A two-year field experiment was car

A two-year field experiment was carried out on the acidic coastal plain sands of South Eastern Nigeria during the
year 2009 and 2010 planting seasons to study the effect of lime levels (L = 0, 500 and 1000 kg ha-1) and nitrogen
rates (N = 0, 40, 80 and 120 kg ha-1) on -popcorn varieties (Yellow composite and Ashland). Results showed that
N application resulted in significantly (p=0.05) higher grain yield at 80kg N ha-1 in 2010 than that obtained at
120 kg Nha-1 in 2009. Yield in 2010 outstripped yield in 2009 by 23.65%. Results also showed that lime at 500
kg ha-1 gave the highest popcorn yields in 2010, a yield increase of 18.03 % above control, whereas there was no
yield response to lime in 2009. Based on the results obtained, it can be concluded that popcorn sown at 80 kg N
ha-1 and 500 kg ha-1 rates of lime significantly increased the crop productivity compared to those sown at other N
and lime rates. The study demonstrated the effect of lime amendment in reducing rates of inorganic N applied to
popcorn especially with resource poor farmers who form the bulk of maize producers in Nigeria.
Keywords: popcorn, nitrogen, Lime, agronomic efficiency, acid soil
1. Introduction
Corn shows large responses to nitrogen (N) fertilizer application, depending on weather, soil characteristics, water
supply, crop uniformity and the nutrient responses of the cultivated varieties (Nagy, 1997). However, concerns
about N pollution of the environment, such as leaching of nitrates into ground water, nitrous oxide emission into
the atmosphere and other forms of environmental degradation have stimulated interest in low-input strategies for N
fertilization (Weisler et al., 2001; Sheng-wei et al., 2009). Nitrogen is vital for most plant metabolic activities and
plays an important role in tillering, stalk elongation and photosynthesis (Koochekzadeh et al., 2009). Its deficiency
results in leaf area reduction which causes decreased photosynthesis which in turn leads to suppression of yields
and crop quality (Sreewarome et al., 2007).
Soil acidity is a major limitation to crop production in the humid tropics, which necessitates the use of liming for
corrective purposes and amelioration of acidity. Soil acidity affects soil property and crop performance, causes
deficiency of soil nutrients, depresses microbial growth and suppression of organic matter accumulation (Brady &
Weil, 1999). The possibility of increasing yields through judicious fertilization and liming has been reported by
several workers (Caires et al., 2007; Mullen et al., 2007; Hassan et al., 2007; Eze and Obi, 2008). Liming improves
growth conditions for plants by increasing soil pH, availability of phosphorus and basic cations, resulting in
increased nutrient uptake by plants (Brady & Weil, 1996; Halder et al., 2003). Eze and Obi (2008) obtained the
highest pocorn yield of 1.58 t ha-1 at 0.5 t ha-1 lime rate while Hassan et al., 2007 recorded the highest yields of
popcorn 4.32 t ha-1 with 0.25 t ha-1 lime rate. Oluwatoyinbo et al. (2005) obtained the highest fruit yield of okra 3.0
t ha-1 at 500 kg ha-1 lime.
Generally, yield response of corn grown on low fertility soils increases with increment in nitrogen uptake until
yield is maximized, whereupon it decreases or becomes unresponsive to additional fertilizer rate increases (Nagy,
1997; Gokmen et al., 1999; Vasanthi & Kumaraswamy, 2000). In other words, yield response to larger N supply is
positive until factors other than nitrogen limit higher yield. The positive response could be due to either a large
amount of radiation intercepted over the crop growth period or higher average daily rate of photosynthesis (Vos et
al., 2005), photo-assimilation (Melchiori & Caviglia, 2008) and nutrient partitioning (Sierra et al., 2006).
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Corn grain yield is a product of yield components such as number of plants per unit area, number of ears per plant,
number of kernels per ear, kernel weight, total dry matter and 1000-grain weight. Increasing the N rates increases
the number of cobs per ear, number of grains per ear and other parameters associated with yield (Onasanya et al.,
2009; Orosz et al., 2009; Akmal et al., 2010).
Hamid and Nasab (2001) observed that both economic and biological yield, are positively correlated with
vegetative and reproductive phase duration in maize. Leaf area influences interception and utilization of solar
radiation by crop canopies, and consequently dry matter accumulation as well as economic yield. Valentinuz and
Tollenaar (2006) reported that leaf area and yield increased with higher rates of N. According to Pandey et al.
(2008), maize cultivars differ in their ability to maintain leaf area index (LAI), crop growth rate (CGR) and above
ground dry matter biomass at different levels of water deficit and N supply (Dahmardeh, 2011).
Our objective was to assess the effects of nitrogen and efficacy of lime on the yield performance of two varieties of
popcorn on an acid soil in south eastern rainforest agro-ecology of Nigeria.
2. Materials and Methods
2.1 Experiments, Crops and Management
Field experiments were conducted for two years at the Teaching and Research Farm of the University of Calabar in
the south eastern rainforest zone of Nigeria (4.50 -5.20 N,8.0 – 8.30 E, 39m altitude) during the years 2009 and 2010
growing seasons.A different site was used each year of the experiment. The soil was an Ultisol under no till since
2002, organic matter contents were 1.0 and 3.18, total N 0.07 and 0.14 (g kg-1) for plots in years 1 and 2
respectively, while P was 106.6 and 279.29(mg kg-1). Previous crops were cocoyam and alley cropped cooking
bananas in year 1 and 2 respectively. Treatments were laid out in a split-plot design with three replications and
included a factorial combination of three factors- varieties (V1= Yellow composite and V2= Ashland), four
nitrogen rates (0, 40, 80 and 120 kg ha-1) and three rates of lime (0, 500 and 1000 kg ha-1). The hybrid elite popcorn
varieties- Yellow composite and Ashland were sown at a plant spacing of 0.75m x 0.25m, all the lime rates were
soil incorporated one week before planting. Half of the nitrogen as urea (46% N), alongside basal single
superphosphate (26 kg P ha-1) and muriate of potash (50 kg K ha-1) were ring applied by hand one week after
emergence. The second half of N was side-dressed 6 weeks after sowing, at about 8 -10cm depth and a distance of
10cm away from the plants.
Relevant results of soil physico-chemical analyses and meteorological conditions of the experimental location
during the seasons are presented in Tables 1 and 2 respectively. Crops were rain fed, therefore received varying
amounts of water in the different years of the study. Sites were manually cleared, tilled and leveled to a fine tilled
flat, before sowing on 18th April and 14th May for the 2009 and 2010 planting seasons respectively. Three seeds
were sown per stand and the seedlings were later thinned to one per stand one week after sowing, giving a plant
population of 53,333 plants per hectare at 0.75 m inter rows and 0.25 m intra-row spacing through out the
experiment. Experiments were kept free of diseases and pests, while weeding was done by manual hand hoeing at
4 and 8 weeks after sowing (WAS). The ears were harvested on 4th July and 21st August in 2009 and 2010 seasons
respectively and sun dried until 4 months later when the seeds attained more than 80% popping percentage.
Table 1. Mean monthly rainfall, average temperature, Humidity and photo-synthetically active radiation during the
two experimental seasons
Rainfall (mm) Average Temp (0C) Humidity (%) Sunshine (Hrs)
2009 2010 2009 2010 2009 2010 2009 2010
April 150.5 130.4 32.1 33.1 84 83 3.0 5.2
May 308.9 306.5 31.6 31.5 84 85 4.4 4.4
June 218.4 611.3 30.2 29.8 87 88 2.2 3.2
July 507.3 384.0 28.0 28.8 92 90 1.7 2.0
August 507.3 406.7 28.1 28.2 92 91 1.0 1.8
Source: Nigerian Meteorological Unit, Margaret Ekpo International Airport, Calabar.
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Table 2. Physical and chemical properties of the soil from 0-20cm at the experimental sites during 2009 and 2010
planting seasons
Year
Physical Composition 2009 2010
Particle size analysis (g kg-1)
Sand 772 801.3
Silt 119 96.5
Clay 109 102.2
Soil textural class Sandy loam Sandy loam
Chemical composition
pH 5.30 5.25
Organic matter (g kg-1) 1.00 3.18
Total Nitrogen (g kg-1) 0.07 0.14
Available P (mg kg-1) 106.5 279.29
Na (cmolkg-1) 0.29 0.09
K “ 0.14 0.12
Ca “ 1.33 1.69
Mg “ 0.23 0.66
ECEC “ 4.80 3.06
Base Saturation (g kg-1) 50.41 52.56
Exchangeable Acidity 0.06 0.06
2.2 Measurements and Analysis of Data
For the collection of data, ten plants were randomly tagged two weeks after planting within the plots and the
following parameters were measured;
Plant height: this was measured with a meter tape from the ground level to the collar of the tallest fully
differentiated plants or the tips of tassels at last sampling and recorded in centimetres.
Leaf area index: This was computed by dividing the total area of leaves by the total ground area covered by the
plant.
Number of days to 50% tasselling: By counting the number of days from sowing till half of the total number of
plants per plot attained tasselling.
Total dry matter (g): This was determined by harvesting above ground portion of a plant in each plot every two
weeks and oven drying to constant weight at 700C and the weights recorded.
Weight of ears per plant (g): Corn ears from plants in the net plot were weighed and averaged to represent mean ear
weight per plant and recorded in grammes.
Number of kernels per ear: The number of ears on plants within the subplot were counted and the average taken as
number of ears per plant.
Total grain yield: This was determined by oven drying the threshed seeds from each yield sample to a constant
weight at 700C, weighing the sample and expressing t