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KWAME NKRUMAH UNIVERSITY OF SCIENCE AND TECHNOLOGY
COLLEGE OF AGRICULTURE AND NATURAL RESOURCE
FACULTY OF AGRICULTURE
DEPARTMENT OF HORTICULTURE
EFFECTS OF OIL PALM BUNCH ASH AND POULTRY MANURE INDEPENDENTLY ON THE
GROWTH AND YIELD OF FRENCH BEANS (Phaseolus vulgaris L.)
A DISERTATION SUBMITTED TO THE DEPARTMENT OF HORTICULTURE, FACULTY OF
AGRICULTURE, COLLEGE OF AGRICULTURE AND NATURAL RESOURCES OF THE
KWAME NKRUMAH UNIVERSITY OF SCIENCE AND TECHNOLOGY, IN PARTIAL
FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF BACHELOR OF SCIENCE
DEGREE IN AGRICULTURE
BY
FELIX KING MENSAH
MAY, 2013
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DECLARATION
I declare that this thesis submitted by me for BSc. degree in Agriculture at the Kwame Nkrumah
University of Science and Technology in Kumasi, Ghana, is my own independent work. References to
other peoples work have been duly acknowledged and the work has not been presented elsewhere for
any degree.
FELIX KING MENSAH------------------------------ ------------------------------
STUDENT Signature DATE
Dr BEN K. BANFUL --------------------------------- ------------------------------
SUPERVISOR Signature DATE
Dr BEN K. BANFUL --------------------------------- -----------------------------
HEAD OF DEPARTMENT Signature DATE
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DEDICATION
This thesis is lovingly dedicated to:
The glory of my Lord Jesus Christ who has blessed me beyond anything I could ever have imagined
and who has loved me beyond my comprehension.
My parents: Mr Bright Mensah and Mrs Mary Mensah. Their effort throughout my life has been out of
this world.
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ACKNOWLEDGEMENTS
I wish to express my sincere thanks and appreciation to my supervisor and Senior Lecturer Dr Ben K.
Banful, for his supervision during my research.
I express my sincere gratitude to Mr Shalom Ado-Danso of Forest Research Institute in Kumasi for his
numerous assistance and help in solving the problems of literature concerning the treatments used for
the research.
I also wish thank the entire staff of the Department of Horticulture for their motivation and support.
I am grateful to my family and friends for their continuous prayers and encouragement during my
studies. Finally, many thanks to all those who assisted me during the entire process: from the research
to thesis development.
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ABSTRACT
A field experiment entitled Effects of oil palm bunch ash and poultry manure independently on the
growth and yield of French beans (Phaseolus vulgaris L.) was carried out during December, 2012 to
February, 2013, on the Research fields at the Department of Horticulture of the Kwame Nkrumah
University of Science and Technology, Kumasi. The soil texture of the experimental site was clay and
was low in available nitrogen (kg ha-1) and phosphorus (kg ha-1) and high in available potassium (kg
ha-1). There were three treatments; oil palm bunch ash, poultry manure and an inorganic fertiliser as
control (NPK 15:15:15). The experiment was laid out in a RCBD with three replications.
Results of the study showed that the application of Palm bunch ash significantly (P< 0.05) increased
soil pH and exchangeable cations but not significant with Poultry manure application. Growth of
French beans, except days to 50% anthesis which was significantly(P< 0.05) lower (28 and 29 DAS)
with Palm bunch ash impose, did not vary significantly (P>0.05) among treatments. No significant
difference was recorded on yield of French beans with respect to treatments imposed and recorded
597.32 kg ha-1
with poultry manure, palm bunch ash, 681.62 kg ha-1
and NPK, 477.82 kg ha-1
per
treatment.
Total nitrogen, phosphorus, potassium and magnesium uptake increased with the crops growth.
The study therefore recommends that French beans production as well as other crops can be cultivated
using these organic wastes as fertiliser substitutes and soil amendments.
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Table of Content
CHAPTER ONE ...................................................................................................................................................... 1
INTRODUCTION ............................................................................................................................................... 1
CHAPTER TWO ..................................................................................................................................................... 3
LITERATURE REVIEW .................................................................................................................................... 3
2.1 EFFECTS OF FERTILISERS ON THE GROWTH AND YIELD OF FRENCH BEANS.............................. 3
2.1.1 Effects of NPK on growth parameters ........................................................................................................ 3
2.1.3 Effects of oil palm bunch ash on growth and yield parameters .................................................................. 6
2.1.4 Effects of poultry manure on growth and yield parameters........................................................................ 7
CHAPTER THREE ....................................................................................................................................................... 8
MATERIALS AND METHODS ........................................................................................................................ 8
3.1 SOIL CHARACTERISTICS OF EXPERIMENTAL SITE .......................................................................... 8
3.2 CLIMATIC CONDITIONS .......................................................................................................................... 8
3.4 EXPERIMENTAL DETAILS ....................................................................................................................... 9
3.4.1 Experimental design, treatments and analysis of treatments ...................................................................... 9
3.5 CULTURAL PRACTICES ........................................................................................................................... 9
3.5.1 Land preparation ......................................................................................................................................... 9
3.5.2 Seeds and seed sowing ............................................................................................................................... 9
3.5.3 Fertiliser application ................................................................................................................................. 10
3.5.4 Crop management ..................................................................................................................................... 10
3.6 COLLECTION OF DATA .......................................................................................................................... 10
3.6.1 Growth parameters ................................................................................................................................... 10
3.6.1.1 Plant height ............................................................................................................................................ 10
3.6.1.2 Number of branches per plant ............................................................................................................... 11
3.6.1.3 Days to fifty percent flowering .............................................................................................................. 11
3.6.2 Yield components ..................................................................................................................................... 11
3.6.2.1 Number of pods per plant ...................................................................................................................... 11
3.6.2.2 Pod weight ............................................................................................................................................. 11
3.6.2.3 Yield per sample area ............................................................................................................................ 11
3.6.2.4 Total yield per hectare ........................................................................................................................... 11
3.7 STATISTICAL ANALYSIS ....................................................................................................................... 12
CHAPTER FOUR ................................................................................................................................................. 13
EXPERIMENTAL RESULTS .......................................................................................................................... 13
4.1 GROWTH PARAMETERS ........................................................................................................................ 23
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4.1.1 Plant height and number of branches ....................................................................................................... 13
4.1.2 Days to 50% flowering ............................................................................................................................. 13
4.2 YIELD COMPONENTS AND YIELD ...................................................................................................... 14
4.2.1 Number of pods per plant ......................................................................................................................... 14
4.2.2 Pod weight ................................................................................................................................................ 14
4.2.3 Total yield per hectare .............................................................................................................................. 14
CHAPTER FIVE ................................................................................................................................................... 15
DISCUSSION.................................................................................................................................................... 15
5.1 WEATHER CONDITIONS AND CROP PERFORMANCE ..................................................................... 15
5.2 DISEASES AND PESTS ............................................................................................................................ 16
5.3 EFFECT OF PALM BUNCH ASH (PBA) ................................................................................................. 16
5.4 EFFECT OF POULTRY MANURE (PM) ................................................................................................. 17
CHAPTER SIX ..................................................................................................................................................... 18
SUMMARY AND CONCLUSIONS ................................................................................................................ 18
RECOMMENDATIONS .................................................................................................................................. 19
REFERENCES ...................................................................................................................................................... 20
APPENDICES ....................................................................................................................................................... 26
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LIST OF TABLES
Table 1: Effects of treatment on days to 50 % flowering in French beans14
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LIST OF APPENDICES
Appendix I: Soil samples analysed from the experimental site before the experiment.26
Appendix II: Treatment samples analysed.26
Appendix III: Soil samples analysed from the experimental site treatment-wise after
harvest.27
Appendix IV: Monthly meteorological data for the experimental period (December, 2012 to February,
2013)..................27
Appendix V: ANOVA tables....27
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CHAPTER ONE
INTRODUCTION
French bean (Phaseolus vulgaris L.) is a short duration nontraditional grain legume gaining
utilisation in many homes in Ghana. French beans are known by various names viz., haricot bean, field
bean, kidney bean, snap bean, pole bean etc. It is an important vegetable grown both for tender pods
which has a rich source of crude protein (21.25%), fat (1.7%) and carbohydrates (70%). Besides, it
contains 0.16 mg iron, 1.76 mg calcium and 3.43 mg zinc per 100 g of edible part (Jasvinder Kaur and
Mehta, 1994).
French beans being native to South and Central America probably Mexico, is being widely cultivated
in tropical, sub-tropical and temperate regions. Its cultivation in Ghana, however, is scattered across
the regions.It is a major export vegetable crop in Kenya and a potential income earner to small scale
farmers (out growers).
Unlike other pulses, French beans is inefficient in symbiotic nitrogen fixation (Ali and Lal, 1992) as it
lacks nodulation due to the absence of NOD gene regulator (Kushwaha, 1994) even with native
Rhizobia and commercially produced cultures. Hence, the nitrogen requirement of the crop must be
met through the application of nitrogen fertilisers if its yield potential has to be exploited.
Empty fruit bunch (EFB) is one of the major waste products generated from processing fresh fruit
bunch (FFB) in palm fruit processing mills. About 22% of FFB processed into oil end up as EFB (Lim
and Zaharah, 2000). Currently, Ghana produces about 120,000 metric tons of FFB annually (FAO,
2011) which, when processed into oil, generate a good amount of EFB annually.
In the large industrial estates, EFB is incinerated in the mills as a means of providing energy for the
boilers in FFB sterilization. However, the small-scale mills which process about 60% of the total FFB
produced in the country (Opoku and Asante, 2008) burn the EFB as a means of disposing of them,
resulting in heaps of ash dotted around small-scale mills in the major oil palm producing areas in
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Ghana. There is currently no large-scale use for palm bunch ash in Ghana, although it could be used
for the manufacture of local soap due to its high potassium content. The palm bunch ash (PBA)
produced by burning EFB, which constitutes about 6.5% by weight of the EFB, contains 3040% K2O
(Lim and Zaharah, 2000) and could thus be used as source of potassium fertilizer.
Moreover, the rising cost of inorganic fertilizers coupled with their inability to condition the soil has
directed attention to organic manures in recent times. Poultry manure, an organic manure, abounds in
major areas in Ghana.
The disposal of the manure has become a big problem. However, some farmers are aware of the
beneficial effects of poultry manure and its release of nutrients for a good response in plant growth.
This notwithstanding, there seems to be little use of poultry manure nationwide, due mainly to the little
knowledge available on the effects of the manure on crops.
The present study was therefore undertaken to determine the independent effects of poultry manure
and oil palm bunch ash on growth and yield of French beans.
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CHAPTER TWO
LITERATURE REVIEW
2.1 EFFECTS OF FERTILISERS ON THE GROWTH AND YIELD
OF FRENCH BEANS
The average yield potential of French bean under both rain-fed and irrigated condition is high. One of
the agronomic approaches is the efficient use of fertilizer, particularly N, P and K, which plays an
important role in enhancing the production and productivity of the crop by increasing cell division and
multiplication. Nitrogen nutrition is also required for improvement of growth parameters through
efficient metabolic activity and increased rate of photosynthesis. Phosphorus is a constituent of
nucleoprotein and it helps for increased cell division and expansion of cells resulting into higher dry
matter accumulation in reproductive parts. It also stimulates early root growth and development,
encourages fruiting, seed setting and hastens maturity of plants. Potassium plays a significant role in
increasing the crop yield and extra balancing effect on both nitrogen and phosphorus. It is essential for
cell organization and structure of cell walls. It enhances plants ability to resist diseases, cold and other
adverse conditions.
2.1.1 Effects of NPK on growth parameters
Studies by Singh and Singh (2000) showed an increase in plant height of French bean due to increase
in Nitrogen fertilization from zero to 120 kg N/ha. Patil (2003) also acknowledged increase in plant
height (92.2 cm) at a fertilizer application of 25:112:60 kg NPK per hectare over control (no NPK)
(84.7 cm and 4.3, respectively) in cluster bean.
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Kumar et al. (2004) noticed significant increase in plant height (21.68 cm) with fertilizer level of
120:60:45 kg NPK per hectare which was followed by 80:40:30 kg NPK per hectare and it was
significantly less (17.00 cm and 5.9, respectively) in control (no fertilizer) in the French bean crop.
A field investigation conducted by Rana et al. (2003) revealed that application of K2O up to 30 kg ha-
1significantly increased plant height of French bean. Veeresh (2003) also reported significant increase
in plant height (37.77 cm) and number of branches of French bean during up to 75 kg P2O5ha-1
application.
Delayed flowering in French beans (flowering after 29, 32 and 33 days, respectively) was observed
due to increased N application (40, 80 and 120 kg ha-1
) (Veeresh, 2003).
Phosphorus supplement to crop at 0, 20, 40 and 60 kg P2O5 ha-1
recorded 71.0, 70.66, 70.44 and 70.18
days, respectively to first flowering (Tewari and Singh, 2000) whilst increased P fertilization (25, 50
and 75 kg ha-1
) significantly reduced number of days to 50 per cent flowering (34, 31 and 29 days,
respectively) of French bean (Veeresh, 2003).
2.1.2 Effects of NPK on yield parameters
Nitrogen fertilization up to 120 kg ha-1
in French bean increased number of fruits per plant (Tewari and
Singh, 2000; Singh and Singh, 2000). However, the difference between 120 kg and 80 kg N ha-1
was
not significant (Singh and Singh, 2000).
In addition, Singh and Singh (2000) and Tewari and Singh (2000) reported significant increase in
number of pods per plant due to increased P fertilization between 60 and 120 kg P2O5ha-1
.
Furthermore, Veeresh (2003) observed significantly higher number of fruits per plant (11) of French
bean with 75 kg P2O5ha-1
application.
Higher number of pods per plant was recorded in the treatment receiving 120 kg N ha-1
(Prajapatiet al.
(2003). Similar results were obtained by Veeresh (2003) and Behura et al. (2006) while pod number
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per plant in French bean increased significantly up to the highest level of nitrogen ( thus 180 kg ha-1
)
(Rajesh Singh et al., 2006).
Rana et al. (2003) also stated that the number of fruits per plant increased significantly up to 30 kg
K2Oha-1
application.
Number of seeds per pod increased significantly up to 120 kg N ha-1
(Dhanjal et al., 2001). Similar
results were obtained by Prajapati et al. (2003), Veeresh (2003) and Behura et al. (2006) while Rajesh
Singh et al. (2006) reported that application of 180 kg N ha-1
resulted in higher number of seeds per
pod which significantly increased the pod length.
According to Veeresh (2003), higher number of grains per pod (5.12) of French bean was observed
due to increased rate of P application up to 75 kg P2O5ha-1
thereby increasing the length of the bean
pod.
Considering pod weight, linear increase in grain weight per plant from 11.2 to 19.2g (during 1991-
1992) and 12.1 to 20.0g (during 1992-93) was observed from zero to 120 kg N ha-1
(Rana and Singh,
1998 and Tewari and Singh, 2000).
For total yield per hectare, Nitrogen application increased the grain yield of French bean. Grain yield
was increased due to increasing levels of N up to 100 kg ha-1
.
According to Rana and Singh (1998) mean increases in seed yield with 120 kg N ha-1
over zero to 40
and 80 kg N ha-1
which was 66.6, 21.7 and 7.0 per cent, respectively.
An observation by Singh and Singh (2000) observed improvement in yield and yield components with
increasing Nitrogen rate from zero to 120 kg ha-1
.Dhanjalet al. (2001) also reported improvement in
grain yield with increasing N rate; the yields with zero, 60 and 120 kg ha-1
were 6.52, 8.30 and 9.49 q
ha-1
, respectively. Veeresh (2003) recorded significantly higher grain yield (1917 kg ha-1
) of French
bean with 80 kg N application.
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Rajesh Singh et al. (2001) recorded linear significant increase in grain yield up to 240 kg N ha-1
(2091
kg ha-1
) over 80 and 160 kg ha-1
while Rajesh Singh et al. (2006) reported that nitrogen application
increased grain yield (2651 kg ha-1
) up to 180 kg N ha-1
.
Tewari and Singh (2000) reported significant increase in grain weight per plant with 60 kg P2O5ha-1
.
Veeresh (2003) observed significant increase in grain weight per plant (8.65 g) due to increased P
application up to 75 kg ha-1
.
Dwivedi et al. (2002), in their fertilizer application found that increased level of nutrition 40:60:40 kg
NPK per ha significantly increased the yield parameters like pod weight per plant, number of pods per
plant and seed yield per ha as against control (0 kg NPK).
Singh and Singh (2000) and Tewari and Singh (2000) also revealed significantly increased seed yield
due to incremental P application from75 to 100 kg P2O5ha-1
.
Tomar (2001) recorded that application of phosphorus influenced the seed yield significantly up to 60
kg P2O5ha-1
. Also, higher grain yield (2006 kg ha-1
) of French bean was observed due to increased rate
of P application up to 75 kg P2O5ha-1
(Veeresh, 2003).
2.1.3 Effects of oil palm bunch ash on growth and yield parameters
Though the utilization of oil palm bunch ash in crop production has little exploitation, few experiments
have been performed using it as a soil amendment material or applying it alongside inorganic fertiliser.
The highest increase in maize grain yield in both seasons was obtained at the application rate of 2 tons
ha1
PBA. This increase in maize grain yield as well as root yield of cassava has been reported by
several workers (Mbahet al, 2010; Awodunet al, 2007; Adekayode and Olojugba, 2010; Ojeniyi et al,
2010; Offor et al ,2010; Ezekiel et al ,2009).
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It was also found to increase nutrient supply to cassava and its yield significantly (Ezekiel et al, 2009a,
2009b,).
Ojeniyi et al (2006) also found that oil palm bunch ash supplied organic matter, N, P, Ca and Mg to
soil which caused an increased maize yield by 26% at an application rate of 4 t/ha.
2.1.4 Effects of poultry manure on growth and yield parameters
Mullens et al. (2002) revealed that poultry litter contains a considerable amount of organic matter due
to the manure and the bedding material. Litter can also have an impact on soil pH and liming due to
varying amounts of calcium carbonate in poultry feed. Poultry manure improved soil physical
properties significantly by reducing soil bulk density and temperature and increasing total porosity and
moisture content in Nigeria (Agbede et al., 2008).
An experiment conducted by Amanullah et al. (2007b) indicated that application of organic manure
yielded higher uptake of NPK than the control. The study also revealed that uptake of nutrient was
higher with Composted Poultry Manure. The added organic manure not only acted as a source of
nutrient but might have also influenced their availability.
In an experiment conducted by Zamil et al.(2004) the highest mustard seed yield (8.68 g pot-1
) was
obtained in cage system poultry manure at 20 t ha-1
which was statistically similar to chemical
fertilizer (8.49 g pot-1
). The lowest seed yield was obtained from the control. Cage system poultry
manure showed better performance in producing seed yield.
Ibeawuchi et al. (2006) reported that in a degraded soil of Nigeria, poultry manure application
increased the residual soil N, K, Ca, Mg and organic matter. The high organic matter with increase in
other soil chemical components is an indication that poultry manure has high potential of gradual
nutrient release to the soil that can help to improve the fertility of a degraded soil thereby sustaining
yield in a continuous cropping system.
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CHAPTER THREE
MATERIALS AND METHODS
A field experiment entitled Effects of oil palm bunch ash and poultry manure independently on the
growth and yield of French beans (Phaseolus vulgaris L.) was carried out during December to
February, 2012, on the Research field sat the Department of Horticulture of the Kwame Nkrumah
University of Science and Technology, Kumasi.
3.1 SOIL CHARACTERISTICS OF EXPERIMENTAL SITE
Soil of the experimental site was a black, well drained loamy soil. Random soil samples from four
different locations of the experimental site before the initiation of the experiment were collected from
a depth of 0-20cm and composite soil sample was analyzed for the chemical characteristics of
Nitrogen (N), Phosphorus (P), Potassium (K), Calcium (Ca), Magnesium (Mg) and soil pH. The soil
analysis was carried out at the Department of Crop and Soil Sciences, Kwame Nkrumah University of
Science and Technology (KNUST).The soil analysis was repeated after harvest. The same nutrients
were analysed.
3.2 CLIMATIC CONDITIONS
There was no rainfall received during the crop growth period. The maximum temperatures from
December 7th
2012 to February 5th
2013 are 33C, 36C and 36C respectively and the minimum
recorded temperatures are 27C, 32C and 34C for the experimentation period respectively.
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3.4 EXPERIMENTAL DETAILS
3.4.1 Experimental design, treatments and analysis of treatments
The experiment comprised of three treatments namely poultry manure, palm bunch ash and NPK
(15:15:15) as a control replicated three times. The treatment details were:
Treatment 1: Poultry manure at 9kg/plot
Treatment 2: Palm bunch ash at 2kg/plot
Treatment 3 (Absolute control): NPK (15:15:15) at 0.5kg/plot
The treatment samples wereanalysed for the chemical characteristics of Nitrogen (N), Phosphorus (P),
Potassium (K), Calcium (Ca), Magnesium (Mg) and soil pH and are presented in Appendix II. The
treatment analysis was carried out at the Department of Crop and Soil Sciences, Kwame Nkrumah
University of Science and Technology (KNUST).
3.5 CULTURAL PRACTICES
3.5.1 Land preparation
One deep ploughing and one harrowing were carried out to bring the soil to fine tilth. Before taking up
sowing, the field was leveled and the plots were laid out according to the experimental plan. The plot
size was 9m2at plant spacing of 0.60m X 0.60m.
3.5.2 Seeds and seed sowing
French bean (Contender) seeds was obtained from the AgriSeed Co. Ltd. were used for sowing. Seeds
were placed in a depth of 5 cm at a row spacing of 60 cm and plant to plant spacing of 60 cm. The
sowing was done on 7th December, 2012 at the rate of two seeds per hill. To maintain the desired plant
population gap filling was done within first fortnight of sowing.
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3.5.3 Fertiliser application
Poultry manure, palm bunch ash and NPK were applied as per the treatments. Fertilizers were applied
in a ring at 5 cm away from the plant.
3.5.4Crop management
Hoe weeding at fortnight intervals after sowing was done in order to keep the weeds under check. To
control the damage of piercing and sucking pests and as well as all insects a spray of Aceta Star 45 EC
was taken up at the rate of 2 ml per liter of water from 30 DAS and fortnightly. Shavit F71.5WP, a
broad spectrum fungicide, was also sprayed at 45 DAS to prevent fungal diseases. The crop was
harvested from 21st January to 5
th February, 2013 thus from 45 days after sowing to 60 days after
sowing. Six plants from each plot area were harvested as sample plants.
3.6 COLLECTION OF DATA
A sample consisting of six plants selected randomly were tagged from the plot area of each treatment
for recording various observations. The mean of the six plants was considered for further analysis. The
observations on various growth parameters were recorded at 18, 30, 45, 52 and 60 DAS. Yield
parameters were recorded at harvest.
3.6.1 Growth parameters
3.6.1.1 Plant height
The plant height was measured from the base of the plant to the base of the fully opened youngest
trifoliate leaf and expressed in centimeters (cm).
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3.6.1.2 Number of branches per plant
The number of branches on the tagged plants was counted and mean was recorded as number of
branches per plant.
3.6.1.3 Days to fifty percent flowering
The number of days taken from sowing to days of 50 per cent anthesis of the plants sampled.
3.6.2 Yield components
3.6.2.1 Number of pods per plant
Pods from the tagged plants were counted and average was recorded as number of pods per plant.
3.6.2.2 Pod weight
The pod weight of six plants was recorded and average was taken as pod weight per plant and
expressed in grams (g).
3.6.2.3 Yield per sample area
The pods harvested from the six tagged plants were carefully weighed on a balance and their average
was calculated and expressed as pod yield in grams (g) per sample area.
3.6.2.4 Total yield per hectare
The pods obtained from plots of all treatments replication-wise, thus, yield of the six tagged plants
harvested separately was used in calculating the total pod yield per hectare. The average pod yield was
computed and expressed in kilograms per hectare.
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3.7 STATISTICAL ANALYSIS
Data collected were analysed using GenStat statistical package to generate analysis of variance
(ANOVA) and means separated by LSD at 5%.
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CHAPTER FOUR
EXPERIMENTAL RESULTS
The field experiment was conducted to know the effects of oil palm bunch ash and poultry manure
independently on the growth and yield of French beans (Phaseolus vulgaris L.) Cv. Contender. The
results obtained from the above experiment are presented in this chapter.
4.1 GROWTH PARAMETERS
4.1.1 Plant height and number of branches
Plant height of French beans was not significantly influenced by the application of Palm Bunch Ash
and Poultry Manure at the various stages of the crop. Similarly, French beans number of branches
were not significantly influenced by the application of Palm Bunch Ash and Poultry Manure
treatments.
4.1.2 Days to 50% flowering
Application of Palm Bunch Ash significantly influenced the number of days to 50 % flowering in
French beans (28, 29 and 30 days) against the control. However no significant difference was recorded
between Poultry Manure and NPK (30 and 31 days).
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Table 1: Effects of treatment on days to 50 % flowering in French beans
TREATMENT
Fertiliser Days to 50 % flowering
NPK
30a
Palm Bunch Ash
29b
Poultry Manure
30a
Lsd. (%) 0.027
CV (%) 0.80
Values with the same letter are not significantly different
4.2 YIELD COMPONENTS AND YIELD
4.2.1 Number of pods per plant
Palm Bunch Ash and Poultry Manure did not significantly influence the number of pods per plant.
4.2.2 Pod weight
Pod weight (means) did not differ significantly with respect to Palm Bunch Ash and Poultry Manure.
4.2.3 Total yield per hectare
Palm Bunch Ash and Poultry Manure did not influence significantly the total yield of French beans as
compared to the control. Poultry Manure recorded 597.32 kg ha-1
, Palm Bunch Ash, 681.62 kg ha-1
and
NPK, 477.82 kg ha-1
.
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CHAPTER FIVE
DISCUSSION
The results obtained from the investigations on the Effects of oil palm bunch ash and poultry manure
independently on the growth and yield of French beans (Phaseolus vulgaris L.)are discussed in this
chapter under the following headings:
5.1 Weather conditions and crop performance
5.2Diseases and pests
5.3 Effect of Palm Bunch Ash (PBA)
5.4 Effect of Poultry Manure (PM)
5.1 WEATHER CONDITIONS AND CROP PERFORMANCE
Crop growth is the net result of the interplay of diverse metabolic activities taking place in different
parts of a plant during its growth and development. The synthesis, accumulation and translocation of
metabolites to the economic part are often influenced by environmental conditions thereby influencing
the yield potential of the crop.
The total rainfall received during the experimental period (2012, December to 2013 February) was
0.00 mm. The mean monthly maximum air temperature ranged from 36 C (February) to 33 C
(December) while the minimum temperature ranged from 24 C (February) to 21 C (December)
during the experimentation. The mean relative humidity was highest during December (82%) and the
lowest in February (75%). The crop might have experienced some amount of moisture stress during
the cropping season, temperature effects and other climatic factors that growth and yields were
affected.
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5.2 DISEASES AND PESTS
French bean, a crop leguminous crop, is highly preferred of livestock and insects as well. It is well
attacked by piercing and sucking insects usually of the Pyrrhocoridae (cotton stainer) family whiteflies
and aphids. They pierce the fleshy and usually growing vegetative parts of the crop and such out the
fluid from them. This results in wilting of the crop and stunted growth to some extent of survival.
This experiment was affected by the attack of these insects though they were controlled; their damage
was severe resulting in the insignificance of the growth parameters treatment-wise.
Viral diseases that affect French beans are many. These are known to have no cure but can be
controlled and are transmitted by insects and pests. Golden mosaic virus, spread by the whitefly insect
vector (Bemisia tabaci) was found on the experimental field though insect control was undertaken.
Curly top, a viral disease, transmitted by a leafhopper (Circulifer tenellus) also was identified on the
field.
These fatally affected the growth and yield of the crop by destroying photosynthetic organs like the
leaves, hence stunting growth and metabolic processes from the early stages of the crop growth.
5.3 EFFECT OF PALM BUNCH ASH (PBA)
Palm Bunch Ash constitute about 30-40% K2O (Nsiah-Adjei, 2012). Potassium stimulates nitrogenase
activity and greater partitioning of above ground nitrogen to seeds and thereby increases seed yield
(Thomas and Hungaria, 1998).
In the present investigation no significant difference was observed with the application of PBA with
respect to growth parameters. The non-significant effect of PBA might be due to its low Nitrogen as
well as Phosphorus contents.
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Days to 50% flowering was significantly affected by the application of PBA in that earlier flowering
was recorded. Potassium plays a major role in protein synthesis, improves water regime and increases
tolerance to drought. Phosphorus, which was of a good amount in PBA, affected the number of days to
flowering confirming the findings of Veeresh in 2003.
No significant differences were recorded with respect to yield parameters though PBA contained a
good amount of N, P, K, Mg and Ca as observed by Mbah et al, 2010; Awodun et al, 2007;
Adekayode and Olojugba, 2010; Ojeniyi et al, 2010; Offor et al ,2010; Ezekiel et al ,2009;Ojeniyiet al,
2006. This may be due to moisture stress, environmental factors such as high temperatures and the pest
and viral diseases which affected the crop from 30 DAS. The viral disease affected the leaves of the
crop hindering photosynthesis.
5.4 EFFECT OF POULTRY MANURE (PM)
Nitrogen plays an important role in the growth and yield of crops and is vital for the vegetative phase
and is important for the uptake of other nutrients. PM has good percentage of it. Therefore the
application of PM becomes ideal for exploiting the yield potential of French beans (Sushant et al.,
1999). Poultry manure was slightly acidic (6.02) and it altered the pH of the soil which was moderately
acidic.
PM did not affect the number of days to flowering significantly as it did according to the findings of
Veeresh, 2003.However significant differences were recorded on number of pods per plant at 45 DAS.
The no significant differences recorded with the application of poultry manure on the crop may as a
result be because of its gradual release of nutrients in the soil as recorded by Ibeawuchi et al., 2006.
Poultry manure recorded no significant difference in yield as against the control, NPK as confirmed by
Amanullah et al., in 2007b. This may be due to environmental conditions like high temperature, low
soil moisture and the viral attack on the crop curtailing most of the crops vital processes for growth
and reproduction.
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18
CHAPTER SIX
SUMMARY AND CONCLUSIONS
The field experiment results obtained from the investigations on the Effects of oil palm bunch ash and
poultry manure independently on the growth and yield of French beans (Phaseolus vulgaris L.) with
NPK 15:15:15 as control carried out on theResearch fields of the Department of Horticulture, Kwame
Nkrumah University of Science and Technology, Kumasi during December, 2012 to February 2013.
The experiment was laid out in the randomised complete block design with three treatments and three
replications. The salient results of the investigations are summarised below:
1. The plant height, number of branches per plant, days to 50 % flowering, number of pods per
plant, pod weight, yield per sample area and total yield per hectare were studied.
2. The treatments studied were Palm Bunch Ash and Poultry Manure with NPK as control.
3. The treatments imposed on the crop did not significantly affect the various parameters studied
of the crop to the majority due to certain factors that affected the crop during the experiment as
discussed.
4. Palm Bunch Ash and Poultry Manure are organics that releases their nutrients gradually and
hence final soil analysis treatment-wise reveals an improvement in the soil characteristics with
respect to pH and Ca contents but a reduction due to the crops massive uptake of the other
nutrients, major and minor, the other nutrients.
5. The objective for this experiment was achieved but with no significant difference among
results due to the effects of environmental and pests and diseases factors that affected the crop.
Good fertiliser substitutes and fertiliser supplements as well as soil amendment materials were
identified for crop production.
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19
RECOMMENDATIONS
There is scope for study the effects of the combination of Palm bunch ash and Poultry manure
on the growth and yield of French beans.
Any study or work conducted on French beans should tackle insect control from early crop
stages and irrigation should be a very important practise especially if during the dry periods of
the year.
There is scope for studies on French beans with different organic wastes such as cattle dung
manure.
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20
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APPENDICES
Appendix I: Soil samples analysed from the experimental site before the experiment
PARAMETER SAMPLE 1 SAMPLE 2 pH (1:2.5 Soil: Water
suspension)
5.53 5.39
Total N (%) 0.12 0.14
Available P (mg/kg) 212.28 273.92
Exchangeable cat ion
(cmol/kg)
Ca 7.20 7.00
Mg 0.80 0.80
K 0.71 0.99
Appendix II: Treatment samples analysed
PARAMETER PALM BUNCH ASH POULTRY MANURE
pH (1:2.5 Soil: Water
suspension)
7.90 6.02
Total N (%) 0.43 1.89
Available P (%) 0.70 1.09
Exchangeable cat ion
(cmol/kg)
Ca 3.12 2.35
Mg 3.46 1.77
K 3.77 4.71
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27
Appendix III: Soil samples analysed from the experimental site treatment-wise after harvest
PARAMETER PALM BUNCH
ASH
POULTRY
MANURE
NPK
pH (1:2.5 Soil: Water
suspension)
5.73 5.72 5.15
Total N (%) 0.21 0.15 0.11
Available P (mg/kg) 122.36 152.22 169.47
Exchangeable cat ion
(cmol/kg)
Ca 4.40 5.40 6.00
Mg 3.60 2.40 2.60
K 0.37 0.42 0.32
Appendix IV: Monthly meteorological data for the experimental period (December, 2012 to February,
2013)
MONTHS RAINFALL
(mm)
NUMBER OF
RAINY
DAYS
TEMPERATURE (C) RELATIVE
HUMIDITY
(%)
December
2012
-- -- 82
January
2013
-- -- 78
February
2013
-- -- 75
Appendix V: ANOVA tables
ANOVA for Plant Height at 18 DAS
Source of variation d.f. s.s. m.s. v.r. F pr.
REP stratum 2 4.365 2.183 1.60
REP.*Units* stratum
TREATMENT 2 0.130 0.065 0.05 0.954
Residual 4 5.465 1.366
Total 8 9.960
Grand mean: 17.89 CV: 6.5
Max. Min.
33 21
36
36
22
24
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28
ANOVA for Plant Height at 30 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 60.99 30.50 2.05 REP.*Units* stratum TREATMENT 2 29.02 14.51 0.98 0.451 Residual 4 59.40 14.85 Total 8 149.41 Grand mean: 30.0 CV: 12.8
ANOVA for Plant Height at 45 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 40.651 20.326 2.06 REP.*Units* stratum TREATMENT 2 8.097 4.048 0.41 0.688 Residual 4 39.410 9.852 Total 8 88.158 Grand mean: 37.6 CV: 8.4
ANOVA for Plant Height at 52 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 52.334 26.167 2.74 REP.*Units* stratum TREATMENT 2 17.041 8.521 0.89 0.478 Residual 4 38.198 9.549 Total 8 107.574 Grand mean 38.0 CV: 8.1
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29
ANOVA for Plant Height at 60 DAS Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 50.87 25.44 1.84 REP.*Units* stratum TREATMENT 2 47.00 23.50 1.70 0.292 Residual 4 55.20 13.80 Total 8 153.07 Grand mean: 37.6 CV: 9.9
ANOVA for Number of branches at 18 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.013924 0.006962 2.75 REP.*Units* stratum TREATMENT 2 0.001026 0.000513 0.20 0.825 Residual 4 0.010138 0.002534 Total 8 0.025088 Grand mean: 0.73 CV: 6.8
ANOVA for Number of branches at 30 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.011151 0.005576 1.08 REP.*Units* stratum TREATMENT 2 0.003300 0.001650 0.32 0.743 Residual 4 0.020590 0.005148 Total 8 0.035041 Grand mean: 1.05 CV: 6.8
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30
ANOVA for Number of branches at 45 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.002284 0.001142 0.98 REP.*Units* stratum TREATMENT 2 0.000119 0.000060 0.05 0.951 Residual 4 0.004667 0.001167 Total 8 0.007071
Grand mean: 1.17 CV: 2.9
ANOVA for Number of branches at 52 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.004403 0.002202 2.04 REP.*Units* stratum TREATMENT 2 0.000639 0.000320 0.30 0.758 Residual 4 0.004310 0.001078 Total 8 0.009353 Grand mean: 1.17 CV: 2.8
ANOVA for Number of branches at 60 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.004403 0.002202 2.04 REP.*Units* stratum TREATMENT 2 0.000639 0.000320 0.30 0.758 Residual 4 0.004310 0.001078 Total 8 0.009353 Grand mean: 1.17 CV: 2.8
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31
ANOVA for Number of days to 50 % flowering
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.0001496 0.0000748 0.53 REP.*Units* stratum TREATMENT 2 0.0010032 0.0005016 3.52 0.131 Residual 4 0.0005697 0.0001424 Total 8 0.0017225 Grand mean: 1.47 CV: 0.8
ANOVA for Number of pods per plant at 45 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.7864 0.3932 1.73 REP.*Units* stratum TREATMENT 2 2.0254 1.0127 4.46 0.096 Residual 4 0.9073 0.2268 Total 8 3.7191 Grand mean: 1.48 CV: 32.2
ANOVA for Number of pods per plant at 52 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 1.3778 0.6889 0.74 REP.*Units* stratum TREATMENT 2 1.9026 0.9513 1.02 0.437 Residual 4 3.7130 0.9283 Total 8 6.9934 Grand mean: 4.17 CV: 23.1
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32
ANOVA for Number of pods per plant at 60 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 0.459 0.230 0.17 REP.*Units* stratum TREATMENT 2 0.667 0.333 0.25 0.792 Residual 4 5.387 1.347 Total 8 6.513 Grand mean: 2.61 CV: 21.2
ANOVA for Pod weight at 45 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 17.07 8.54 0.56 REP.*Units* stratum TREATMENT 2 25.00 12.50 0.81 0.505 Residual 4 61.50 15.37 Total 8 103.57 Grand mean: 7.0 CV: 24.30
ANOVA for Pod weight at 52 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 35.55 17.78 1.01 REP.*Units* stratum TREATMENT 2 134.97 67.48 3.83 0.118 Residual 4 70.53 17.63 Total 8 241.05 Grand mean: 20.9 CV: 11.70
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33
ANOVA for Pod weight at 60 DAS
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 34.06 17.03 0.43 REP.*Units* stratum TREATMENT 2 16.79 8.40 0.21 0.817 Residual 4 158.26 39.57 Total 8 209.11 Grand mean: 14.3 CV: 16.60
ANOVA for Total yield per hectare
Source of variation d.f. s.s. m.s. v.r. F pr. REP stratum 2 3338. 1669. 0.56 REP.*Units* stratum TREATMENT 2 6991. 3496. 1.17 0.397 Residual 4 11917. 2979. Total 8 22246. Grand mean: 195.0 CV: 28.0