Agriculture means field cultivation. But agriculture has continued to grow and expand that it can now be broadly be defined as:
The art and science of crop and animal production
Agriculture as an art
Agriculture is referred to as an art because it involves the following:
Tilling of land
Construction of farm structures
Measuring of distances
Machine operations
Harvesting of crops
Feeding and handling of livestock
Marketing of agricultural produce
Agriculture as a science
Agriculture is referred to as a science because it involves the following:
Crop pathology: study of crop diseases
Entomology: study of insects and their control
Soil science:
Genetics: plant and breeding
Agricultural engineering
Branches of agriculture
Crop production
Livestock production
Soil science
Agricultural economics
Agricultural engineering
Crop production
This is the production of crop on cultivated land.
Crop production is divided into:
a) Field crops
These are crops grown on fairly large area of land. May be annual or perennial crops.
b) Horticultural crops
The growing of perishable crops. It involves the following:
i) Floriculture: growing of flowers
ii) Olericulture: growing of vegetables
ii) Pomoculture: growing of fruits
Livestock production
This is the rearing of all types of animals. It involves:
a)Pastoralism (mammalian livestock farming)
Rearing of farm animals on pastures eg cattle, goats, sheep etc
b) Aquaculture
Rearing of aquatic animals eg fish farming (pisciculture)
c) Apiculture: keeping of bees
d) Aviculture: keeping of poultry
Soil science
This is a branch of agriculture that provides knowledge how soil is formed, how it works to sustain life and how it can be kept alive through many years
Agricultural economics
This branch deals with the utilization of scarce resources in the production of agricultural products.
Agricultural engineering
This branch deals with the use and maintenance of farm tools, machinery and structures.
Roles of agriculture in the economy
Provision of food
Source of employment
Provision of foreign exchange
Source of raw materials to the industries
Provision of market for industrial goods
Source of money or capital
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FARMING SYSTEMS
This is how the farm and all the enterprises in it are organized. There are two main farming systems namely:
Extensive system
Intensive system
Extensive farming system
This is a farming system which involves the use of large tracts of land. Its characterized by:
Low capital investment
Low labour per unit area
Low yield per unit area
Intensive farming system
This is a system of farming which requires high capital and labour investment. Its characterized by:
High yield per unit area
Use of modern technology
High labour per unit area
High capital investment
N/B: Extensive and intensive farming systems can be practiced under:
a) Large scale farming
b) Small scale farming
a) Large scale farming
This involves the use of large tracts of land. Its features include:
Heavy capital investment
Use of skilled labour
High level of management
Products are for commercial purposes
Large tracts of land is used
Large scale farming can either be:
i) Plantation farming: growing of one type of crop (monoculture)
ii) Ranching: rearing of beef animals
b) Small scale farming
This is a type of farming which is practiced on small piece of land. The products are either for subsistence or commercial purposes.
Methods of farming
Pastoralism
Arable farming
Mixed farming
Shifting cultivation
Organic farming
Agro forestry
Pastoralism
This is the practice of rearing livestock on natural pasture can be:
Settled livestock farming
Nomadic Pastoralism
a) Nomadic Pastoralism
This is the practice of rearing livestock and moving with them from place to place in search of water and green pasture. Nomadic Pastoralism can only be practiced where:
Land is not a limiting factor
Land is community owned
Arable farming
This is the growing of crops on a cultivated land: can be,
Mono cropping
Mono culture
Mixed cropping
Inter cropping
a) Mono cropping
This is the growing of one type of crop per season. Its disadvantages include:
Cause soil erosion
Diseases spread easily
If the crop fails, the farmer suffers total loss
Leads to nutrient depletion in the soil
N/B: Mono cropping can be practiced under mono culture where only one crop is grown throughout as in plantation farming eg in Tea, Coffee plantations.
b) Mixed cropping
This is the practice of growing different crops on the same piece of land but on different plots or strips. Usually helps to control soil erosion.
c) Intercropping
This is the practice of growing different crops on the same piece of land per season.
Advantages of intercropping
If one crop fails, the farmer has the other crop to support him, ie does not suffer total loss
Helps to control soil erosion
If legumes are included, they will enrich the soil with nutrient
Also interrupts the spread of diseases
There is high yield per unit area of land
There is also proper utilization of land
Disadvantages of intercropping
Requires a lot of labour
Routine crop management practices difficult to carry out
Requires high capital investment
Mixed farming
This is the growing of crops and rearing of animals on the same piece of land.
Advantages of mixed farming
Animals benefit from crop residues /remains as food while crops benefit from animals wastes as manure
Gives farmers income throughout the year
Ensures proper utilization of labour and land throughout the year
In case one enterprise fails, the farmer will still depend on the enterprise
Disadvantages of mixed farming
Requires high initial capital investment
There is lack of specialization
Limited land area allowed for each enterprise
Requires a lot of labour
Shifting cultivation
This involves farming on a piece of land continually until its exhausted after which the farmer moves to a new fertile land. Shifting cultivation can be practiced where:
Land is abundant
Population is sparse
Land is communally owned
Low number of livestock units per area
Advantages of shifting cultivation
Low capital investment
No pests and diseases build up
Soil structure is regained
No land disputes as the land is owned communally
Disadvantages of shifting cultivation
Yield per unit area is low
A lot of time is wasted when the farmer shifts to new area and builds structure
Farmers have no incentive to develop and conserve water and soil
Cannot be practiced in areas where there is high population density
Organic farming
This is the growing of crops and rearing of animals without using agricultural chemicals. It can be practiced through:
Use of organic manures instead of artificial fertilizer
Use of medicinal plants instead of chemical
Mulching
Crop rotation, to control diseases
Importance of organic farming
Its environment friendly
Its cheap
Does not require special skills
Agro forestry
This is the growing of trees, crops and keeping of animals on the same piece of land.
Advantages of agro forestry
Trees help to conserve water and soil
High output per unit area
Helps to reduce soil erosion
Provides trees for building and fuel
FACTORS INFLUENCING AGRICULTURE
There are a number of factors which influence both crop and animal production, some of these factors include:
Human factors
Biotic factors
Climatic factors
Edaphic factors
HUMAN FACTORS
These are factors which are due to the behavior of human beings or how they do things and how they influence agriculture. These human factors are:
Level of education and technology
Health of the people
Economic conditions
Government policy
Transport and communications
Cultural beliefs and religion
Market forces
a) Level of education and technology
High level of education leads to:
Accuracy in applying inputs and assessing results
Helps in proper decision making and organization
Better problem solution
Better utilization of livestock feeds and fertilizers
Understanding of technical language used in agriculture
Development of skills for operating machines and their maintenance
Increase in efficiency and minimizes costs
b) Health of the people
Today the biggest threat to farming is the HIV/AIDS, ill health makes people do little or no work. The general effect of HIV/AIDS and ill health on agriculture includes:
Shortage of farm labour
Increase the cost of living through treatment, thereby lowering their purchasing power thus low demand for agricultural products
Low standards of living leads to lack of motivation to invest in agriculture, thus increasing poverty
Low food supply
A lot of funds used to control it, instead of being used to develop agriculture
c) State of the economy
Economic conditions which have affected agriculture include:
Collapse of cooperative societies which affected the sale of farm produce such as milk, sugar, cotton etc
Liberalization of the economy, which has led to dumping of cheap products from other countries, this has caused the drop in price of agricultural products leading to low income to farmers
N/B: Kenya can benefit from liberalization by:
Producing goods of high quality and selling them competitively
Diversification
d) Government policy
These are the laws which are put in place by the government that govern the production, marketing and distribution of agricultural products. The policies that the government can put in place which can encourage the agricultural production include:
Heavy taxation of imports to prevent dumping of cheap goods into the local market
Subsidizing the growing of local crops thus making them affordable to farmers
Enact policies to enforce the production of high quality products
Put in place, policies aimed at conservation of natural resources in order to sustain agriculture
Stepping up disease and pest control eg through quarantine, vaccination etc
e) Transport and communication
Transport and communication plays an important role in conveying agricultural products
Railway lines are goods for transporting bulky goods to long distances
Airways are also efficient for air lifting horticultural products
Weather roads are necessary to transport farm produce to factories
N/B: proper transport and communication therefore will promote the development of agriculture, the electronic media eg radio, TV, internet, all need to be cheap and affordable to all farming areas.
f) Cultural practices and religious beliefs
The society’s beliefs and culture may also effect agriculture eg Muslims do not eat pork and therefore may not see the need for rearing pigs even if pigs are very productive.
Pastoral communities also only keep animals and may find it difficult to diversify to livestock farming even if its profitable.
N/B: A combination of the above factors may retard agricultural development
g) Market forces:
The local demand and supply of agricultural produce will also affect the level at which farmers produce, also the international demand eg of Kenyan coffee, Tea will affect how much the farmers produce.
BIOTIC FACTORS
These are influences (factors) caused by living organisms, living both in and on the soil surface. These organisms include:
Pests
Parasites
Predators
Decomposers
Pathogens
Pollinators
Nitrogen fixing bacteria
Effects of pests
They feed on plants lowering both the quality and quantity of produce
They transmit diseases
Injure the plants, thus exposing them to secondary infection
Increases the cost of production eg through buying chemicals to control them
N/B: other effects of living organisms on agriculture include:
They decompose the organic matter in the soil eg the decomposers
Encourage aeration through burrowing into the soil
Some living organisms eg ticks also acts as parasites to animals thereby transmitting diseases
Some insects and birds also act as pollinators to flowering plants thus enabling cross pollination
CLIMATIC FACTORS
These are factors due to the changes in the climate. Climate is the weather condition of a place taken over a long period of time. These climatic factors include:
Rainfall
Temperature
Wind
Humidity
Light
a) Rainfall
Rainfall is very important in agriculture production as it ensures supply of water required by all life processes. Aspects of rainfall important in agriculture include:
i) Rainfall reliability
ii) Rainfall amount
iii) Rainfall distribution
iv) Rainfall intensity
v) Form of rainfall
i) Rainfall reliability
This is the assurance that rain will fall come the expected time eg there are two rainy seasons in Kenya. Long rains begin around march 15 – 20 of every year and short rains occur in October – November.
Reliability of rainfall determines:
Time of land preparation
Time of planting
N/B: when rainfall fails to follow the expected patterns, there is usually heavy crop failure and loss of livestock.
ii) Rainfall amount
Rainfall amount is the quantity of rainfall that falls in a given area within a year. Its measured in mm/year. Rainfall amount determines:
Type of crop to be grown
Type of animals reared
iii) Rainfall distribution
Rainfall distribution refers to how the rainfall was spread throughout the year. It determines the crop variety grown in an area
iv) Rainfall intensity
Rainfall intensity is the amount of rain that falls in an area within a period of 1 hour. Its measured in mm/hr.
High rainfall intensity causes: damage to crops, and also soil erosion
v) Form of rainfall
This is the form in which rainfall falls ie may be form of hailstones etc
b) Temperature
This is the hotness or coldness of a place measured in degrees Celsius or centigrade
N/B: All crops thrive well under certain range of temperature known as cardinal range. These crops require narrower ranges of temperature within the cardinal range this is called optimum range.
Effects of low temperature on crop production
Slow growth rate of crops as process like photosynthesis etc will be slow
High incidences of diseases infection to crops eg Elgon die back, CBD, hot and cold diseases in coffee
Quality of crops eg tea, pyrethrum improves with the lowering of temperature
Effects of high temperature on crop production
Increase evaporation leading to wilting in crops
Increase rate of growth or hasten the maturity of crops
Improve the quality of crops such as pineapples
Causes incidences of diseases infection eg leaf rust in coffee and pest infestation eg aphids in vegetables
c) Wind
Wind is air in motion. Wind influences agricultural production by:
Causing lodging in cereals and damage to crops
Blowing away and bringing in rain bearing clouds
Acting as an agent of seed dispersal
Acting as agent of pollination
Increasing the spraed of pest and diseases
Destroying farm structures by carrying away roof tops
Also causes a cooling effect
d) Humidity
Humidity is the amount of water vapour in the air at a given temperature.
Relative humidity is the amount of water vapour held in the air at a given temperature compared to what it would hold when saturated
Evaporation is the loss of water from the soil surface in form of water vapour
Transpiration is the loss of water vapour through the leaf pores
Evapotranspiration is the loss of water vapour both from the soil and leaf pores
N/B: humidity influences:
Rate of evapotranspiration
Temperature of a given area
e) Light
Light provides energy required for photosynthesis
Photosynthesis is the process by which carbon dioxide in the air and water in the soil are synthesized in the presence of light to form carbohydrates. The light is absorbed by green pigments called chlorophyll.
Carbon dioxide + water = glucose
3CO2 + 6H2O = C6H12O6
Aspects of light important in crop growth are:
i) Light intensity
ii) Light duration
iii) Light wavelength
i) Light intensity
This is the strength in which light is harnessed by chlorophyll for the purposes of photosynthesis.
N/B: The rate of photosynthesis increases with increase in light intensity up to where other factors become limiting eg water.
ii) Light duration
This refers to the period during which light is available to plants per day. The duration is usually 12 hours in a 24 hour day. Plant varieties are classified into:
Short day plants: requires less than 12hrs eg soya beans, rice, tobacco
Long day plants: requires more than 12hrs of day light eg some wheat varieties
Day neutral plants: requires 12hrs of light eg coffee, maize, beans etc
iii) Light wavelengths
Chlorophyll only absorb certain wavelengths of light which are not present in artificial light a part from ultra violet or infra red light
N/B: light influences:
Rate of photosynthesis in green plants
Flowering of plants
Performance of livestock eg growth rate and laying % in poultry
EDAPHIC (SOIL) FACTORS
Soil is derived from latin word solum
Solum means floor
Soil is the natural, consolidated material that originates from weathered mineral rock and decomposing organic matter.
Importance of soil
It’s a natural medium on which seeds germinate and roots grow.
It supplies plants with the mineral nutrients necessary for crop growth
It provides water, air, and warmth for small animals, micro organisms and plant roots to sustain life
It provides anchorage to plants
It also shelters many micro organisms
SOIL FORMATION
Soil is formed through the process of weathering and decomposition of organic matter
Weathering is both chemical and physical transformation that take place in the rocks, converting the components minerals into soils
Decomposition is the decaying/rotting of organic matter.( remains of dead plants and animals) that break down to form soil
Types of weathering
Physical weathering
Biological weathering
Chemical weathering
a) Physical weathering
Agents of physical weathering include:
i) Water
ii) Moving ice
iii) wind
iv) temperature
i) Water
Running water wears away the rocks over which it flows by rolling stones and hand particles on them.
Rain water dissolves carbon dioxide and forms weak carbonic acid which falls into rocks and dissolve them
Moving ice also has a grinding effect
When it rains, the rain drops hit the ground with force
Rainfall erodes soil surfaces
ii) Wind
Strong winds carry rock dust which hit hard on the surface of rocks which then break down to form soil.
iii) Temperature change
Due to temperature changes taking place within the rocks, they crack and crumble to form soil.
Also in cold places, the water in rocks freezes and expands which then produces pressure on rocks then they break to small particles
b) Biological weathering
This is carried through plants, animals and mans activities
Large animals eg elephants, buffalloos, cattle etc when they move, cause pressure on the rocks causing them to break down
Mans activities like mining cultivation and construction of buildings, roads, reduce the size of rocks into smaller particles
c) Chemical weathering
This is weathering which takes place due to chemical decomposition or change in the chemical structure of the rocks
Types of chemical weathering
i) Carbonation
ii) oxidation
iii) Hydration
iv) Hydrolysis
v) Dissolution
i) Carbonation
When it rains, rain water combines with free carbon dioxide in the air to form a weak carbonic acid eg
Rainwater + carbon dioxide = carbonic acid
H2O + CO2 = H2CO3
The weak carbonic acid reacts with limestone found in the rocks to form calcium bicarbonate eg
Calcium bicarbonate formed from this reaction is soluble in water and the process effectively dissolves the rock minerals
ii) Oxidation
This is common in rocks having iron. Oxygen reacts with iron which is in ferrous state. This process forms unstable crystal which is easily decomposed and disintegrated
iii) Hydration
Minerals in rock combine with water to form hydrated compounds. Hydrated compounds so formed are weaker than the original form and these are then acted upon by physical or mechanical agents of weathering
iv) Hydrolysis
this is the reaction of minerals with water which then undergoes weathering process through other agents.
v) Dissolution
The minerals in the rock dissolve in water leaving behind unstable rock, which can break easily.
FACTORS INFLUENCING SOIL FORMATION
Parent material
Climate
Topography
Time
Living organisms
Parent material
The texture of the parent material affects the rate of soil formation. Freely drained parent materials can develop soils faster than dense impermeable parent materials. Also minerals composition of the soil depends on the nature of the materials eg coarse grained soils are from granite which when fully disintegrated will separate into constituent minerals like feldspar, quartz and mica
Climate
Climate factors like rainfall, temperature, light and relative humidity and wind are all important in soil formation. Due to continuous weathering, rainfall for example provides water which is an important reactant in all forms of weathering high temperature also spend up most chemical reactions
Topography
Topography may either increase or delay the effects of climate on soil reaction eg factors like slope, degree of exposure or shelter may influences the degree of sol erosion which leads to shallow or deep soils.
Topography also affects the movement of products of weathering which consist of soluble and solid particles. It therefore affects the soil depth and type of vegetation
Time
The length of time over which the soil forming processes have been in action affects the age of the soil. Where the soil forming processes have been taking place for a long time, deep mature soils can be found. This is possible if other factors such as topography, parent materials climate etc, favour the development of deep soils. Where soils erosion has been severe because of topography there is a tendency for the soils to remain shallow and youthful with poorly differentiated profile.
Living organisms
Living organisms affect accumulation of organic matter and also profile mixing. The micro organisms eg rhizobium add nitrogen to the soil
Vegetation cover also reduces surface erosion and this in turn mineral removal is reduced. Therefore the nature and number of organisms growing on and in the soil play a big role in the kind of soil that develops
SOIL PROFILE
Soil profile is the vertical arrangement of soil layers. The layers are called horizons
There are four broad groups of horizons, namely: A,B, C, and D
Top soil ———– horizon A
Sub soil ———– horizon B
Substratum —— horizon C
Parent rock —— horizon D
Cross – section of soil profile
Superficial layer
This is a layer consisting of dry and decayed organic matter covering the soil surface
Top soil (horizon A)
This is the top layer of the soil. Its dark in colour because it contains humus in it. It has many living organisns and plant nutrients, this layer of the soil has goodcrumb structure and is quite permeable to air and water.
Sub soil (horizon B)
Its below the top soil
Has no humus and usually orange brown in colour
It has few living organisms and deeper growing roots of plants
It may have an impermeable layer called the hardpan
Causes of hardpan
Working the soil when wet with heavy machinery
Cultivation at the same depth throughout
Disadvantages of hardpan
Hinders air circulation in the soil
Prevent crop root penetration
Weathered rock (substratum)
This layer is found beneath the sub soil. Its made of partly weathered rolck with no humus. Its hard and therefore impermeable to water.
Parent rock
This is the bedrock. The soil formed from this rock. Ponds of water are often formed on this rock. Roots of some plants in very dry areas reach these ponds to absorb water
Transitional zone
This is a zone between any two bordering soil layers, whereby one layer gradually merges into the next one in the series
Influence of profile on crop production
Most plant nutrients are found in the top soil
The deeper or thicker the profile, the better its for crop production
Loosely packed soil allows for easy root penetration
The nature of the bed rock also determines the nutrients availability in the soil.
SOIL CONSTITUENTS
Soil is made up of the following:
Mineral matter
Soil water
Soil air
Organic matter
Living organisms
Mineral matter
These are inorganic compounds formed from the weathering of rocks. They differ in size ranging from an clay to gravel. They include:
Clay
Silt
Sand
Gravel
Influence of mineral particles on crop production
They make the main frame work of the soil
They hold plant roots firmly together
How to determine the mechanical composition of the soil
Using various sieves of different diameter
Soil water
Soil has water which comes from rainfall and also from irrigation in dry lands
Forms of soil water
Superfluous water
Capillary water
Hygroscopic water
Superfluous water
This is water which is held by gravity. Its also called gravity water.
Its easily lost because its loosely held by soil particles
Its readily available to plants but not useful because too much of it limits aeration
Capillary water
This is water occupying the micro pores. Its held by soil particles
It’s the water available to plants. Its also reffered to as available water
Hygroscopic water
This is water which forms a thin film around the particles. Its not available to plants
Functions of water to plants
Soil water maintains the life of plants
Its used as a raw material for protein for diffusion of mineral salts and oxygen into the root hairs and the mineral salts dissolved in water are conducted upwards to the leaves.
Its also acts as a solvent for the diffusion of other substances from one part ofplant to another
It makes protoplasm and cell sap of the growing plants
It keeps the cell turgid and thus supports plant
Also cools the leaves of the plant during transpiration
Experiment 1 to find the percentage of soil water content
Apparatus: – dish, stirring, weighing balance, soil sample and heater or oven
Procedure: –
Measure the mass of the dish
Pour soil in the dish and weigh
Half fill the dish with water
Heat upto a bout 105oc
Cool the sol with a dessicater then reweigh – repeat the process until you get a constant mass
Soil air
The spaces between the soil particles are filled with air. These include
Oxygen —————– 20.6
Carbon dioxide ——- 0.6 – 0.6
Nitrogen ————– 78.6
Other rare gases.
The amount of air available in the soil is inversely proportional to the amount of water in rhe soil pore spaces.
Oxygen present in the air is essential for the respiration of roots and other living organisms in the soil
Nitrogen in the soil is converted into nitrates by the nitrogen fixing bacteria
Air is also needed by the micro organisms living in the soil
Excess carbon dioxide in the soil is poisonous to plants
Experiment 2: To find the percentage of air by volume in a soil
Apparatus
Small tin
Graduated cylinder
Knife and stirring rod
Procedure
Turn the empty tin upside down and press firmly into the ground until the tin is completely filled with soil
Turn the tin upright and level the soil to the brim of the tin with a ruler
Pour 250cm3 of water into a cylinder and scrap off soil into the water until no bubbles comes out
Record the final volume of soil and cylinder
Soil organic matter
Organic matter in the soil is the remains of the dead plants and animals plus their waste products
Humus is the decayed organic matter
Importance of organic matter
Decomposes to release nutrients to plants
Makes the soil lighter to cultivate
Also improves the soil structure
Experiment 3 To find the % of humus content in the soil
Apparatus
Dish
Garden soil
Tripod stand
Wire gauze
Bunsen burner
Procedure
Weigh the empty dish
Put the garden in the dish and reweigh
Place in an oven at about 105oc
Cool in a dessicater and reweigh
Repeat the process several times until a constant weight is obtained
Note the difference weight
Soil living organisms
There are two types of living organisms in the soil namely:
Macro organisms
Micro organisms
Macro organisms are large organisms found in the soil eg rodents, earthworms, ants, termites, plant roots etc
Micro organisms are tiny organisms which can only be seen with the help of a microscope they include bacteria, fungi, protozoa etc.
Importance of soil living organisms
They barrow in the soil and aerate the soil and improve drainage
They help in the decomposition of organic matter
Some also fix nitrogen in the soil eg the nitrogen fixing bacteria
Experiment 4: To show the presence of living organisms in a soil sample
Apparatus
2 flasks
Rubber cork
Muslin bag
Heater
Lime water
Garden soil
Procedure
Put a handful of garden soil in two muslin bags labeled A and B
Heat the soil in muslin bag B strongly to kill the micro organisms
Suspend the two bags in the flasks also labeled A and B, the flasks should contain lime water
Leave the apparatus for 4hrs
Observation
Lime water in flask A turns milky
Lime water in flask B remains clear
Conclusion
Lime water in flask A turns milky because of the presence of carbon dioxide produced during respiration. Carbon dioxide turns lime water milky
Lime water in flask B remained clear since the living organisms were killed during heating so no respiration took place
Physical properties of soil
These include:
Soil structure
Soil texture
Soil colour
Soil structure
This is the way in which the individual soil particles are arranged
Types of soil structure
Single – grained structure
Crumby structure
Granular structure
Platy structure
Blocky structure
(a) Single – grained structure
In this structure, the particles are not cemented together. They exist as individual grain. They form no aggregates and are non porous.
They are mostly found in top soils of sandy soils and in arid climate and in alkaline soils
(b) Crumby structure
This type consists of small, soft porous aggregates of irregular shapes. They are not closely fitted together
(c) Granular structure
This is made of friable rounded aggregates of irregular shapes called granules. Its formed when particles co agulate and are cemented together to form rounded aggregates whose diameter is not more than 15cm
When wet it becomes porous since the spaces are not readily closed by swelling. The structure is found in top horizon in cultivated soils and in the sub- soil under grass. The structure is not porous and is usually affected by tillage.
(d) Prismatic structure
This is where the structure aggregates are arranged vertically. The primary particles are vertically oriented forming distinct columns which vary in length depending on the type of soil.
The structure is found in sub soil of arid and semi arid soils
N/B: If the tops are rounded, they are called columnar. But if the tops have clear cut edges, the its called Prismatic
Platy soil structure
In this structure, the aggregates are arranged on top of one another on thin horizontal plates. The plates overlaps and impair permeability and hence drainage and root penetration. The structure is found in top soils of clay soil and forested area.
(f) Blocky structure
Here the aggregates are in form of rectangular blocks. The aggregates easily fit together a long vertical edges
Influence of soil structure on crop production
A loosely packed structure ensures good air circulation in the soil
Good structure also ensures proper water holding capacity
Good structure also gives proper root anchorage
Good structure also reduces then soils liability to erosion
Factors that influence the soil structure
Parent material
The physical and chemical properties of the parent rock will determine the type of structure being formed
Soil forming processes
Processes which lead to soil formation will determine the type of structure being formed
Climate
In areas where a lot of rainfall is followed by dry periods cracks tend to form giving rise to good structure which is well aerated
Organic matter
Presence of organic will stabilize the soil structure
Living organisms
Living organisms also help to decompose organic matter which turn improve structure
Cultivation
The nature of cultivation eg digging channels results in a better structure
Inorganic compounds
Presence of compounds like iron oxide have binding properties and help in the formation of granules
Soil texture
This refers to the various mineral particles present in a soil sample.
Particles Diameter
Clay 002mm and below
Silt 002 —— 0.02
Fine sand 02 ——- 0.2
Coarse sand 2 ——– 2mm
Gravel 2 ———- 20mm
Stone 20mm and above
Determination of soil texture
Can be determined by:
Mechanical analysis
Chemical analysis
Mechanical determination of soil texture
Apparatus
Sieves of different diameter
Containers
Weighing balance
Procedure
Put a known amount of soil sample in a container
Pass the soil through a sieve of the smallest diameter and shake
Weigh the soil that remains in the sieve
Repeat the process using sieves of different diameter until all the soil I passed through
Observation
After every sieving it will be observed that a certain amount of soil remains in the sieve
Conclusion
Soil is made up of different sized particles of different diameter
Experiment 6: to show that soil is made up of different sized particles
Apparatus
Measuring cylinder
Sodium carbonate
Garden soil
Procedure
Put some soil sample in a measuring cylinder
Add about 4 times its volume of water with sodium carbonate to aid in dispersion of particles
Cover the mouth of the cylinder with the hand and shake vigorously for about 2min.
Place cylinder on the bench for about 1hr or more to allow the contents to settle down
Observation
At the end of the period, it will be seen that fractions have settled in layers
The heavy, coarse gravels settle first, then followed in succession by sand, silt and clay
The humus and organic matter remain floating in the water or on top of the clay
Conclusion
From the above observations, it can then be concluded that soil is a mixture of particles of different sizes.
Influence of soil texture on crop production
Coarse soils have poor water holding capacity
Very fine textured soils also have poor aeration
Soil colour
Soil colour depends mainly on the mineral composition of the soil
If the soil was made from a rock containing a lot of iron compounds, it tends to be brownish yellow, reddish or orange in colour
Humus content also gives dark brown colour
Soil colour influences temperature of the soil
Soil classification
Soil can be classified based on the following
Soil structure
Soil texture
Soil colour
Soil ph
According to structure, soils could be classified as granular, crumby, blocky, or platy soil structures
According to texture, a soil containing high proportion of sand particles is called sandy soils, if it contains high amount of clay then its called clay soils
In terms of colour, soils could be either dark coloured soils or light coloured soils
Types of soils
Sandy soils
Silty soils
Clay soils
Clay loams
Loamy soils
Sandy soils
They have bigger particles
Contains 50 – 80% sand, and 20 – 50% silt and clay
Organic matter content is 0.1 – 3%
Are well drained
Are more prone to soil erosion have low water holding capacity
They are slightly acidic
Easy to cultivate but less fertile
how to improve sandy sols
Add organic matter
Addition of fertilers
Silty loams
They contain 20 – 30% sand
Also contains 70 – 30% clay
Has 0.1 – 4% organic matter
They are fine textured, well drained and have a good water holding capacity
They have moderately acidic ph
Moderately fertile and aerated
Clay loams
They contain 20 – 50% sand
Clay and silt is 20 – 60%
Has organic matter content of 0.1 – 6%
They are fine textured
Poorly drained and aerated
Has capillarity and water retention
They are rich in plant nutrients
Are suitable for flood irrigation for rice growing
This soil can be improved through drainage
Clayey soils
Have clay content of more than 40%
Have high water holding capacity
Have crystalline and platy structure
Expand when wet
Crack when dry
Get water logged easily
Also suitable for flood irrigation
Have high capillarity
Loamy soils
They contain 30 -50% sand, 50 -70% silt and clay and 0.4% organic matter
Are moderately textured and drained
Are slightly acidic
Have good water holding capacity
Can be improved by planting cover crops and adding organic manures
Experiment 7: To compare the porosity and water holding capacity of sand, loam and clay
Apparatus
Measuring cylinder
Funnels
Cotton wool
Dry sand, loam and clay
Procedure
Place equal volumes of each soil in each funnel plugged with cotton wool
Tap all the funnels persistently until all visible air spaces are filled up
Stand each funnel in the open end of measuring cylinder and add 50cm3 of water into each funnel
Note the time taken for the first drop of water through into the cylinder
Observation
After some time, it will be seen that water level is high in sand than the rest
Conclusion
Sandy soil is more porous than the other 2
Clay soil has the highest water holding than the other 2
Experiment 8: To compare the capillarity of sand, loam and clay
Apparatus
3 long cylinders
Dry sand, clay and loam
Water trough
Clock
Ruler
Procedure
Close the lower end of each tube with a plug of cotton
Fill each tube with different soils
Tap the end of each tube gently in the bench to tightly pack the soils
Stand and clamp each tube with a clamp and put in an empty water trough
Poor water into the trough to a depth of 5cm
Measure the height of water in each tube after 3 – 5min
Take as many readings as much as possible
Record the readings
Observations
Water will be seen to be rising up the tubes
It rises very fast in sand and loam in the first 3 – 5min. but very slow in clay
After 2hrs water level will be higher in loam than in clay soil and least in sand
Water rise continues in clay soil but stops after some time in loam
Conclusions
Clay and loam have higher capillary action due to their fine pore spaces
Sand has poor capillary action due to their large pore spaces
Clay soil has the highest capillarity
Chemical properties of soil
Soil ph
Soil mineral content
Soil pH
This is the acidity or alkalinity of soil solution
Acidity is determined by hydrogen ion concentration while alkalinity is determined by hydroxyl ion concentration
Influence of soil ph on crop production
Soil ph affects the availability of various nutrients eg low ph makes P, and molybdenum less available and high ph makes Mn, K, Fe and zinc less available
Very low ph affects the activities of micro organisms eg nitrogen fixing bacteria
Different crop species require different ph ranges
Ways of modifying pH
Apply lime to raise the pH
Apply basic fertilizers
Apply sulphur to raise the pH
Apply acidic fertilizers to lower the Ph
FARM TOOLS AND EQUIPMENT
TOOL
A tool is any instrument held in the hand and used to do work
EQUIPMENT
This is something used for specific purpose
Why farmers use tools and equipment
To increase efficiency
To make farm operations easier
To minimize injuries
To enhance production
Precautions in handling tools and equipment
Proper maintenance
Proper use of tools
Proper storage
Use safety devices and clothing
Proper dressing
Skilful handling of tools
Categories of farm tools and equipment
Garden tools and equipment
Livestock production tools and equipment
Workshop tools and equipment
Plumbing tools and equipment
Masonry tools and equipment
Factors determining the choice of tools to use
The task to be performed
The tools efficiency
The level of knowledge and skill of user
Availability of the tools
General Maintance practices of farm tools
Sharpen the cutting edge
Grease the moving parts
Repair or replace worn out parts
Proper and safe storage
Clean after use
Tighten loose nut and bolts
Oil and paint before long storage
Reasons for maintaining farm tools and equipment
To durability
To improve efficiency
To avoid injury
Reduce production cost
CROP PRODUCTION I
LAND PREPARATION
Land preparation involves all those activities that make land suitable for planting eg ploughing, harrowing, ridging and rolling
Seed bed: this is apiece of land prepared ready for planting. To achieve good germination of seeds the following must be achieved:
Suitable size of clods
Good depth
Looseness of soil
Absence of weeds
Reasons for land preparation
To kill weeds
To incorporate manure and other organic matter in the soil
To destroy different stages of crop pest such as eggs, larva or adult stages by burying them and exposing them to the heat
To encourage the penetration of roots in the soil
To make subsequent operation easy
To encourage water penetration in the soil
Operations in land preparation
Land clearing
Primary cultivation
Secondary cultivation
Tertiary operations
Land clearing
This is the removal of vegetation cover from the surface before land is cultivated. Its done to prepare land for cultivation as well as a method of land reclaimation
Conditions that necessitate land clearing
When opening up virgin land
Where a stalk growing crop was previously planted
Where the interval between primary and secondary cultivation is long such that land is reverted back to its original virgin state
Where land was left fallow for a long time
Methods of land clearing
Tree felling
Burning
Slashing
Use of chemicals
a) Tree felling
This involves cutting down trees. Axes, pangas, are used and small power saws where the trees are few. Bulldozers and root rakers are used where trees are on large scale. After cutting down the trees, destumping or removal of stumps and disposal of trash is done.
b) Burning
here fire is set on the vegetation cover. Should be done when the speed of wind is low to avoid spread of fire to other fields. Burning should be discouraged because:
it destroys organic matter
kills soil micro organisms
also destroys plants nutrients
c) Slashing
Small bushes or grasses can be cleared by slashing. Slashers or pangas are used in a small area, while a tractor drawn mower can be used in large areas
d) Use of chemicals
Chemicals used to kill weeds are called herbicides. They kill weeds faster and more easily.
Primary cultivation
This is the initial opening of land either after land clearing or following a previous crop. Primary cultivation should be done well before the onset of rains to give time for all operations to be done in good time.
Importance of primary cultivation
To remove weeds
To burry organic matter for easy decomposition
To facilitate water infiltration and aeration
To destroy soil borne pests by exposing them to predators and sun
To make planting easy
Ways of carrying out primary cultivation
Hand digging
Mechanical cultivation
Use of ox plough
a) Hand digging
This is mainly the use of simple hand tools such as jembes, mattocks and fork jembes to cut and turn the soil slices.
b) Mechanical cultivation
Where large pieces of land is involved, farmers use tractor mounted implements which include mould board, disc ploughs. Also there is use of sub soilers to break the hard pan.
c) Use of an ox plough
This is use of ploughs drawn (pulled) by animals such as donkeys, camels, oxen etc. common in areas where such animals are available and the terrain is flat.
Aspects to be considered when carrying out primary cultivation
i) Time of cultivation
ii) Depth of cultivation
iii) Choice of implements
i) Time of cultivation
land preparation should be done early enough before the onset of rains.
Reasons for early cultivation
To give weeds and other vegetation enough time to dry up and decompose into organic matter
To allow carbon dioxide and other gases to diffuse out of the soil while being replaced by oxygen required in seed germination and growth of soil organisms
Also gives time for subsequent operations to be done giving way for early planting
ii) Depth of cultivation
factors that determine the depth of ploughing are:
The type of crop to be planted: Deep rooted crops require a soil which has been cultivated deeply, because it will facilitate easy root penetration. Shallow rooted crops may not need deep cultivation
The implements available: There are some implements which canot cut the soil beyond a certain depth. Such implements can be sharpened or weight be added
Type of soil: heavy soils are hard particularly when they are dry. Simple implements such as jembes tend to dig shallowly on such hard soils
iii) Choice of implements
Choice of implements used in primary cultivation is determined by:
The condition of the land: If the land has a lot of stones and stumps, it would be advisable for one to choose a disc plough which would not break easily when working on such land. A jembe cannot be used efficiently on land which has a lot of couch grass because it cannot pull all the rhizomes.
The type of tilth required: very fine tilth requires the use of different types of implements
The depth of cultivation needed: heavy implements are necessary when deep cultivation is needed and light implements are required when shallow cultivation is necessary
Secondary cultivation
These are operations which follow the primary cultivation and means seedbed refinement practices before planting, also called harrowing
Importance of secondary cultivation
To remove any weeds that might have germinated after primary cultivation
To break the soil clods into small pieces for easy planting
To level the field on order to achieve a uniform depth of planting
To incorporate organic matter into the soil in order to encourage decomposition before planting
Factors that determine the number of times of secondary cultivation
Size of planting materials: Big seeds such as those of groundnuts, maize etc require a fairly rough seedbed, and small seeds such as those of finger millets require fine seedbed
Slope of the land: When the land is very steep, less cultivation should be done to discourage soil erosion
The moisture content of the soil: In dry soils less cultivation are preferred so as to conserve the available moisture
Condition of the soil after primary tillage: where there is plenty of trash, more harrowing operations should be carried out to incorporate most of the trash into the soil
N/B: Implements used for secondary cultivation are: pangas, jembes, fork jembes, and garden rakes. Tractor drawn harrows eg discs, spike toothed and spring tine harrows
Tertiary operations
These are operations carried out to suit production of certain crops. They are carried out after land clearing primary cultivation and secondary tillage. They include:
Leveling
Rolling
Ridging
a) Leveling
This is the practice of making the soil surface flat and uniform so as to promote easy germination of small seeded crops such as wheat, grasses, and barley. It facilitates uniform germination of seeds.
b) Rolling
This is done to compact soil which is loose or fine tilth. Its done to prevent small seeds from being carried away by wind and to prevent soil erosion. Also increases seed soil contact. Implements used are: simple hand tools and heavy rollers
c) Ridging
This is the process of digging soil in a continuous line and heaping it on one side to form a bund ( ridge) and a furrow. The ridges are important for planting root crops like Irish potatoes, cassava etc. ridging helps in: tuber expansion and easy harvesting of root crops.
N/B: Other tillage operations include:
Sub soiling
Minimum tillage
Sub soiling
This is the process of cultivating the soil for the purpose of breaking up the hard pans which might have formed as a result of continuous use of heavy machinery in land preparation. Implements used in sub soiling are:
Sub soiler
Chisel ploughs
Cultivators
Importance of sub soiling
Helps to break up hard pans
Helps to facilitate gaseous exchange in the soil
Also brings to the surface, minerals which might have leached to the deeper layers
N/B: hard pan is an impervious layer of soil found within the sub soil.
Minimum tillage
This is the application of a combination of farming practices aimed at least disturbance to the soil.
Reasons for carrying out minimum tillage
To reduce the cost of cultivation or ploughing by reducing the number of operations
To control soil erosion, mulching and cover cropping greatly reduce chances of soil erosion
To maintain soil structure, continuous cultivation destroys soil structure hence its avoided
To conserve moisture, continuous cultivation exposes the soil to the heat of the sun thus enhance evaporation of available moisture
To prevent disturbance of roots and underground structures for example tubers and bulbs
To prevent exposure of humus to adverse conditions such as the suns heat that cause volatilization of nitrogen
Ways of carrying out minimum tillage
Application of herbicides in controlling weeds
Use of mulch on the soil surface. Mulch prevents weeds from growing by smothering them
Timing cultivation, late weeding of cotton crop, for example often produces a clean seedbed for finger millet to be sown without further cultivation
Restricting cultivation to the area where seeds are to be planted. Weeds in the rest of the field are controlled by slashing
Establishment of cover crop on the field
Uprooting or slashing weeds on perennial crops
WATER SUPPLY, IRRIGATION AND DRAINAGE
Sources of water
Surface water
Ground water
Rain water
Surface water
Sources of surface water are:
Rivers
Streams
Lakes
Ground water
Sources of ground water are:
Springs
Wells
Boreholes
a) Springs
Here water comes out of the ground as a result of an impervous layer meeting the ground surface.
Low wall can be constructed around the spring to increase the water volume for easier pumping
Also on higher ground, water can be conveyed to lower grounds by gravitational flaw
Diagram of a spring
b) Wells
Wells are holes dug in the ground until water table is reached. Can go up to 15m deep.
It’s advisable to dig the well during dry season to ensure that even during dry season water will be available
Fence around the well to avoid contamination
Construct a reinforced slab with a lockable lid to prevent contaminations and wearing of the top sides of the well. Water is lifted using buckets
Diagram of a well
c) Boreholes
These are deep holes drilled or sunk into the ground by use of drilling machines. The holes are usually sunk into the Parent rock to ensure continuous supply of water. The hole is of small diameter and usually lined with metal casing perforated at the bottom end to allow the water to rise up. Special pumps operated by either electricity or engines are used to lift water out of the hole.
Diagram of borehole
Rain water
Collected from roofs then stored in tanks. Ponds also constructed to store the run off. This is done during the rainy season.
Water collection and storage
Methods of water collection and storage include:
Dams
Weirs
Water tanks
Dams
This is a barrier constructed across a river or dry valley to hold water and raise its level to form a reservoir or lake. It has a spillway to allow excess water flow away. The accumulated water is then pumped to farms.
Weirs
A weir is a barrier constructed across the river to raise the water level, but still allow water to flow over it
Water tanks
Rain water, ground water and run off can be stored in tanks. The water storage structures (tanks) include:
Concrete tanks (overhead or underground)
Corrugated iron sheets
Steel tanks
Plastic tanks
Parts of a water tank
Funnel lid
Overflow pipe
Drainage pipe
Roof
Gutter
Outlet
Base
Diagram of water tank
Pumps and pumping of water
Water pumps
Types of water pumps include:
Centrifugal/Rotar dynamic pumps
Piston/Reciprocating pumps
Semi rotary pumps
Hydram pumps
a) Centrifugal pumps: These are made of metal discs with blades that rotate at high speed. They are powerful and can pump water for irrigation. Electric motors, diseal or petrol engines are used to operate them.
b) Piston pumps: Consist of pistons that move back and forth thereby pushing water through the pipes. Do not pump a lot of water thus suitable only for domestic and livestock use.
Diagram of a piston pump
c) Semi rotary pumps
These are operated by hand, and mostly used to pump water from wells for domestic and livestock use
d) Hydram pumps
these are operated by the force of flowing water. The higher the speed of water, the greater the pressure created in the pump. Cannot pump stationary water and only suitable for slopy areas, where water flows at high speed.
N/B: Pumping of water is the lifting of water from one point to another by use of mechanical force.
Conveyance of water
This is the process of moving water from one point mostly from storage to where its used or stored
Ways of conveying water
Piping
Use of containers
Use of canals
a) Piping
This is where water is moved through pipes
Types of water pipes
i) Metal pipes
ii) Plastic pipes
iii) Hose pipes
i) Metal pipes
These are two types: Galvanized iron and Aluminum pipes
Galvanized iron pipes are heavy and suitable for permanent installation of water system. Alumimium pipes are light and used for irrigation systems,
N/B: metal pipes are expensive but durable
ii) Plastic pipes
These are made of synthetic materials. There advantages include:
They are cheap
Easy to install
Durable when installed properly
Disadvantages include:
Become brittle when exposed to sun
Can burst under high pressure
Can be eaten by rodents
iii) Hose pipes
There are two types: rubber hose pipes and plastic hose pipes
Rubber hose pipes are more expensive but durable, hose pipes are used to convey water from taps to various areas eg irrigation areas or washing places
b) Use of containers
Water is drawn and put in containers such as drums, jerry cans, pots, tanks and buckets which are carried by animals, bicycles, human beings and vehicles
c) Use of canals
Water is conveyed from a high point to a lower appoint along a gradual slope to avoid soil erosion. Water conveyed in canals is mostly used for irrigation and livestock drinks
WATER TREATMENT
Water treatment is the process of making raw water from source safe for use in the farm.
Importance of treating water
To kill disease causing micro organisms such as cholera and typhoid bacteria which thrive in dirty water
To remove chemical impurities such as excess fluoride this may be harmful to humans
To remove smell and bad taste
To remove sediments of solid particles
The process of water treatment
Filtration at water intake
Softening of water
Coagulation and sedimentation
Filtration
Chlorination
Storage
Stage 1: Filtration at water intake
At the pint of water intake, water is made to pass through sieves before entering the intake pipe. This is to trap large impurities. Several sieves of different sizes are made.
Stage 2: Softening of water
The water in the pipe flows into the mixing chamber. This is a small tank where water circulates and is mixed with soda ash ( sodium bicarbonate) and alum ( aluminium sulphate) these chemicals are added into water in equal proportions. Soda ash softens the water, while alum helps to coagulate solid particles which finally settle down to the bottom
Stage 3: Coagulation and sedimentation
The softened water moves to the coagulation tank which is a circular and large solid particles such as silt and sand coagulate and settle down. The tanks is also open to allow in fresh air into the water. Water should stay in this tank for at least 30 hrs to kill bilharzias which cannot survive in water stored that long
Stage 4: Filtration
Water with very few impurities passes into a filtration tank where all the remaining solid particles such as silt are removed. The filtration tank has layers of different sizes of gravel and a top layer of sand. At its bottom is a layer of large pieces of gravel, this is followed by another layer of gravel but of fine texture. A layer of fine sand is placed on top of this fine gravel. These layers allow water to seep through very slowly leaving all the solid particles behind. When water leaves this tank, its clean.
Stage 5: Chlorination
The filtered water enters the chlorination tank. In this tank, small amount of chlorine solution is controlled by a doser and the amount added will depend on the volume of water to be treated and the outbreak of water borne diseases. Chlorine kills pathogens
Stage 6: storage
Water is then stored in large tanks, before distribution to consumers.
General uses of water in the farm
For domestic purposes eg washing, cooking etc
For watering livestock eg washing pigs
For diluting chemicals
For processing farm produce eg coffee etc
For construction of buildings
For irrigation
IRRIGATION
Irrigation is the artificial application of water to soil for the purpose of supplying sufficient moisture to crops.
Conditions that make it necessary for irrigation
In dry areas
During dry periods
In the growing of paddy rice
Soften the soil during transplanting
To effect the application of fertilizers and other chemicals
Types of irrigation
Surface irrigation
Sub surface irrigation
Overhead irrigation
Drip/Trickle irrigation
Factors that determine the type of irrigation to use
Capital availability
Topography of the land
Water availability
Type of soil
Type of crop to be irrigated
Surface irrigation
Here water is applied to the field by allowing it to flow on top of the ground surface.
Methods of surface irrigation
Flood irrigation
Furrow irrigation
Basin irrigation
Boarder irrigation
a) Flood irrigation
In flood irrigation, water is allowed to cover the whole field a few centimeters in depth. Its suitable for growing paddy rice fields.
Advantages of flood irrigation
Its cheap to establish and maintain
Does not require skills
Disadvantages of flood irrigation
There is uneven distribution of water in the field
A lot of water is wasted
b) Furrow irrigation
Here water is supplied by use of open ditches or furrows. Its suitable for all crops and application to most soils
Maintenance of furrows
Repair furrows when worn out or eroded
Remove weeds and silts
Advantages of furrow irrigation
Reduces chances of fungal diseases
Cheap to establish
Require little skills
Disadvantages of furrow irrigation
A lot of water is lost through evaporation and seepage
Erosion can occur if the furrows are not maintained
If water has high content of salt, it may have damaging effect on the plant roots
c) Basin irrigation
Basin irrigation involves the application od water into basins that have been checked by construction of banks or ridges. The basins may be rectangular ring shaped or have contour checks
This system is suitable in:
Relatively flat areas
Soils of low infiltration
For crops requiring large quantities of water
Soils that require leaching
Advantages of basin irrigation
Helps to control soil erosion
Retains rain water in the basins
Disadvantages of basin irrigation
Much land is occupied by water covering channels and ridges
There is no surface drainage
Requires precise land grading
Requires a lot of labour
Cannot be used in crops that require free draining soils
May result in accumulation of salts
Areas where basin irrigation is being practiced in kenya: mwea tebere, ahero, bunyala, west kano etc
d) Boarder irrigation
This is where parallel ridges guide a sheet of water that spread cover a relatively flat, but slanting piece of land. The ridges form long boarders. This method is applied where:
Soils have low to relatively high infiltration capacity
Crops are closely spaced, such as wheat, barley fodder crops as well as legumes
Advantages of boarder irrigation
Its easy and simple to operate
Requires less labour as compared to basin irrigation
Boarder ridges can be constructed economically with simple farm implements eg ox drawn ridgers
Large irrigation streams can be efficiently used
Sub surface irrigation
This is a system of irrigation where water is supplied to crops using underground perforated pipelines or any other porous medium that make water available from below the soil surface. Pipes sometimes referred to as conduits
The system is suitable in soils of high capillarity and water holding capacity
Advantages of sub surface irrigation
Little labour requirements
No need to construct dykes or soil grading
Can be practiced on both sloppy and flat land
Water does not cause soil erosion
Does not encourage fungal diseases
Economizes use of water
Minimizes theft of pipes
Disadvantages of sub surface irrigation
Its expensive method ie to buy pipes and to lay them
Pipes can be broken during weeding
Nozzles can get blocked
Overhead irrigation
This is the application of water above the crops by means of sprinklers or watering cans. Wind breaks should be constructed to avoid misdirecting the water.
Advantages of overhead irrigation
Water is evenly distributed over the required area
There is less water wastage than in furrow irrigation
It can be practiced on slopy grounds
Foliar fertilizers can be applied together with irrigation water thus reducing labour costs
Sprinkler systems can be easily be moved from one place to another
Disadvantages of overhead irrigation
Its expensive to install
Encourages fungal diseases eg blight, CBD
Causes soil erosion
Requires establishment of wind breaks
Sprinklers used are: oscillatory sprinklers, spring loaded sprinklers
Sprinklers can also be classified into: rotating head, perforated pipe system
Maintenance of sprinklers and pipes
Lubricate the rotating parts
Repair broken parts
Cleaning and unblock the nozzles
Drip/Trickle irrigation
Here pipes with tiny perforations are used. As water passes through the plastic pipes, water comes out through the holes in small amounts and drips to the ground.
Advantages of drip irrigation
Requires little amount of water
Can also use water of low pressure
Discourages fungal diseases eg blight, CBD
Does not encourage the growth of weeds
Can be used in sloppy topography
Disadvantages of drip irrigation
Pipes are expensive to buy and install
Require clean water, since dirty water will block the perforations
Factors to consider when choosing irrigation equipment
Capital availability
Topography
Availability of repair and maintenance
Type and source of power
Source
DRAINAGE
This is the method of removing excess water from water logged land. It’s a method of land reclaimation.
Land reclaimation is the process of bringing back waste land to agricultural production
Importance of drainage
Improves soil aeration: removal of excess water around the root zone allows for enough air for proper growth
Increases soil volume: increases the amount of soil around the roots
To raise the soil temperature: improves the rate at which soil worms up for better plant growth
Increases microbial activities: micro organisms in the soil increase in number due to proper aeration, they help to improve soil structure and make plant food more readily available
Reduce soil erosion: well drained soils have higher water holding capacity which helps to reduce water run off and increase infiltration
Remove toxic substances: due to water logging, soluble salts such as those of sodium increases in concentration to levels that are toxic to plants or may retard growth
Methods of drainage
Use of open ditches:
ditches are dug for the water to flow in by gravity to a water way thereby lowering the water table. May be U shaped or V shaped or trapezoidal
Underground drain pipes:
perforated pipes are laid underground. Water then seeps from the surrounding area into the pipes and flows to a water away. Such drains do not interfere with field operations. The pipes may be made of steel, clay or plastic materials
French drains:
ditches are dug, filled with stones and gravel, then covered with soil. Water from the surrounding area seeps into these drains and is carried into a water way
Cambered beds:
raised beds are constructed on the poorly drained soils
Pumping: where other methods of drainage are not possible, water is pumped out.
Areas where drainage has been carried out in kenya are: yala and bunyala to control flooding, ahero to control flooding of river nyando, loriaan region
WATER POLLUTION
This is the contamination of water by either chemical, industrial wastes, farm residues etc, making it unsafe for human beings and animals.
Agricultural practices that pollute water
Fertilizer and pesticides: chemicals compound found in the fertilizers and other pesticides do not decompose easily, hence they find their way into water sources through drainage, irrigation channels, erosion, seepage and leaching
Improper disposal of used farm chemicals: when containers contaminated with chemicals are disposed of into water sources, the result is water pollution
Damping of farm wastes: farm wastes such as slurry, manure used polythene, dead animals etc when improperly disposed of cause water pollution.
When land is cultivated or the soil is left bare erosion will easily occur leading to contamination through unwanted soil
Blockage of irrigation channels and water ways prevents free flow of water leading to stagnation of contaminated water
When pit latrines and sewage sites are located near water sources, they cause pollution
Other sources of pollution include industrial wastes and generalized contamination in the atmosphere and the environment
Methods of preventing water pollution
Practice organic farming
Safe disposal of used farm chemicals and industrial wastes
Proper location of pit latrines, sewage sites and waste dumps
Control of irrigation and establishment of grassed water ways to purify the water
Controlled use of fertilizers, manures and farm chemicals
Ensuring that the water source is free from contamination from the farm
Treating and piping water for farm use
SOIL FERTILITY I
This is the ability of the soil to produce and maintain high yields of crops for an indefinite period.
Characteristics of fertile soil
Should have good depth
Be well drained not water logged
Well aerated
Good water holding capacity
Supply nutrients needed by plants in correct amount and form available to plants
Correct soil pH for different crops
Free from crop pests and diseases
How soil loses fertility
Continuous growing of arable crops: continuous cultivation makes the soil loose and liable to erosion, this leads to lose of fertility.
Mono cropping: growing of crops every season leads to depletion of soil nutrients
Soil erosion: This leads to lose of top fertile soil
Leaching: leads to lose of soil nutrients into the lower horizons of the profile
Poor soil aeration: if soil is poorly aerated, the denitrifying bacteria increase in number and they make the infertile by converting nitrates into free nitrogen.
Poor drainage of the soil: If the soil poorly drained, the soil becomes flooded, forms acid soils which are useless for cultivation
Dry soils: If the soils are dry, the nutrients cannot be dissolved to be used by crops
Change of pH: soil pH influences the availability of certain nutrients eg low pH decreases solubility of phosphorus and high pH also decreases the availability of K, Mn etc
Accumulation of salts: certain salts usually become toxi if present in excess eg Mn, boron, fluorine etc
Burning of land: burning of land kills certain micro organisms and destroys certain nutrients
Ways of maintaining soil fertility
Control of soil erosion: control of erosion prevents loss of top fertile soil
Crop rotation : this ensures maximum utilization of crop nutrients. Also helps to control pest and diseases, will also add nutrients if legumes are included in the rotation
Maintaining soil pH: when soil pH is maintained at given ranges, particular nutrients will be available in the soils
Proper drainage: soil should be well drained to eliminate flooding
Weed control: control of weeds ensures no competition for nutrients, adequate space for crops and destroys alternate hosts for crop pests and diseases.
Minimum tillage: this helps to maintain soil structure and prevent erosion
Use of manures: manures supply a wide range of plant nutrients to the soil
Use of inorganic fertilizers: inorganic fertilizers supply specific plant nutrients
Organic matter, humus, and manures
Organic matter: this is the remains of dead plants and animals and their waste products
Humus: humus is the decayed organic matter ie the remains of plants and animals which have decomposed
Manure: manures are organic substances that are added to the soil to provide one or more plants nutrients. They have high matter content
Roles of organic matter in the soil
Increases water holding capacity and also water infiltration due to its colloidal nature
Releases a wide range of nutrients into the soil thus improves fertility
Provides food and shelter to micro organisms such as ants and rodents
Improves soil structure by binding soil particles
Buffers soil pH by avoiding rapid chemical changes due to the addition of lime and fertilizers
Reduces toxicity of plants poisons that have built up on the soil as a result of continous use of pesticides and fungicides
Classification of manures
Manures are classified according to: method of preparation and nutrients from which they are prepared.
There are 3 types of manures:
Farmyard manure
Compost manure
Green manure
Farmyard manure
Farmyard manure is a mixture of animal waste (urine and dung) and crop residues used as animal beddings.
Importance of farmyard manure
Increases yield of the crop
Adds organic matter into the soil and improves the texture and water holding capacity of thee soil
Adds useful bacteria to the soil
Factors influencing the quality of FYM
Type of animals: dung from fattening animals is richer in nutrients than farm growing animals which extract a lot of phosphorus from food eaten
Type of food eaten: the richer the food in terms of minerals the richer will be the manure
Type of litter used: wood shavings and saw dust are slow to decompose and contain no nutrients and absorb 1.5 times as much urine as their weight, while nappier grass provide both N and P, but has low absorptive capacity.
Method of storage: farmyard manure must be stored well in a place with a cemented floor and covered roof. The N and P are soluble and therefore can get leached by heavy rains
Age of FYM: well rotten manure is richer in nutrients and easier to handle and mix with the soil
Preparation of farmyard manure
A bedding of grass, wood shavings or saw dust is provided in the house of farm animals eg cattle, sheep
The animals deposit their droppings and urine on the bedding materials
After some time, ie daily, months or more as in poultry, the beddings are replaced with new ones
The discarded beddings are deposited in a specially prepared shaded place
New layers of used beddings are continuous added until a heap is formed
N/B: decomposition and mineralization of the materials take place through activities of certain bacteria resulting in a rich manure
Green manure
This is a type of manure prepared from green plants. The plants are grown for the purpose of incorporating into the soil when its green at the flowering stage for the purpose of improving soil fertility.
Characteristics of plants used for green manure
They should be highly vegetative or leafy
They should have faster growth rate
They should have high nitrogen content, thus preferably legumes
The plants must be capable of rotting quickly
The plants should be hardy ie can establish in poor conditions
Reasons why green manure is not commonly used
Most of the crops grown are food crops and its hard for people to use them as green manure
Green manure crops might use most of the soil moisture and leave very little for next main crop
Most of the nutrients are used up by micro organisms in the process of decomposing the green manure plant. These will only be released by micro organisms when they die.
It takes time for green manure crop to decompose and therefore planting is delayed
Preparation of green manure
The plant to be used is planted in the field
The plant is allowed to grow up to flowering stage
Its then incorporated into the soil by ploughing
Left for 2hrs to decompose after which the field is prepared for planting the main crop
Compost manure
Compost manure is the accumulation of plants residue, mixed with animal waste, piled together in a heap where conditions are conducive for decomposition, sometimes contain refuse and kitchen left over foods
Preparation of compost manure
There are two methods namely:
Indore method
Four heap system (stalk method)
Indore method
This was devised in a place called Indore in India
Procedure
A pit is prepared which is 1 – 2 m deep. The material to be made into compost is placed is placed.
The first layer 0.5m deep consist of fresh material to be made into compost eg grass, maize stalk refuse etc
The layer is followed by dung, old compost to provide micro organisms to decompose the fresh material
Artificial fertilizers eg SSP and Muriate of potash are added to increase the nutrient level of the compost
N/B: Nitrogenous fertilizers are not added because they are easily leached
The 2nd layer is followed by a layer of top soil with micro organisms to decompose plant and animal remains
The same is repeated until the pit is full. Its also kept moist by applying water during dry season
Pit
Pit
Pit
Pit
Pit
1
2
3
4
5
Pit 1, 2, 3, and 4 are simultaneously filled and after 3 – 4 wks, the materials in pit 4 is taken to pit 5
This process is repeated until the material that was prepared 1st is well rotten and taken to the field as composed.
The Four heap system
x
y
x
z
In this method, 4 – 7 heaps are used.
Materials used are crop residue, animal waste old manure FYM or onorganic fertilizers and top soil.
The materials is placed in heap X, then transferred to heap Y after 3 – 4 wks. After another 3 – 4 wks, the compost is taken to heap Z where it stays for another 3 – 4 wks then taken to the field
N/B: The manure heaps must be turned occasionally at least every 3 months to facilitate circulation within the heap, manure should be ready after 6 months.
Cross section through a compost heap
N/B: too much water runs the compost
Too little water stop the bacterial action
Always keep the compost under cover of grass and soil
Posts are fixed at a distance of 1.2 m a part to form the 4 corners of the heap, the post should be 2m high
Factors to consider when selecting a site for compost manure
Drainage of the site
Direction of prevailing wind
Size of the farm ie centrally placed
Accessibility
Problems associated with organic manures
Bulkiness
Laborious in application and transport
They spread diseases, pests and weeds
Loose nutrients when poorly stored eg through leaching
If not fully decomposed, crops will not benefit since it releases nutrients which can scotch the crops
AGRICULTURAL ECONOMICS I
Economics: this is the study of how man and society choose with or without money to employ scarce resources to produce goods and services over a period of time and eventually distribute them for consumption now and in the future.
Agricultural economics: this is an applied science that aims at maximizing out put while minimizing costs by combining the limited factors of production to produce goods and services for use by the society over a period of time.
Factors of production
Land
Capital
Labour
Management/entrepreneurship
Basic concepts of economics
These concepts include:
Scarcity
Preference and choice
Opportunity cost
Scarcity
Scarcity means limited in supply
The factors of production named above are scarce and the production needs are many therefore the need for choice
Preference and choice
Since the factors of production are limited, the farmer needs to make a choice on what to produce. This choice has to be guided by the needs of the society and the preference of the farmer on what he needs to produce.
Opportunity cost
When the farmer makes a choice on what to produce, he is forced to leave others due to scarcity of resources eg a piece of land is suitable for growing both rice and maize and he choose to grow maize, the value that could have been derived from rice becomes the opportunity cost.
Opportunity cost is the value of the best foregone alternative
FARM RECORDS
Farm records can be defined as the systemic entries and storage of information of various farm business activities and transactions in appropriate books and sheets.
Uses of farm records
Helps to compare the performance of different enterprises within a farm
Show the history of the farm
Guides a farmer in planning and budgeting of farm operations
Help to detect loses or theft on the farm
Help in the assessment of income tax to avoid over or under taxation
Helps to determine the value of the farm or to determine the assets and liabilities of the farm
Make it easy to share the profits and loses in partnership
Helps in settling dispute among heirs to the estate when a farmer dies without leaving a will
Help to show whether a farm business is making profits or loses
Helps in supporting insurance claims on death, theft etc
Provide labour information like terminal benefits eg NSSF
Types of farm records
Production records
Inventory records
Field operation records
Breeding records
Feeding records
Marketing records
Labour records
Inventory records
This is the physical count of everything that the farm owns and all that it owes others. There are two types of inventory records namely:
Consumable goods inventory
Permanent goods inventory
a) Consumable goods inventory
This is inventory showing a list of goods which normally are used up during a production process, therefore needs constant replacement. Such goods include:
Fertilizers
Livestock feeds
Planting materials eg seeds
Chemicals eg insecticides, herbicides
Sisal ropes and strings etc
Example of consumable goods inventory
RECIEPTS
ISSUES
DATE
ITEM
QUANTITY
DATE
ISSUED TO
QUANTITY
BALANCE IN STORE
b) Permanent goods inventory
This is inventory showing a list of goods which are permanent in nature ie the type of goods which will not get used up in the production process such goods include:
Farm machinery and implements
Farm equipment and buildings
Livestock such as breeding stock
Annual crops
Hand tools
Land (arable)
Example of permanent goods inventory
DATE
ITEM
QUANTITY
WRITTEN OFF
BALANCE IN STOCK
REMARKS
Production records
This is a record which show the total yield from each enterprise and also the yield per unit of the enterprise.
Example of production records (dairy milk production record)
This record contains all the activities carried out in the production from land preparation, planting to harvesting. It contains the following information:
These are records showing the breeding activities and programmes for different animals in the farm.
Importance of breeding records
Help the farmer to plan his breeding programmes
Help in selection of animals within a herd
Example of cattle breeding record
Name/No. of cow
Name of bull/sire
Date of service
Date of pregnancy diognosis
Expected date of calving
Actual date of calving
Sex of calf
Wt. of calf
rmks
N/B: students to draw sheep, pig, and sow breeding records
Feeding records
This is a record showing the type and amount of feeds used in the farm.
Example of feeding records
Month:……………………………………….
Enterprise…………………………………..
Type of feed……………………………….
Date
No. of animals
Amount received (kg)
Amount used (kg)
Balance in stock (kg)
remarks
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