Research Article

Integrated Management of Fertilizer Nitrogen and Poultry Manure Enhance Wheat Production

Tanzim Ullah Khan1*, Mohammad Tariq Jan1, Ahmad Khan1, Gulzar Ahmad2, Muhammad Ishaq2, Khilwat Afridi2, Murad Ali2, Muhammad Adeel Qureshi2, Imtiaz Ahmad3 and Muhammad Saeed2

1Department of Agronomy, Faculty of Crop Production Sciences, Khyber Pakhtunkhwa Agricultural University, Peshawar, Pakistan; 2Cereal Crops Research Institute, Pirsabak, Nowshera, KP, Pakistan; 3Agricultural Research Institute, Tarnab,KP, Peshawar, Pakistan.

Received | September 12, 2017; Accepted | June 18, 2018; Published | August 19, 2018

*Correspondence | Tanzim Ullah Khan, Department of Agronomy, Faculty of Crop Production Sciences, Khyber Pakhtunkhwa Agricultural University, Peshawar, Pakistan; Email: tanzim_khan383@yahoo.com

Citation | Khan, T.U., M.T. Jan, A. Khan, G. Ahmad, M. Ishaq, K. Afridi, M. Ali, M.A. Qureshi, I. Ahmad and M. Saeed. 2018. Integrated Management of Fertilizer Nitrogen and Poultry Manure Enhance Wheat Production. Pakistan Journal of Agricultural Research, 31(3): 207-215.

DOI | http://dx.doi.org/10.17582/journal.pjar/2018/31.3.207.215

Keywords | Grain yield, Leaf area, Nitrogen, Poultry manure, Wheat

Introduction

Wheat is a self-pollinated, long day and winter crop and belongs to the plants family Poaceae. It is grown for grains as well as for fodder purposes to fulfill human and livestock requirements (Khalil et al., 2011). Globally, the use of wheat is more than it is produced (Anonymous, 2013). This lower production is due to inappropriate level and timing of fertilizers (Shah et al., 2011), alkalinity, nitrogen and organic matter deficit soils of the area (Shah et al., 2010). Huge quantity of inorganic N lost during the crop growth and causes pollution (Mattas et al., 2011). In such situation, organic and synthetic fertilizers applied in combination improve yield and yield components of wheat and made the soil structure better (Zhang et al., 2016).

Nitrogen is the major element of chlorophyll, protein and amino acids and play an important role in wheat productivity (Khalil, 2008). Dwarfed wheat growth and lodging were recorded due to under-and over-application of nitrogen respectively than the optimum level (Hawkesford, 2014). Nitrogen enhances spike population and has a greater contribution in yield components (Maqsood et al., 2014), increased leaf area index and grain yield (Bashir et al., 2017). Research on synthetic nitrogen fertilizers depleted soil nitrogen (Mulvaney et al., 2009) showed that inorganic N fertilizers mainly in ammonium form reduced the mass of organic carbon due to more consumption through microorganisms and decreased total nitrogen within the soil because of more nitrogen uptake by the grains. Chaudhary et al. (2009) have reported that high cost, degradation of soil and environmental pollution are the major problems of commercial fertilizer applied alone.

Organic source of N not only boosted wheat production but also increased organic matter of the soil (Maltas et al., 2013), more nutrient bio-availability (Dikinya and Mufwanzala, 2010) and resultant higher yield (Naderi and Ghadiri, 2010). Synthetic N applied along with poultry manure not only enhance microorganism’s activity in the soil but also increase the availability of potash and phosphorus and brings lesser nitrogen loss (Zhang et al., 2016), develop protein content and economic yield (Ahmed et al., 2017) as compared to single inorganic fertilizer application. A field trial on nitrogen mineralization (Abbasi and Khaliq, 2016) pointed out that synthetic N along with poultry manure addition in soil converted unavailable N to available form of N. Due to better nutritional status, farm yard manure might be replaced with poultry manure (Abbas et al., 2012).

Split application of inorganic N resulted in lesser nitrogen loss and better growth (Shahzad and Akmal, 2017), more grains protein (Abedi et al., 2011) and target yield (Jan et al., 2011). Higher protein content and 1000 grains weight have been achieved through application of N in split doses (Amanullah and Shah, 2010). Higher grain filling rate, grain nitrogen content, 1000 grain weight and economic yield were recorded through split application of fertilizer nitrogen (Yildirim et al., 2016). Addition of nitrogen fertilizer at tillering or in three split doses (tillering, booting and anthesis stages) enhances protein content and does not decrease economic yield of wheat (Ferrari et al., 2016).

In the current research, a field experiment was carried out to evaluate the best combination of fertilizer nitrogen (amount and time) and poultry manure for better crop growth and higher productivity in wheat.

Materials and Methods

Fertilizer application treatments distribution

The experiment contained two factors i.e. Factor A consisted of Fertilizer N and Poultry manure (PM) and the various treatment combinations were (75, 100 and 125 kg N per ha without PM or with 4 tonnes (t) PM per ha) and were allotted to main plot. Where, factor B comprised of fertilizers N application time (Full at land preparation, full at boot stage and 50% at land preparation and 50% at boot stage) were allotted to subplot. Phosphorus was applied at the rate of 90 kg/ ha in the form of DAP. Urea was used as an inorganic and poultry manure as an organic source of N. Full PM was incorporated in to the soil at the time of land preparation while N was added as planned. Total N was determined in soil (0.5 mg/ kg) and PM (2.93 mg/ kg) samples before planting with Kjeldhal apparatus.

Experimental model and data collection

The trial was carried out in randomized complete block (RCB) design with split plot arrangement replicated four times. A subplot size of 4 x 2 m having eight rows, 25 cm apart with 4 m length. The crop was sown on 13th November 2010. Data was collected on productive tillers per sq. meter, leaf area, grains per spike, 1000 grain weight, biological yield, grain yield and harvest index.

Productive tillers per sq. meter was at three randomly selected places in one-meter row length recorded from the following formula:

Productive tillers at three randomly selected places in one-meter row length =

Productive tillers counted

------------------------------

R-R x number of rows x row length

Leaf area was calculated as:

Leaf area =leaf L × leaf W × 0.65

 

Where;

L and W are length and width of all the leaves from five randomly selected tillers taken with simple meter rod and 0.65 is leaf area factor.

Biological yield was converted in to kg ha-1 by using formula:

Biological yield of harvested rows

= -------------------------------- x 10000

R-R x rows harvested x row length

 

Grain yield (kg ha-1) was determined as:

Grain yield of harvested rows

= -------------------------------- x 10000

R-R x rows harvested x row length

 

Harvest index for each treatment was measured as:

Grain yield

= ------------------x 100

Biological yield

 

Irrigation plan

Irrigations were applied at seedling, booting and grain development stages, while no irrigation was given at tillering and heading stages due to high rain fall and low temperature in the months of December, 2010 and February, 2011 (Figure 1). Two weeding were done manually and chemical bactril super was used for controlling broad leaf weeds like fumaria indica, mellilotus parviflora etc.

Source: Pakistan Forest Institute, Peshawar, Khyber Pakhtukhwa.

Statistical data analysis

Fertilizer N amount, poultry manure and Fertilizer N application timing along with their interactive responses (N × PM, N × M, PM × M and N × PM × M) were compared through MS EXCEL software. The data were subjected to analysis of variance (Jan et al., 2009). Least Significant Differences test was used to compare means among different treatments at α= 0.05 level of probability when F test was significant.

Results and Discussion

Productive tillers m-2

Synthetic N and, poultry manure and application time of synthetic N significantly affected productive tillers m-2. Similarly, all the interactive responses were found significant (Table 1). Less productive tillers per square m were recorded for N applications i.e. 75 kg ha-1 (222) and 125 kg ha-1 (227) as compared to 100 kg ha-1 (238). This may be due to insufficient as well as excessive quantities of N had a negative impact on the crop growth and yield of wheat (Khalil et al., 2011). Greater number of productive tillers m-2 (235) was observed through poultry manure Incorporation in comparison to control plots (223). Plenty of moisture and nutrients availability in poultry manure incorporated plots (Abbasi and Khaliq, 2016) may have provided favorable environment for wheat growth. Application of inorganic N produced more productive tillers m-2 (239) than full at sowing (220) and/or at boot stage (229). This may be associated with N availability in sufficient amount at suitable crop stage (Shahzad and Akmal, 2017), could enhance number of productive tillers. Interaction between N and PM indicated that in PM control plots, increased N rate enhanced productive tillers linearly, while in PM incorporated plots productive tillers showed a quadratic trend (Figure 2). Similar response to N and PM through interaction (N x PM) was also proved in all the parameters determined in this field trial (Figure 5, 6, 7, 8, 11 and 14). N x M interaction clarified that boosting N rate at either application time, brought quadratic response with respect to productive tillers m-2 (Figure 3). Interactive response of PM and M, regardless of application time of N and increasing the PM level, resulted in linear improvement in the number of productive tillers (Figure 4).

Leaf area

Data related to leaf area indicated that fertilizer N, poultry manure and time of fertilizer N had significant effects (Table 1). N x PM was found significant, whereas other interactive responses were not significant for leaf area. The application of 100 kg N ha-1 enhanced leaf area (27.87 cm2) in comparison to 75 kg N ha-1 (25.12 cm2) and was not different from 125 kg N ha-1 (26.68 cm2). Higher chlorophyll content in response to adequate N (Bashir et al., 2017) may increase leaf area. Maximum leaf area (27.42 cm2) was recorded through poultry manure fertilization as opposed to non-fertilized plots (25.70 cm2). This may be correlated with best utilization of nutrients released through the decomposition of poultry manure (Ahmed et al., 2017), which may enhance leaf area. Addition of synthetic N in split doses and full at boot stage resulted in increased leaf area (27.90 and 27.16 cm2), respectively in comparison to full N application at land preparation (24.62 cm2). This is in contradiction with Yahya et al. (2008), who found that more nitrogen loss (gaseous form) at the end of vegetative stage that may cause reduction in leaf area.

Table 1: Productive tillers m-2, leaf area, grains spike-1 and 1000 grain weight of wheat as affected by Fertilizer-N, poultry manure and Fertilizer-N application time.

Treatments	Parameters
Fertilizer-N (kg ha-1)	Productive tillers m-2	Leaf area (cm2)	Grains spike-1	1000-grain weight (g)
75	222 c	25.12 b	40 b	45.01 c
100	238 a	27.87 a	42 a	48.38 a
125	227 b	26.68 ab	41 ab	46.57 b
LSD 0.05	3.85	1.36	1.23	1.07
Poultry manure (PM)(t ha-1)
0	223 b	25.70 b	40 b	45.64 b
4	235 a	27.42 a	42 a	47.66 a
Significance	**	*	**	*
Time of N application (M)
Full at sowing	220 c	24.62 b	40 b	45.10 b
Full at boot stage	229 b	27.16 a	40 b	46.00 b
½ at sowing + ½ at boot	239 a	27.90 a	43 a	48.85 a
LSD 0.05	3.51	1.12	1.34	1.35
Interactions	P-values
N x PM	0.00	0.01	0.01	0.00
N x M	0.01	0.86	0.86	0.20
PM x M	0.02	0.40	0.90	0.18
N x PM x M	0.00	0.06	0.32	0.58

**Significant at 1% level of probability

Grains per spike

ANOVA for grains per spike revealed that fertilizer N, poultry manure and application time of fertilizer N had significant effects. All interactions were non-significant except N x PM (Table 1). More grains per spike (42) were gained from 100 kg N/ ha application than N rate of 75 kg per ha (40), but was not statistically different from 125 kg ha-1 (41). These results are in line with Khalil et al. (2011) who reported that sufficient nitrogen may have favorable effects on number and filling of grains. The plots where no PM was used, lesser grains spike-1 (40) were recorded than PM used plots (42). This may be due to prolong nutrients availability through the whole life cycle of wheat (Shah et al., 2010), which may have enhanced the number of grains. Synthetic N added in split doses resulted greater quantity of grains per spike (43) where lesser from full applications either at planting (40) or boot stage (40). This response may be related with more nutrients available throughout growing season of the plant growth (Yildirim et al., 2016), which may bring vigorous growth and more grains.

1000 grains weight

Statistical analysis of 1000 grain mass showed that inorganic N, poultry manure and time of inorganic N had significant effects. Only the interaction (N x PM) was significant while the others were non-significant (Table 1). Addition of 100 kg N per ha resulted in heavier grains (48.38 g) than nitrogen levels of 75 kg/ ha (45.01 g) and 125 kg/ ha (46.57 g). Similar findings obtained by Maqsood et al. (2014) who recorded greater assimilate translocation from leaves and stem to grains in response to proper nitrogen level. Higher thousand grains weight (47.66 g) was gained from poultry manure addition than plots having no poultry manure (45.64 g). Improvement in water and nutrient holding capacity due to poultry manure incorporation (Ahmed et al., 2017), could produce heavier grains. Split application of inorganic N produced heavier grains (48.85 g) than 100% at sowing (45.10g) and 100% at boot stage (46 g). This may be related with more nitrogen accessibility and decrease in losses due to leaching etc. (Yildirim et al., 2016), which may have enhanced the weight of grains.

Biological yieldx

Inorganic N Level, poultry manure and application time of N significantly affected biological yield (Table 2). All interactions were significant for biological yield of wheat. Higher biomass weight (7244 kg ha-1) was recorded in treatments involving addition of 100 kg N ha-1 as compared to lowest nitrogen rate (6594 kg ha-1) and highest one (6995 kg ha-1). Adequate nitrogen rate than lower and over doses may produce more productive tillers per unit area (Khalil et al., 2011), which may improve the biomass production. Poultry manure control plots gave lower biological yield (6747 kg ha-1) than poultry manure applied plots (7141 kg ha-1). The variation in biomass production may be due to more moisture and nutrients available during whole season (Abbas et al., 2012). Split dose application of synthetic fertilizer N boosted biological yield (7147 kg ha-1) than whole at planting (6686 kg ha-1), but was not statistically different to whole at boot stage (6999 kg ha-1). This finding may be associated with greater availability of nitrogen in critical stages of wheat growth (Shahzad and Akmal, 2017), thus higher biological yield may be acquired. Interaction (N x M) showed that biomass weight was boosted in linear trend by increasing N rate used as full at sowing, while full N at boot and/or in split doses indicated a quadratic response (Figure 9). Regardless of M, when PM was incorporated, enhanced biomass weight linearly (Figure 10).

Grain yieldy

Grain yield was significantly affected by synthetic N rate and timings and poultry manure. All of the interactions (N x PM, N x M, PM x M and N x PM x M) proved significant for grain yield (Table 2). The addition of 100 kg N ha-1 resulted in greater grain yield (2644 kg ha-1) than other two nitrogen levels ha-1 i.e. 125 (2510 kg ha-1) and 75 (2197 kg ha-1). This is possibly due to enough nitrogen accessible to the crop (Bashir et al., 2017), may result better growth and promoted leaf area. Using poultry manure brought higher grain yield (2639 kg ha-1) than plots where no poultry manure was added (2262 kg ha-1). More nutrients availability and lesser N losses or more nitrogen uptake during life cycle of crop (Zhang et al., 2016), could bring higher grain yield. Concerning dose and times of inorganic N application, better performance (2701 kg ha-1) was recorded through split application than whole both at boot stage (2449 kg ha-1) and at land preparation (2201 kg ha-1). Nitrogen availability at the correct time and minimum N loss (Jan et al., 2011), may enhance grain yield. Enhancing N levels boosted grain yield linearly when applied in split doses, while full applications either at planting or boot stage presented a quadratic response (Figure 12). A linear trend was observed from control to PM incorporation when N applied in any amount at any growth stage (Figure 13).

Table 2: Biological yield, grain yield and harvest index of wheat as affected by fertilizer-N, poultry manure and fertilizer-N application time.

Treatments
Fertilizer-N (kg ha-1)	Biological yield (kg ha-1)	Grain yield (kg ha-1)	Harvest index (%)
75	6594 c	2197 c	33.25 b
100	7244 a	2644 a	36.30 a
125	6995 b	2510 b	36.02 a
LSD 0.05	192.62	127.40	2.10
Poultry manure (PM)(t ha-1)
0	6747 b	2262 b	33.32 b
4	7141 a	2639 a	37.06 a
Significance	**	**	**
Time of N application (M)
Full at sowing	6686 b	2201 c	32.90 b
Full at boot stage	6999 ab	2449 b	34.85 b
½ at sowing + ½ at boot	7147 a	2701 a	37.82 a
LSD 0.05	160.86	132.70	2.08
Interactions
N x PM	0.00	0.00	0.00
N x M	0.00	0.01	0.02
PM x M	0.04	0.03	0.01
N x PM x M	0.00	0.02	0.01

**Significant at 1% level of probability.

Harvest indexz

The Table 2 shows that fertilizer N, poultry manure and time of fertilizer N significantly affected harvest index. Similarly, the overall interactions were also significant. Higher harvest indices (36.30 and 36.02 %) were recorded through application of 100 and 125 kg N ha-1, respectively as compared to 75 kg N ha-1 (33.25 %). Improvement in grain yield relative to biomass (Hammad et al., 2011), may have enhanced harvest index of the crop. Maximum harvest index (37.06 %) was obtained from N + PM application whereas lesser from without poultry manure (33.32 %). Prolonged availability of water and essential elements may result bumper growth and enhanced leaf area (Kabesh et al., 2009), thus boosting harvest index of wheat. Application of inorganic nitrogen as full at planting or at boot stage produced lower harvest indices (32.90 and 34.85 %) respectively than 50% at planting and 50% at boot stage (37.82 %). This result is similar to more development in economic yield in comparison to biomass production (Yildirim et al., 2016) so that higher harvest indices means may be obtained. Interaction (N x M) revealed that through either application times, quadratic relationship was observed between N levels and harvest index except for split application, which presented linear enhancement (Figure 15). Whole N applied at sowing and in split doses increased the harvest index linearly with PM incorporation except full N at boot stage, which resulted in decline of harvest index (Figure 16).

Conclusions and Recommendation

It is concluded from the research work that application of 100 kg N ha-1 applied as ½ at land preparation and ½ at boot stage along with poultry manure incorporation performed better regarding growth, yield and yield components of wheat and incorporation of optimum nitrogen level in split doses with poultry manure could be recommended for higher wheat productivity.

Author’s Contribution

Tanzim Ullah Khan: Data collection, conducting experiment and wrote the paper.

Mohammad Tariq Jan: Conceived the idea and technical support.

Ahmad Khan: Technical input at every step.

Gulzar Ahmad: Incoporated reviewers comments.

Muhammad Ishaq: Data entry and statistical analysis.

Khilwat Afridi: Overall management of the article.

Murad Ali: Analysis of soil and poultry manure samples.

Muhammad Adeel Qureshi: Incoporated reviewers comments.

Imtiaz Ahmad: Review of paper.

Muhammad Saeed: Helped in references.

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