, dry matter yield, crude protein percentage and
zinc content of plant but decreased the neutral detergent fiber,
acid detergent fiber and ash percentage. Values for different parameters
recorded at second and third levels of zinc and nitrogen were remained
at par with each other. Application of 10 kg ha-1 zinc and 120 kg ha-1 nitrogen
showed an average increase of 7.3 and 18.6% in green fodder yield
while 12.1 and 15.8% in dry matter yield, respectively. Similarly
6.1 and 7.5% increase in crude protein was noted over control. Correlation
between NDF and
ADF
was negative with rest of the studied parameters.
In conclusion, Zn2 and N2 gave the best results in term
of yield and quality of fodder sorghum.
Keywords: Agronomic biofortification;
fodder; nitrogen; sorghum; zinc
ABSTRAK
Tanah yang kekurangan zink (Zn) berlaku
di seluruh dunia dan ia menjadi halangan
bagi mencapai potensi pengeluaran dan kualiti tanaman. Penggunaan
mikronutrien yang tidak dapat dielakkan bersama penggunaan makronutrien
yang tidak teratur diamalkan untuk pengeluaran foder di Pakistan.
Tahap zink (0, 5, 10 dan 15 kg ha-1)
dan nitrogen (0, 60, 120 dan 180 kg ha-1) telah dinilai untuk kesannya
terhadap hasil, kualiti dan pengambilan zink pada sorgum foder (pelbagai
Hegari) dalam uji kaji bidang selama dua tahun berturut-turut (2014
dan 2015). Data dianalisis menggunakan
analisis Fisher's pelbagai (pada p<0.05) dan kaedah gerak balas permukaan (RSM).
Korelasi antara parameter yang berbeza juga
dikaji. Penggunaan zink dan nitrogen meningkatkan ketinggian
tumbuhan, tumbuhan daun tanaman-1, hasil foder hijau, hasil bahan kering, peratusan protein
mentah dan kandungan zink tumbuhan tetapi menurunkan serat detergen
neutral, serat pencuci asid dan peratusan abu. Nilai untuk parameter
yang berbeza yang dicatatkan pada tahap kedua dan ketiga zink dan
nitrogen kekal setanding dengan satu sama
lain. Penggunaan 10 kg ha-1
zink dan 120 kg ha-1 nitrogen menunjukkan peningkatan purata sebanyak 7.3
dan 18.6% dalam hasil foder hijau manakala 12.1 dan 15.8% dalam
hasil bahan kering. Begitu juga 6.1 dan 7.5%
peningkatan dalam protein mentah telah diperhatikan melalui kawalan.
Korelasi antara NDF dan ADF negatif dengan sisa parameter
yang dikaji. Sebagai kesimpulan, Zn2
dan N2
memberikan hasil terbaik dalam bentuk hasil dan kualiti
sorgum foder.
Kata
kunci: Biofortifikasi agronomik; foder; nitrogen; sorgum;
zink
RUJUKAN
Alloway,
B.J. 2008. Zinc in Soils and Crop Nutrition. Brussels, Belgium:
International Zinc Association.
Amin,
M. & El-Murtada, H. 2011. Effect of different nitrogen
sources on growth, yield and quality of fodder maize (Zea mays L.). Journal of Saudi Society of Agricultural Sciences 10: 17-23.
Anonymous.
2011. Pakistan Agriculture Research Council. Government of
Pakistan. Available on line at http://www. parc.gov.pk/NARC/Fodder/Pages/intro.html.
AOAC.
1990. Officials Methods of Analysis. Washington D.C., USA. Association of Official Analytical Chemists.
Ashoka, P., Mudalagiriyappa, M., Pujari, B.T., Hugar, P.S.
& Desai, B.K. 2008. Effect of micronutrients with or without
organic manures on yield of baby corn (Zea mays L.) chickpea (Cicer
artietinum L.) sequence. Karnataka Journal of Agricultural
Sciences 21(4): 485-487.
Ayub, M., Nadeem, M.A., Tahir, M., Ibrahim, M. & Aslam,
M.N. 2009. Effect of nitrogen application and harvesting intervals on
forage yield and quality of pearl millet (Pennisetum americanum L.). Pakistan Journal of Life and Social Sciences 7: 185-189.
Ayub, M., Nadeem, M.A., Tanveer, A., Tahir, M. & Khan,
R.M.A. 2007. Interactive effect of different nitrogen levels and seeding
rates on fodder yield and quality of pearl millet. Pakistan Journal
of Agricultural Sciences 44(4): 592-596.
Ayub, M., Nadeem, M.A., Tanveer, A. & Husnain, A. 2002. Effect
of different levels of nitrogen and harvesting times on growth, yield and
quality of sorghum fodder. Asian Journal of Plant Sciences 4:
304-307.
Azam, M., Waraich, E.A, Pervaiz, A. & Nawaz, F. 2010. Response
of a newly developed fodder sorghum (Sorghum bicolor L. Monech) variety
(F-9917) to NPK application. Pakistan Journal of Life and Social
Sciences 8: 117-120.
Bhoya, M., Chaudhari, P.P., Raval, C.H. & Bhatt, P.K.
2014. Effect of nitrogen and zinc on growth and yield of fodder sorghum (Sorghum
bicolor L.) Moench varieties. International Journal of Agricultural
Sciences 10(1): 294-297.
Box, G.E.P., Hunter, W.G. & Hunter, J.S. 2005. An
Introduction to Design, Data Analysis, and Model Building. Statistics for Experimenters. 2nd ed. New York: John Wiley & Sons.
Cakmak,
I. 2002. Plant nutrition research priorities to meet human
needs for food in ustainable ways. Plant Science 247: 3-24.
Castagnara, D.D., Krutzmann, A., Steiner, T.Z.F., Castro,
A.M.C., Neres, M.A. & Oliveira, P.S.R. 2012. Effect
of boron and zinc fertilization on white oats grown in soil with average
content of these nutrients. Revista Brasileira de Zootecnia 41:
1598-1607.
Chaab,
A., Savaghebi, Gh. R. & Motesharezadeh, B. 2011. Differences
in the zinc efficiency among and within maize cultivars in a calcareous soil. Asian Journal of Agricultural Sciences 3(1): 26-31.
Chao,
N.K., Kang, Y.K. & Boo, C.H. 2001. Effect of split
nitrogen application on agronomic characteristics, forage yield and composition
of Japanese millet. Journal of Animal Science and Technology 43(2):
253-253.
Fageria,
N.K. 2002. Influence of micronutrients on dry matter yield and interaction with
other nutrients in annual crops. Pesquisa Agropecuária Brasileira 37:
1765-1772.
Fulkerson, W.J., Horadagoda, A., Neal, J.S., Barchia, I.
& Nandra, K.S. 2008. Nutritive value of forage species grown in the warm
temperate climate of Australia for dairy cows. Livestock Science 114:
75-83.
GOP.
2016. Economic Survey of Pakistan 2015-2016.
Ministry of Finance, Finance Division. Economic Advisor's Wing,
Islamabad. pp. 24-42. Hafeez, B., Khanif, Y.M. & Saleem, M. 2013. Role of zinc in plant
nutrition- A review. American Journal of Experimental
Agriculture 3(2): 374-391.
Hosnedlova, B., Travnicek, J. & Soch, M. 2007. Current view of
significance of zinc for ruminants: A review. Agricultura Tropica et Subtropica 40(2): 57-64.
Kwon,
S.H. & Torrie, J.H. 1964. Heritability and interrelation
among traits of two soybean populations. Crop Sciences 4:
196-198.
McGraw-Hill, C. 2008. Statistix 8.1. Analytical
Software, Tallahassee, USA.
Mehdi,
S.S., Husain, B. & Singh, L. 2012. Influence of seed
rate, nitrogen and zinc on fodder maize (Zea mays L.) in temperate
conditions of western Himalayas. Indian Journal of Agronomy 57(1):
85-88.
Rana, A.S., Ahmad, A.H., Saleem, N., Nawaz, A., Hussian, T.
& Saad, M. 2014. Differential response of sorghum
cultivars for fodder yield and quality. Journal of Global Innovative
in Agricultural and Social Sciences 2(1): 6-10.
Reddy,
V.R. & Soussan, J. 2004. Assessing the impacts of watershed development
programmes: A sustainable rural livelihoods framework. Indian Journal of
Agricultural and Economics 59(3): 331-343.
Sharifi,
R.S. & Taghizadeh, R. 2009. Response of maize (Zea mays L.)
cultivars to different levels of nitrogen fertilizer Journals of Food,
Agriculture and Environment 7(3-4): 518-521.
Shukla,
V.K., Agarwal, S.B. & Thakur, G.S. 2003. Response of seed rate and nitrogen
levels on forage yield of sorghum under rainfed condition in Madhya Pradesh. Jawaharlal
Nehru Krishi Vishwa Vidyalaya Research Journal 37: 83-84.
Singh,
P.H. & Sumeriya, K. 2012. Effect of nitrogen on yield,
economics and quality of fodder sorghum genotypes. Annals of Plant
and Soil Research 14: 133-135.
Soltanpour,
P.N. 1985. Use of AB-DTPA soil test to evaluate elemental
availability and toxicity. Communications in Soil Science and Plant
Analysis 16: 323-338.
Steel, R.G.D., Torrie, J.H. & Dickey, D.A. 1997. Principles and
Procedures of Statistics: A Biometrical Approach. 3rd ed.
New York: McGraw Hill Book Co., Inc. pp. 400-428.
van Soest, P.J., Robertson, J.B. & Lewis, B.A. 1991. Methods for dietary fiber, neutral detergent fiber and non-starch
polysaccharides in relation to animal nutrition. Journal of Dairy
Science 74: 3583-3597.
Verma,
S.S., Singh, N., Joshi, Y.P. & Deorari, V. 2005. Effect of nitrogen and zinc on growth
characters, herbage yield, nutrient uptake and quality of fodder sorghum (Sorghum
bicolor L). Indian Journal of Agronomy 50: 167-169.
Yatoo,
M.I., Saxena, A., Deepa, P.M., Habeab, B.P., Devi, S., Jatav, R.S. & Dimri,
U. 2013. Role of trace elements in animals: A review. Veterinary World 6:
963-967.
*Pengarang untuk surat-menyurat; email: waqasahmad.uaf@gmail.com
|
|||
|
