Smallholder farmers having fragmented lands need fodder and grains simultaneously for earning food security for their families. A study was conducted in Crop Physiology and Ecology Research Field and Laboratory at Hajee Mohammad Danesh Science and Technology University, Bangladesh during the period of March to July-2013 to investigate the effect of leaf clipping and population density on fodder and grain yield in maize. Three population densities (D1= 75 cm × 25 cm, D2= 60 cm × 20 cm and D3= 50 cm × 20 cm) and three clipping treatments (C1 = no clipping, C2 = removal of all leaf blades below the lowermost cob and C3 = removal of all leaf blades above the uppermost cob) at the silking stage were included as experimental treatments. The experiment was laid out in a two factors Randomized Complete Block Design (RCBD) with three replications. Results revealed that D1 required the maximum days to attain most of the phenological stages of maize. Higher population density (D3) with C3 clipping treatment gave the highest plant height, whereas D1 with non-clipping treatment gave the lowest. Highest total dry matter (TDM) was found in D2 with C1 and the lowest was found in D1 with C1 treatment. The highest yield (8.88 t ha^-1) and harvest index (36.2%) were found in D3 treatment whereas the lowest yield (5.92 t ha^-1) in D1 population density but harvest index (32.6 %) was lowest in D2. The highest yield (8.33 t ha^-1) and harvest index (35.5 %) were obtained from C1 treatment and the lowest yield (6.55 t ha^-1) and harvest index (33.5 %) were obtained from C3 treatment. The highest fodder yield (3.33 t ha^-1) was obtained from D3 treatment and the lowest (2.11 t ha^-1) in D1 treatment. In C2 treatment, the highest amount of fodder (4.67 t ha^-1) was obtained. The interaction between population density and leaf clipping treatment showed a significant variation among the yield and yield attributes in maize. It is indicated that D3 and C1 combination showed the best performance in respect of grain yield (9.67 t ha^-1) and harvest index (38.3 %) of maize. But for both grain and fodder yield, D3 with C2 showed the best performance.

Abuzar, M. R., G. U. Sadozai, M. S. Baloch, A. A. Baloch, I. H. Shah, T. Javaid and N. Hussain. 2011. Effect of plant population densities on yield of maize. The Journal of Animal & Plant Sciences, 21: 692-95.

Ahmad, N. and F. C. Muhammad. 1999. Plant density effect on yield and quality of maize seed. Journal of Agricultural Research, 37: 25-29.

Ahmed, F. 1994. Maize Production Technology (in Bengali).International Fertilizer Development Center-Consultant of Ministry of Agriculture. Bangladesh. pp. 13-15.

Alam, M., M. Islam, N. Salahin and M. Hasanuzzaman. 2014. Effect of tillage practices on soil properties and crop productivity in wheat-mungbean-rice cropping system under subtropical climatic conditions. The Scientific World Journal, 2014: 40-55.

https://doi.org/10.1155/2014/437283

Ali, M. Y., S. R. Waddington, D. P. Hodson, J. Timsina and J. Dixon. 2008. Maize-rice cropping systems in Bangladesh: Status and research opportunities. Joint Publication of CIMMYT and IRRI. CIMMYT. Mexico. pp. 36.

Baenziger, P. S. and D. V. Glover. 1980. Effect of Reducing Plant Population on Yield and Kernel Characteristics of Sugary-2 and Normal Maize. Crop science, 20: 444-47.

https://doi.org/10.2135/cropsci1980.0011183X002000040005x

Chowdhury, M. K. and M. A. Islam. 1993. Production and use of maizeOn-Farm Research Division, Bangladesh Agricultural Research Institute. Joydebpur, Gazipur, Bangladesh pp. 8-57.

Emran, S. A. 2010. Source-sink manipulation and population density effects on green fodder and grain yield in hybrid maize, Department of Agronomy, Bangabandhu Sheikh Mujibur Rahman Agricultural University. Gazipur, Bangladesh.

Evenson, R. E. and D. Gollin. 2003. Assessing the impact of the Green Revolution, 1960 to 2000. Science, 300: 758-62.

https://doi.org/10.1126/science.1078710

FAO. 2012. Food and Agriculture OrganizationUnited Nations. New York, United States.

FAO. 2016. Food and Agriculture OrganizationUnited Nations. New York, United States.

Gathala, M. K., J. Timsina, M. S. Islam, M. M. Rahman, M. I. Hossain, M. Harun-Ar-Rashid and A. McDonald. 2015. Conservation agriculture based tillage and crop establishment options can maintain farmers’ yields and increase profits in South Asia's rice–maize systems: Evidence from Bangladesh. Field Crops Research, 172: 85-98.

https://doi.org/10.1016/j.fcr.2014.12.003

Goldsworthy, P. R., A. F. E. Palmer and D. W. Sperling. 1974. Growth and yield of lowland tropical maize in Mexico. The Journal of Agricultural Science, 83: 223-30.

https://doi.org/10.1017/s0021859600051893

Hassen, H. and S. S. Chauhan. 2003. Effect of rate of maize leaf defoliation at various growth stages on grain, stover yield components of maize and undersown forage production. Indian Journal of Agricultural Research, 37: 136-39.

Hus, A. and S. C. Huang. 1984. Effects of plant density on yield and agronomic characteristics of maize in spring and autumn cropping seasonTaichung District Agricultural Improvement Station. Changhua, China. pp. 13-21.

Khaliliaqdam, N., A. Soltani, T. Mir-Mahmoodi and T. Jadidi. 2012. Effect of leaf defoliation on some agronomical traits of corn. World Applied Sciences Journal, 20: 545-48.

Leakey, A. D. B., M. Uribelarrea, E. A. Ainsworth, S. L. Naidu, A. Rogers, D. R. Ort and S. P. Long. 2006. Photosynthesis, Productivity, and Yield of Maize Are Not Affected by Open-Air Elevation of CO2 Concentration in the Absence of Drought. Plant Physiology, 140: 779-90.

https://doi.org/10.1104/pp.105.073957

Loesch, P. J., C. F. Stark and M. S. Zuber. 1976. Effects of Plant Density on the Quality of Cobs Used for Corn Cob Pipes1. Crop science, 16: 706.

https://doi.org/10.2135/cropsci1976.0011183x001600050027x

Lomte, M. H. and V. S. Khuspe. 1987. Effects of plant densities, phosphorus levels and Antitranspirant on the yield of summer groundnut. Journal of Maharashtra Agricultural Universities, 12: 28-30.

Mariscal, M. J., F. Orgaz and F. J. Villalobos. 2000. Radiation-use efficiency and dry matter partitioning of a young olive (Olea europaea) orchard. Tree Physiology, 20: 65-72.

https://doi.org/10.1093/treephys/20.1.65

Natr, L. 1992. Mineral nutrients-a ubiquitous stress factor for photosynthesis. Photosynthetica, 27: 271-95.

Osorio, F. O. 1976. Population effect on yield and other characteristics of maize in the E-1 Zamorano Valley, Honduras. Field Crop Abstracts, 33: 1926-80.

Rathore, D. N., K. Singh and B. P. Singh. 1976. Effect of nitrogen and plant population on the yield attributes of maize. Indian Journal of Agricultural Research, 10: 79-82.

Remison, S. U. 1978. Effect of Defoliation During the Early Vegetative Phase and at Silking on Growth of Maize (Zea mays L.). Annals of Botany, 42: 1439-45.

https://doi.org/10.1093/oxfordjournals.aob.a085591

Sangoi, L. 2001. Understanding Plant Density Effects on Maize Growth and Development: An Important Issue to Maximize Grain Yield. Ciência Rural, 31: 159-68.

https://doi.org/10.1590/s0103-84782001000100027

Shiferaw, B., B. M. Prasanna, J. Hellin and M. Bänziger. 2011. Crops that feed the world 6. Past successes and future challenges to the role played by maize in global food security. Food Security, 3: 307-27.

https://doi.org/10.1007/s12571-011-0140-5

Timsina, J., R. J. Buresh, A. Dobermann and J. Dixon. 2011. Rice–Maize Systems in Asia: Current Situation and PotentialIRRI and CIMMYT. Los Banos, Philippines. pp. 232.

Valbuena, D., O. Erenstein, S. Homann-Kee Tui, T. Abdoulaye, L. Claessens, A. J. Duncan, B. Gérard, M. C. Rufino, N. Teufel, A. van Rooyen and M. T. van Wijk. 2012. Conservation Agriculture in mixed crop–livestock systems: Scoping crop residue trade-offs in Sub-Saharan Africa and South Asia. Field Crops Research, 132: 175-84.

https://doi.org/10.1016/j.fcr.2012.02.022

Wilson, J. H. and J. C. S. Allison. 1978. Effect of plant population on ear differentiation and growth in maize. Annals of Applied Biology, 90: 127-32.

https://doi.org/10.1111/j.1744-7348.1978.tb02619.x