Production Practices in Horticultural Crops.pdf

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CROP SCIENCE

PRODUCTION PRACTICES FOR
HORTICULTURAL CROPS

Malvin B. Datan
Steps in Crop Production

Site selection and evaluation
Land preparation
Preparation of Planting materials
Crop establishment
Care and maintenance
Harvesting
Postharvest Handling/processing

2
Land Preparation

3
Site Characterization

Environmental Factors Edaphic Factors
Soil Type
Climate Soil Structure
Precipitation Soil pH
Temperature
Soil fertility status
Wind
Relative Humidity
Light Biological Factors
Prevalence of pest and diseases
Existence of destructive animals
Weed population
4
Site Characterization

Economic Factors Sociological factors

Cost of land Population
Local taxes Peace and order
Available labor Law enforcement
Economic status of the people
School, churches and hospitals
Facilities
Neighborhood
Recreational facilities

5
Land Preparation

Creates favorable conditions for seed
germination, seedling establishment,
and management of the crop.
It eliminates most of the weeds and soil-
borne pathogens.
Improves the water holding capacity,
drainage, and soil aeration.
It facilitates field operations.

6
Basic Operations in Land Preparation

Clearing/Mowing/Under brushing

Under certain conditions, the
farm may be too weedy to be
plowed. Before plowing, then, it
may be necessary to clear the
field of obstructions and tall
weeds.

7
Basic Operations in Land Preparation

Tillage
The manipulation of the soil into a desired condition by
mechanical means; tools are employed to achieve some
desired effect (such as pulverization, cutting, or
movement).

8
Different Tillage Operations

Plowing
to cut soil into furrow slices
to partly pulverize the soil (still in
cloddy condition)
to incorporate weeds and
stubble underneath the soil

9
Different Tillage Operations

Harrowing
To pulverize the clods left after
plowing
To level the field
To compact soil to a certain degree
To destroy weeds as they start to
grow
Done 2 to 3 times

10
The number of plowing and harrowing depends on:

Soil type
Weed density
Moisture content
Crop to be grown
Seed crop – require better seedbed than a crop
normally planted by cuttings
Over- pulverization - avoided

11
Characteristics of well- prepared upland field

Granular, mellow yet compact enough so
that seeds are in close contact with the soil
for better germination
Free of trash or vegetation
Field is level, with minimum depressions
where water may accumulate

12
Soil Moisture Consideration in Land Preparation

Tilling soil when it is too dry increases power
requirements and the likelihood of implement
breakage.
Tilling soil when it is too wet promotes soil
compaction, reduces soil granulation, lengthens land
preparation.
Ideal moisture content – at a level field capacity.

13
Practical Indicators:

Soil should slide freely from the
moldboard

Soil is friable and breaks easily

Freshly cut surface should not glisten
with moisture

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Other Land Preparation Procedures

Field Layouting

appropriate planting distance and planting systems should be
used depending on the terrain and cropping systems to be
adopted.

Furthermore, proper row orientation should be considered to
allow optimum utilization of sunlight.

15
Other Land Preparation Procedures

Field Layouting
Factors to consider when deciding on planting distance to use:
The final size of the crop (whether pruning and training will be
implemented to control size)

The cropping system/pattern (mono or intercropping)

Fertility status of the soil

The size of farm machineries
16
Other Land Preparation Procedures

Field Layouting

For example, for triangular planting system, the rows should be
oriented north to south to minimize shading of neighboring
plants.

However, for avenue planting rows should be oriented in east-west
direction for maximum exposure.

17
Other Land Preparation Procedures

Establishment of Roads and Drainage Network
In large farms, roads should be a major consideration and spaced
200 meters apart.

Roads should be always laid out across the slope or along
contours.

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Other Land Preparation Procedures

Staking and spacing
The planting points are to be marked
with stakes using suitable size and
length of plastic twine or cable wire as
guide for straight planting.

Spacing and planting system depend
on population, cropping system, variety
and shade condition.

19
Other Land Preparation Procedures

Hole Digging
The size of the planting hole should be
big enough to accommodate the ball of
the soil mass.
In preparing holes, the surface soil
should be separated from the subsoil.
This allows the utilization of the
surface soil to cover the base of the ball
of soil holding the seedling.

20
Other Land Preparation Procedures

Hole Digging
Plant immediately after digging holes.
This is done to preserve the available
moisture.
If the soil however is a bit hard (heavy
soil), digging of hole should be done in
advance of the schedule of field planting
to allow weathering thus soften the soil.

21
Planting Material Selection
and Production

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Planting Materials Selection and Preparation

While quality planting materials of horticultural crops could now be
bought from registered and accredited nurseries, it is still essential to
establish plant nursery and produce your own planting materials
particularly for large scale planting.

There should be reliable supply of quality water, a good soil and it
should be near or close to the proposed plantation.

Recommended nursery practices for raising planting materials of the
crop should be followed as much as possible.
23
Propagation

Depending on the kind of crop to mass produce, propagation could be
done sexually (using seeds ) or asexually (using vegetative parts of the
plant).

Sexual propagation as the name suggests, involves contribution of
both female & male sexes for creation of new plants.

On the other hand, asexual propagation involves production of species
through vegetative parts of the plants such as roots, leaves, stems,
bulbs, tubers, runners, corms, suckers etc.
24
Advantages of Sexual Propagation

Simplest, easiest and the most economical process among various
types of plant propagation.

Some plants, trees, vegetables or fruits species can propagate only
through sexual propagation.

This type of propagation leads to better crop species that are stronger,
disease-resistant and have longer life-span.

Viral transmission can be prevented in this type of propagation.
25
Advantages of Sexual Propagation

Sexual propagation is responsible for production of large number of
crops and that too with different varieties.

It is the only propagation process in which resultant offspring have
genetic variation and exhibit diversity of characters from parent crops.

Easy storage and transportation of seeds.

26
Disadvantages of Sexual Propagation

Seeds take a long time to turn into mature plants i.e. time interval
between sowing and flowering is longer.

Seedlings propagated through sexual propagation are unlikely to have
same genetic characteristics as that of parent plants.

Some plant species do not produce viable seeds through sexual
propagation and hence are unsuitable to propagate for the same.

Plants that do not have seeds can’t be propagated through this
process. 27
Advantages of Asexual Propagation

As resultant species formed through asexual process are genetically
identical, useful traits can be preserved among them.

Asexual propagation allows propagation of crops that do not possess
seeds or those which are not possible to grow from seeds. For e.g.
Jasmine, sugarcane, banana, rose etc.

Plants grown through vegetative propagation bear fruits early.

28
Advantages of Asexual Propagation

In this type, only a single parent is required and thus it eliminates the
need for propagation mechanisms such as pollination, cross
pollination etc.

The process is faster than sexual propagation. This helps in rapid
generation of crops which in turn balances the loss.

Injured plants can be recovered or repaired through techniques
involved in asexual propagation.

29
Disadvantages of Asexual Propagation

Diversity is lost in asexual propagation which is the main reason
behind occurrence of diseases in future plant species.

As many crops are produced with this process, it leads to overcrowding
& lack of nutrients.

New varieties of crops cannot be developed in this type of
propagation.

30
Disadvantages of Asexual Propagation

Asexual propagation is an expensive process that requires special skills
for successful cultivation of crops.

Crops produced through this process have shorter life-span than those
grown through sexual process.

Species involved in this process are less likely to resist pests and
diseases.

31
Planting Materials Selection and Preparation

Types of Planting Materials

Seeds

Vegetative Propagules

32
Planting Materials Selection and Preparation

Types of Seeds

Inbred
Hybrid or F1
Open pollinated

33
Types of Seeds

Inbred
An inbred variety is a pureline. This
means that the offspring or
succeeding generations produced by
this variety will have the same
genetic makeup.

34
Types of Seeds
Association of Colleges of Agriculture in the Philippines, Inc.

F1 hybrid
F1 hybrid means literally ‘first offspring after a crossing’. In the case of
F1 hybrids the breeding process is divided into two phases: inbreeding
and combinations of crossings.

So, the process is more complicated and requires more intervention by
breeders than in the case of an open-pollinated variety.

35
Types of Seeds

Open-pollinated variety
Produced using the traditional method of crossing and then selection
of offspring in several generations (base population).

After a few years (usually after 5 - 6 generations) of systematic
selection the variety becomes stable, and the characteristics hardly
ever segregate out again.

36
 Classes of Seed
Breeder Seed comes directly from plant breeder

Foundation Seed grown from breeder seed

Registered Seed grown from foundation seed

grown from either foundation,
Certified Seed registered or certified seed

seed that may be produced from
Good Seed varieties not yet approved by NSIC
Preparing Seeds for Sowing

Soaking or Pre-germination
This is a common practice for large-seeded crops with hard seed coats.

Before they are sown, the seeds are soaked in water and wrapped in
damp cloth until they start to germinate.

38
Preparing Seeds for Sowing

Seed Treatment
refers to procedures that aims to
disinfect the seeds or protect them
against pest that may pose hazards
during germination and subsequent
stages of plant growth.

39
Preparing Seeds for Sowing

Scarification

Done in hard-seeded crops

Soften or make wound on the seed coat
Hard-seeded crops - e.g., okra, some legumes

40
Preparing Seeds for Sowing

Scarification
Chemical means:

treating winged bean seeds – concentrated sulfuric acid

Physical means:

Passing okra seeds through a metal brush in a rotating drum
Clipping - with a nail cutter for melon seeds

41
42
Preparing Seeds for Sowing

Vernalization/Stratification

exposing the germinating seeds
to low temp. 0-5 C for a certain
period to induce early flowering
and higher seed yield.

43
Methods of Planting Seeds

Crops that are usually transplanted

Species under this group are usually
having smaller-sized seeds and slow-
growing at the onset of germination.

Cabbage, Chinese cabbage, broccoli,
cauliflower, tomato, eggplant

44
Methods of Planting Seeds

Crops usually direct seeded
This group has medium to large-sized seeds
which facilitates direct sowing in the
prepared plots or furrows in the field.

Crops are characterized as fast-growing
after germination; hence, they can quickly
establish in the field.

Watermelon, cantaloupe, squash, cucumber,
snap bean, cowpea, soybean, garden pea
45
Methods of Planting Seeds

Crops that should be direct
seeded
This group is never
transplanted because the tip
of their taproots may be
damaged in the process,
resulting in deformed or
forked roots which are
undesirable

Radish, carrots, turnips.
46
Methods of Planting Seeds

Factors to be considered in selecting a planting method

Cost and availability of the seeds

Quality of land preparation

Root-regeneration ability of the crops

47
Nursery Management

Nursery
The facility for growing transplants,
otherwise called the nursery, can be as
simple as a raised bed in a selected
corner of the field

Or as sophisticated as a glasshouse with
micro sprinklers and an automatic
temperature control system.

48
Nursery Management

All these nurseries seek to provide the following
conditions for growing seedlings:

a. Protection from pests, including higher animals.

b. Protection from rain and sun.

c. Protection against temperature extremes.

49
Nursery Management

Nursery Requirements
Shade cloth or UV stabilized plastic roofing. If using plastic, make
sure it is cleaned regularly to allow light to penetrate

Raised benches at least 0.9m off the ground with metal mesh
benchtops

Good light – do not locate under trees

Good ventilation to avoid heat buildup: 20-25ºC is best for
seedling growth
50
Germination and Seedling Growing Medium

Soil is the universally available medium for germinating
seeds and growing seedlings.

However, it is not necessarily the best medium.

Some soils are unsuitable for growing seedlings.

51
Germination and Seedling Growing Medium

Water-holding capacity and aeration

Organic materials, such as peat, are able to retain moisture
without causing waterlogged conditions.

This characteristic is crucial because the germinating seeds and
the roots of seedlings need both water and air.

52
Germination and Seedling Growing Medium

Capacity to supply plant nutrients

Vermiculite, perlite, and their tropical counterpart such as
coconut coir dust and rice husk, are essentially inert and they
contribute very little if at all, to plant nutrition.

Thus, nutrient-rich materials, such as compost, manure, and
fertile soil, should be added to this nursery mix.

53
Germination and Seedling Growing Medium

Freedom from soil-borne plant pathogens

The soil contains millions of different kinds of microorganisms;
some are disease causing.

The nursery mix should retain only the beneficial types.

To achieve this the nursery mix is often sterilized, either with the
use of heat or chemicals.

54
Hot plate sterilization

The soil mix is moistened; so that the steam
generated by the heated soil serves as the
sterilant in addition to the effect of the hot
plate itself.

During sterilization, the soil is constantly
stirred to ensure even heating.

Sterilization is completed when the soil has
dried up.

55
Seedling Production and Care of Seedling

Modified seed box method or cellular method
Prepare small pots made of either used
paper, banana leaves, coconut fronds

Fill the pots with the same kind of sterilized
soil used in the seed box method

Sow 2-3 seeds in each small pot, 7-10 days
after germination, thin the seedlings to only
one per pot

56
Seedling Production and Care of Seedling
Pricking
Transfer the seedlings 7-10 days
after germination to another plot or
seed box

Water the newly pricked seedlings
and protect them from direct
sunlight

2-3 days after pricking, sprinkle the
seedbed with starter solution
57
Seedling Production and Care of Seedling

Hardening

Gradually expose the seedlings to sunlight 7-10 days after
pricking

Reduce and withhold watering until the seedlings start to
exhibit temporary wilting then re-water the seedlings

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Transplanting

Use only transplants that are healthy and
are in good condition.

Seedlings can be transplanted into the
field after 4 weeks, when they have 4-5
true leaves.

Avoid damaging roots when removing
seedlings from the seedling tray or
lokong.
59
Transplanting

Dig a small hole and place basal fertilizer.

Avoid roots in direct contact with inorganic fertilizer.

Water the seedlings in with a generous amount of water as soon
as possible after transplanting.

Transplanting is best done early in the morning or late in the
afternoon.

60
Planting Materials Selection and Preparation

Vegetative Propagules
There are certain plant modifications which are used for vegetative
propagation of plants.

These modified plant parts may be stem, root, or leaves and are
usually specialized for food storage.

61
Vegetative Propagules

Bulbs
Produced by monocotyledonous plants in
which the stem is modified for storage and
reproduction.
Bulb is a specialized underground organ
consisting of a short freshly, usually vertical
stem axis bearing at tip apex or growing
points and enclosed by thick freshly scales.
Ex: Tulip, Daffodils, Onion, Garlic, (cloves)

62
Vegetative Propagules

Tubers
A tuber is the short terminal
portion of an underground stem
which has become thickened
because of accumulation
preserved food material.

Ex: Irish potato

63
Vegetative Propagules

Tuberous roots
Certain herbaceous perennials produce
thickened roots which contain large
amount of stored food.

The tuberous roots differ from the
tubers in that they lack nodes and
internodes

Ex: Sweet potato, Dahlia. Tapioca
(Cassava). 64
Vegetative Propagules

Rhizomes
The horizontal, thick and fleshy or
slender and elongated stem growing
underground are known as rhizomes.

Rhizomes have nodes and internodes
and readily produce adventitious roots.

Ex: Ginger, Ferns, Turmeric, and
Cardamom.
65
Vegetative Propagules

Corms
A corm is solid underground base of a
stem having nodes and internodes and
is enclosed by a dry scale like leaves.

Ex: Gladiolus

66
Vegetative Propagules

Runners
Runners are specialized arial stems
(stolons) arising in the leaf axils of
plant having rosette crowns.

New plants arise from nodes at
interval along these runners.

Ex: Strawberry.

67
Vegetative Propagules

Suckers
Adventitious shoot from the
underground portion of the
stem or from their horizontal
root systems are known as
suckers, they may be utilized as
propagation materials.
Ex: Chrysanthemum, Curry leaf,
Banana.

68
Vegetative Propagules

Offsets/ offshoots
An offset is a shoot or thick stem of
rosette like appearance arising from
the base of the main stem of certain
plant.

Ex: pineapples are propagated
vegetative by separating away the
offshoots and replanting them.

69
Methods of Asexual Reproduction of Horticultural Crops

There are crops that do not produce seeds, hence they
cannot be reproduced sexually.

There are also those that are capable of producing seeds,
yet for economic reasons, convenience and expediency
they are not commonly propagated by seeds.

70
Methods of Asexual Reproduction of Horticultural Crops

Instead, they are multiplied by cuttings or using suckers and
other vegetative plant parts.

All these types of propagation techniques fall under the so
called asexual or vegetative plant propagation.

71
Asexual Reproduction of Horticultural Crops

Separation and Division
Separation uses naturally occurring vegetative structures such as
bulbs and corms. Individual bulbs or corms are separated from a
clump.

Division involves digging up the plant or removing it from its
container and cutting (dividing) the plant into separate pieces.

72
Asexual Reproduction of Horticultural Crops

Layering
Stems still attached to their parent plant may form roots where
they come in contact with a rooting medium.

This method of vegetative propagation is generally successful
because water stress is minimized, and carbohydrate and mineral
nutrient levels are high.

74
Different Types of Layering

Simple layering
Bend the stem to the ground.
Cover part of it with soil, leaving
the remaining 6 to 12 inches
above the soil.

Bend the tip into a vertical
position and stake in place.

75
Different Types of Layering

Compound layering
Bend the stem to the rooting
medium as for simple layering, but
alternately cover and expose stem
sections.

Wound the lower side of the stem
sections to be covered.

76
Different Types of Layering

Mound layering
Cut the plant back to 1 inch above
the ground in the dormant season.

Dormant buds produce new shoots
in the spring.

Mound soil over the new shoots as
they grow. Roots develop at the
bases of the young shoots.
77
Different Types of Layering

Air layering
Ring of bark is removed from the
stem.

Scrape the newly bared ring to
remove the cambial tissue in order
to prevent callus from forming.

After the rooting medium is filled
with roots, sever the stem below.
78
Asexual Reproduction of Horticultural Crops

Budding and Grafting
Budding and grafting are methods of asexual propagation that
join parts of two or more different plants together, so they
unite and grow as one plant.

These techniques are used to propagate cultivars that do not
root well from cuttings or to alter some aspect of the plant (for
example, to create weeping or dwarf forms).

79
Asexual Reproduction of Horticultural Crops

Budding and Grafting
The scion consists of a short stem piece with one or more buds and is
the part of the graft that develops into the top of the grafted plant.

The rootstock (also called stock or understock) provides the new
plant's root system and sometimes the lower part of the stem.
Seedling rootstocks are used commonly.

80
Asexual Reproduction of Horticultural Crops

Budding
Budding, or bud grafting, is the union of one bud, with or without a small
piece of bark, from one plant (scion) onto a stem of a rootstock.

It is especially useful when scion material is limited.

Budding is usually done during the growing season when the bark is
slipping (soft and easy to peel back from the cambium).

81
Common types of Budding
Asexual Reproduction of Horticultural Crops

Grafting
Grafting is the union of the stems of two plants to grow as one.

There are several kinds of grafting; which method to use depends on the
age and type of plants involved.

83
Common types of Grafting
Asexual Reproduction of Horticultural Crops

Budding and Grafting

Six conditions must be met for bud grafting to be successful:

The scion and rootstock must be compatible (capable of uniting).
The scion and stock plant must be at the proper physiological stage of
growth.
The cambial region of the scion and the stock must be in close contact -
touching if possible.

85
Asexual Reproduction of Horticultural Crops

Budding and Grafting
Proper polarity must be maintained (the buds on the scion must be
pointed upward).

Immediately after grafting, all cut surfaces must be protected from
drying out.

Proper care must be given to the graft after grafting.

86
Asexual Reproduction of Horticultural Crops

Micropropagation (Tissue Culture)
The use of tissue culture techniques
to propagate plants from very small
plant parts.

The small plant part is grown
(cultured) in a sterilized container
with a culture medium and precise
environmental conditions.

87
Cultural Management
Practices

88
Cultural Management Practices

Mulching
To control soil temperature, either by
keeping it cool or keeping it warm;

Prevent loss of soil moisture;

to control weeds by shading them and
diseases by preventing soil contact
with the plant foliage.

Some reflective mulches are said to be
effective in repelling insects. 89
Cultural Management Practices

Staking or Trellising
With few exceptions, all viny
vegetables are staked.

There are three types of plants
for purposes of staking:
a. Plants with special structures
such as tendrils;
b. plants that twine
c. plants that do not have the
natural ability to climb.

90
Cultural Management Practices

Staking or Trellising

Staking facilitates management operations, such as irrigation,
intertillage, pest control, and harvesting.

It also helps produce better products

Training or repositioning of the vines is done with viny crops that
are grown under prostrate culture (without stakes) to prevent
overcrowding in some spots in the field.

91
Cultural Management Practices

Staking or Trellising

In insect-pollinated crops, such as watermelon and squash, dense
vines and foliage may interfere with insect activity and reduce fruit
set.

In staked crops, training is necessary in the initial stages to keep
the vines off the ground.

92
Cultural Management Practices

Shading

Sunlight is the primary energy source
plants use in photosynthesis to convert
carbon dioxide and water into sugars,
which the plant uses to make stems,
leaves, roots, and fruits.
However, if the leaves or fruit are exposed
to harmful ultraviolet radiation or they
accumulate too much light radiation,
damage to cells and tissues occurs.
93
Cultural Management Practices

Shading

Shade cloth and nets impacts air and fruit surface temperature as
well as incoming solar radiation.
Shading also alters plant architecture. Plants grown under shade
are taller, have larger leaves, and possibly more nodes.
Shading increases relative humidity under the structure and
decreases wind.
An increase in relative humidity decreases evaporation which
causes soil and plants to retain more moisture under shade.

94
Cultural Management Practices

Pruning

Reduces stored carbohydrates and leaf
area available for carbohydrate
production

temporarily arrest apical dominance

excessive top pruning stimulates
vegetative growth and suppresses
flowering but root pruning increases
flowering. 95
Cultural Management Practices

Pruning

It is a horticultural practice involving the selective removal of certain
parts of a plant, such as branches, buds, roots, fruits or flowers.

It is done to strike a balance between vegetative and reproductive
growth.

Making them safe, healthy, productive, and aesthetic is the most
concerned reason to prune plants.

96
Cultural Management Practices

Pruning

Pruning can manipulate branching habit and influence the hormones
involved in growth of plant.

Increases uptake of water and nutrients by the remaining shoots and
buds, which results to flushing and rejuvenation in old trees.

Increases the amount of light penetrating the canopy resulting to higher
rate of photosynthesis

97
Cultural Management Practices

Types of Pruning

Formative pruning - method of pruning during the early years of a tree
to establish a framework of branches.
Corrective pruning- removal of dead, pest infected/infested parts and
damage plant parts
Preventive pruning - used to help mitigate the risks from tree defects
promoting good structure, making trees more resistant to storms and
other natural forces.
Rejuvenation- reinvigorate old and non-productive crops and involved
heavy pruning.
98
Cultural Management Practices

Pruning Cuts

Heading back removes the
terminal portion of shoots or
limbs.

By removing apical dominance,
heading out stimulates regrowth
near the cut.

99
Cultural Management Practices

Pruning Cuts

Thinning out removes an entire
shoot or limb to its point of
origin from the main branch.

As a result, new growth occurs at
the undisturbed shoot tips while
lateral bud development and
regrowth is suppressed.

100
Cultural Management Practices

Fruit Thinning

To control fruit size, some fruits are
removed before they enlarge.

Some plants, particularly cucurbits,
produce female flowers and set fruit so
early that vegetative growth is still
insufficient to support the normal
growth of the fruit.

101
Cultural Management Practices

Fruit Thinning

To promote the formation of bigger and
better fruits, the first one or two fruits on
the vine is removed.

The number of fruits per vine is
subsequently limited to one. The
practice of fruit thinning is widely used in
melons and watermelons

102
Cultural Management Practices

Training

Establish a strong tree framework

Facilitate management of tree and crop

Harvest sunlight efficiently

Maintain productivity by renewing
fruiting wood

103
Cultural Management Practices

Training

Open center- vase pruning shapes a tree to
a short trunk and three or four main limbs,
each with several lateral branches.

This style creates an open center that allows
light and air to reach all branches and
promotes fruiting on the interior and lower
branches.

104
Cultural Management Practices

Training

Central leader- in central leader training, the
dominant upright branch (trunk) is promoted,
and other branches are allowed or forced to
grow at an angle from it, somewhat resembling
a Christmas tree

105
Cultural Management Practices

Training

Modified central leader - Trees are trained to a
single, upright trunk with evenly paced limbs
until they reach a desired height, usually 6 to 10
feet.

At that point, you prune out the leader and
maintain the tree at that height.

All fruit trees can be trained to this form.
106
Irrigation and Drainage

107
Irrigation and Drainage

Water Management

Refers to the regulatory or control system employed in the farm
in which water is made available to crops at the time it is
needed.

Also deals with drainage

Water supply – rainfall or irrigation

108
Irrigation and Drainage

Crop Water Requirement

Total amount of water required to bring a crop to complete its life cycle
Represents a fraction used by plant for hydration and biological
processes.
Greater amount is lost due to evaporation, transpiration, runoff and
percolation.
Evaporation is greater when the crop is still young
Shading reduces evaporation

109
Irrigation and Drainage
Transpiration

loss of water from the plant in vapor form
A necessary evil
plant transpire because the vapor pressure of the leaf is greater than
that of the surrounding air
could be stomatal, cuticular or lenticular
main bulk of water loss from plants is by stomatal transpiration

110
Irrigation and Drainage

Transpiration

Beneficial effects:

Stabilization of plant body temperature

Enhanced rate of nutrient absorption from the soil

111
Irrigation and Drainage

Evapotranspiration

The sum of transpiration and
evaporation water lost to the
atmosphere in gaseous form
from soil and water surfaces
and from plant surfaces.

112
Irrigation and Drainage

Factors Affecting Evapotranspiration

Temperature: Transpiration rates go up as the temperature goes up,
especially during the growing season, when the air is warmer due to
stronger sunlight and warmer air masses.

Relative humidity: As the relative humidity of the air surrounding the
plant rises the transpiration rate falls.

Wind and air movement: Increased movement of the air around a plant
will result in a higher transpiration rate.
113
Irrigation and Drainage

Factors Affecting Evapotranspiration

Soil-moisture availability: When moisture is lacking, plants can begin to
senesce (premature aging, which can result in leaf loss) and transpire less
water.

Type of plant: Plants transpire water at different rates. Some plants
which grow in arid regions, such as cacti and succulents, conserve
precious water by transpiring less water than other plants.

114
Irrigation and Drainage

Irrigation
The artificial application of water

Different types of irrigation system:
a. Surface Irrigation
b. Sub-surface irrigation
c. Spray irrigation
d. Trickle system

115
Irrigation and Drainage

Irrigation Methods

Surface Irrigation: applying water at the soil surface, via furrow and
flooding About 90% of the irrigated areas in the world are by this
method.

Sprinkler Irrigation: Applying water under pressure. About 5 % of the
irrigated areas are by this method.

116
Irrigation and Drainage

Irrigation Methods

Drip or Trickle Irrigation: Applying water slowly to the soil ideally at the
same rate with crop consumption.

Sub-Surface Irrigation: Flooding water underground and allowing it to
come up by capillarity to crop roots.

117
118
 LEPA- Low Energy
Precision Application

LESA- Low Elevation
Spray Application
Irrigation and Drainage

Irrigation Methods

Drip or Trickle Irrigation: Applying water slowly to the soil ideally at the
same rate with crop consumption.

Sub-Surface Irrigation: Flooding water underground and allowing it to
come up by capillarity to crop roots.

121
Irrigation and Drainage

Factors Affecting Irrigation Requirements

Stage of growth of the crop
Type of crop
Depth of the absorbing system
field capacity of the soil
Soil structure

122
Irrigation and Drainage

Drainage

The removal of excess water from the soil root zone reservoir

Detrimental effects of poor drainage:
a. Reduction of oxygen in the soil
b. predisposes the plants to diseases
c. reduction in stem growth
d. Yellowing of leaves
e. Twisting of petioles and production of adventitious roots

123
Irrigation and Drainage

Drainage Methods

Surface drainage

This method eliminates ponding, prevents prolonged saturation, and
accelerates the flow to an outlet without siltation or erosion of soil.

In some cases, orientation of row crops with the land slope may
accomplish this purpose.

124
Irrigation and Drainage

Drainage Methods

Subsurface drainage

Lowers the high-water table caused by precipitation, irrigation water,
leaching water, seepage from higher lands, irrigation canals, and
ditches.

125
Soil Nutrient Management
Soil Nutrient Management

Soil productivity is defined as the capability of soil to
produce a specific crop (or sequence of crops) under a
specific management system which includes planting
date, fertilization, irrigation schedule, tillage, and pest
control.

127
Soil Nutrient Management

Soil productivity is an economic concept which considers
inputs (a specified system of management), output (yields
of particular crops), and soil type.

Soils differ in their capacity to absorb management inputs
on a given type of soil for maximum profit.

128
Soil Nutrient Management

A soil must be fertile to be productive; however,
some fertile soils are not necessarily productive.

For instance, many fertile soils in the arid regions
are not considered productive for vegetable crops
because of lack of irrigation.

129
Soil Nutrient Management

Factors Determining Fertilizer Needs

When a fertilizer is applied, it contacts the
soil and the crop and undergoes some
changes.

The fertilizer reacts with the soil and its
efficiency to supply nutrients either
increases or decreases depending on
some conditions.

130
Factors Determining Fertilizer Needs

Kind of crop

The economic value, the nutrient removal, and the
absorbing ability of the crop should be considered.

High-value vegetables can be fertilized heavily to ensure
high yields.

131
Factors Determining Fertilizer Needs

Precipitation

Rainfall affects the availability of the
nutrients to the plant; between the
time it is applied and the time the
nutrients are used by the plant.

132
Factors Determining Fertilizer Needs

Temperature

It affects the release of nitrogen, phosphorus, and sulfur
from organic matter.

Likewise, it affects nitrification and absorption of
phosphorus and potassium by plants.

133
Factors Determining Fertilizer Needs

Nutrient Mobility

Mobile nutrients are usually translocated to the growing sections when
intake is limited, leaving a deficiency symptoms to the older leaves.

Immobile nutrients, cannot be translocated within the plant, resulting in
deficits in the younger leaves.

134
Factors Determining Fertilizer Needs

Nutrient Mobility

Mobile nutrients: Nitrogen, Potassium, Phosphorus and Magnesium

Immobile nutrients: Sulfur, Calcium, Iron, Molybdenum, Manganese,
Boron and Zinc

135
Soil Nutrient Management

Soil Testing

To effectively manage soil nutrients,
optimize productivity, and save
expenses, soil testing is required.

The results of soil tests reveal the state of
numerous chemical aspects of the soil.

Nutrient levels, soil pH, CEC, and percent
base saturation are among them. 136
Soil Nutrient Management
Association of Colleges of Agriculture in the Philippines, Inc.

Lime Application

The pH of a soil is a good chemical
indicator of its quality.

Liming to adjust pH to the levels
required by the crop to be grown
can enhance the soil quality of acid
soils.

137
Soil Nutrient Management

Organic fertilizers

Such as manure and plant waste, are
by-products of everyday living.

They deliver nutrients in a slow-release
form that lasts longer in the soil.

The nitrogen is usually in a complicated
organic structure that is difficult to
dissolve in water.
138
Soil Nutrient Management

Inorganic fertilizers

Usually far more concentrated than
organic fertilizers, which are made from a
variety of sources.

The available nutrients are usually quite
soluble, and if they aren't provided
appropriately, they can quickly drain
from the soil.

139
Soil Nutrient Management

Method of application

One important factor to consider in the efficient use of
fertilizers is the placement of the material in relation to
the plant.

The fertilizer should be placed in the soil zone where it
will serve the plant to the best advantage.

140
Soil Nutrient Management

Method of application

There are three important considerations in determining the proper
application method:

1. The efficient use of the nutrients from the time of plant emergence
to maturity
2. Prevention of salt injury to the seedling
3. Convenience of the grower

141
Method of Application

Broadcast -The fertilizer is applied uniformly over the field before
planting. It is then incorporated by tilling or cultivating.

Banding -The fertilizer is applied in bands on one side, both sides,
or below the seeds or transplant. Care should be taken not to
injure the seedlings through contact with the fertilizer.

142
 Method of Application

Topdressing or side-dressing -Topdressing means broadcasting the
fertilizer on the crop, while side-dressing means applying the
fertilizer beside the rows of the crop. Both are done after crop
emergence.

Fertigation -This is the application of fertilizer through the irrigation
water. Nitrogen and sulfur are the principal nutrients commonly
used.

144
145
Method of Application

Foliar application-This method can
be used with fertilizer nutrients
readily soluble in water.

It is also used when there is a soil-
fixation problem. In this method,
however, it is difficult to apply
sufficient amounts of the major
elements.

146
Pest Management

147
Pest Management

Pest
Defined as plant or animal or any other organism that is detrimental to a
crop.

Major Types of Pests:
a. Pathogens
b. Insects and Mites
c. Vertebrate Pests
d. Weeds

148
Pest Management

Pathogens
Microorganisms which cause diseases
or abnormalities in susceptible plants
under certain environmental conditions

fungi, bacteria, viruses, mycoplasma
and nematodes.

149
Pest Management

Pathogens’ Mode of Action
Killing host cells or slowing down their metabolism with their toxins.
Blocking the passage of food, water or nutrients.
Absorbing or consuming the cell contents
Taking over the genetic control of the plant cells causing the
multiplication of viral cells.
Multiplying on the surface of the leaves, fruits and stems.
Blocking the sunlight and slowing down the diffusion of gases.

150
Pest Management
Insects and Mites
Reduces the area for Photosynthesis and
quality of the produce

They eat or tear portions of plants; or pierce or
suck cell sap

They also serves as vector for plant pathogens

Induces growth abnormalities in plants
through toxins
151
Pest Management

Weeds
Defined as an undesirable plant

Characteristics of weeds:
a. Easy to germinate
b. Fast growing
c. Deep-rooted and resistant to most
diseases and insect pests
d. Competes for light, nutrients &moisture
e. Alternate host for insects and diseases

152
Pest Management

Vertebrate pests

includes rats, birds, wild and
domestic animals are common
vertebrate pests in the tropics.

Rats are the most destructive
vertebrate

153
Pest Management

Parameters of pest population levels

Economic injury level
Lowest population density that will cause economic damage

Economic threshold
Population size large enough to trigger an action to prevent an
increasing pest population from reaching economic injury level

154
Pest Management

Factors Affecting Pest incidence

Nutritional/ physiological conditions of the plants
Nutrition either improve the resistance or increase susceptibility of plants

Drought causes plant to develop thick cuticles

Climate – macro and microclimate affects incidence, population
dynamics and persistence of pest

Introduction of new crops or new pests.
155
Pest Management

Integrated Pest Management (IPM)

a pest control strategy that uses a variety of complementary strategies
including: mechanical, physical, genetic, biological, cultural
management, and chemical management.

156
Pest Management

Integrated Pest Management (IPM)

strives to enhance health and eventual productivity of the crops and
maintain the integrity of the environment

does not rely solely on one particular method; considers all possible
means of regulating pest population

157
Pest Management
Advantages of an IPM program

Protects environment through elimination of unnecessary pesticide
applications

Improves Profitability

Reduces risk of crop loss by a pest

Peace of Mind

158
Pest Management

Disadvantages of an IPM program

Requires a higher degree of management

More labor intensive

Success can be weather dependent

159
Pest Management

Important considerations in producing a sound IPM strategy

Proper identification of Pest

Learn pest and host life cycle and biology

Monitor or sample environment for pest population

Establish action threshold

160
Pest Management

General Principles of Integrated Pest Management

Prevention and Suppression

The prevention and/or suppression of harmful organisms should be
achieved or supported among other options especially by crop
rotation, use of adequate cultivation techniques, use of
resistant/tolerant cultivars

161
Pest Management
General Principles of Integrated Pest Management

Monitoring

Harmful organisms must be monitored by adequate methods and tools,
where available.

Such adequate tools should include observations in the field as well as
scientifically sound warning, forecasting and early diagnosis systems,
where feasible, as well as the use of advice from professionally qualified
advisors.
162
 Pest Management

General Principles of Integrated Pest Management

Decision-making

Based on the results of the monitoring the professional user must decide
whether and when to apply plant protection measures.

163
Pest Management

General Principles of Integrated Pest Management

Non-chemical methods

Sustainable biological, physical and other non-chemical methods must
be preferred to chemical methods if they provide satisfactory pest
control.

164
Pest Management

General Principles of Integrated Pest Management

Pesticide selection

The pesticides applied shall be as specific as possible for the target and
shall have the least side effects on human health, non-target organisms
and the environment.

165
Pest Management
General Principles of Integrated Pest Management

Anti-resistance strategies

Where the risk of resistance against a plant protection measure is known
and where the level of harmful organisms requires repeated application
of pesticides to the crops, available anti-resistance strategies should be
applied to maintain the effectiveness of the products.

This may include the use of multiple pesticides with different modes of
action.
166
Pest Management

Evaluation

Based on the records on the use of pesticides and on the
monitoring of harmful organisms the professional user should
check the success of the applied plant protection measures.

167
Components of IPM Strategies

Varietal resistance
use of high yielding and resistant varieties

Biological control
living organisms such as pathogens, predators and parasites are used to
suppress pest population.

Advantages:
a. permanence in control
b. nontoxic residues involved
c. less disrupting to non-target organisms
168
Components of IPM Strategies
Biological control

is the reduction of pest numbers by predators,
parasites and pathogens to levels lower than
that would occur in their presence

Three living organisms of biological control
a. predators
b. parasitoids
c. pathogens/entomopathogens

169
Components of IPM Strategies

Physio-cultural control
reduction of pest population by making the
male insect's sterile thru exposure to cobalt
radiation

Cultural method
Includes sanitation, rouging, thinning out
removal of all fruits left in the field, disking
and harrowing, fallowing, crop rotation,
intercropping, cover cropping

170
Components of IPM Strategies

Physical control
flaming and smoking, physical irritants
( scarecrow), sound waves, physical
attractants (light),physical barriers
(metal collar for coconut and bagging
for fruits)

Chemical Control
The most common method of pest
control is the use of pesticides
chemicals that either kill pests or inhibit
their development. 171
Components of IPM Strategies

Regulatory Control

fundamental regulatory control principles involve preventing the entry
and establishment of foreign plant and animal pests in a country or area
and eradication, control and suppression of pests already established in a
limited area

172
Cropping Systems

173
Cropping Systems

The crop production activity of a farm

Comprises all cropping patterns grown on the farm and their
interaction with farm resources, other household enterprises and
the physical, biological, technological and sociological factors or
environments.

174
Cropping Systems

Objectives of Cropping System

Efficient utilization of all resources land, water and solar radiation
maintaining stability in production and obtaining higher net returns

The efficiency is measured by the quantity of produce obtained per unit
resource in a unit time

175
Cropping Systems

Basic Principle of Cropping Systems

Choose crops that complement each other

Choose crops and a cropping rotation which utilize available resources
efficiently

Choose crops and cropping that maintain and enhance soil fertility

176
Cropping Systems

Basic Principle of Cropping Systems

Choose crops which have a diversity of growth cycle

Choose a diverse species of crops

Keep the soil covered

Strategically plan and modify the cropping system as needed

177
Cropping Systems
Benefits of Cropping Systems

Maintain and enhance soil fertility

Enhance crop growth

Minimize spread of disease

Control weeds

178
Cropping Systems

Benefits of Cropping Systems

Inhibit insect and pest growth

Increase soil cover

Reduce risk for crop failure

Use resources more efficiently

179
Cropping Systems

Monocropping

refers to the presence of a single crop in a field.

This term is often used to refer to growing the same crop year
after year in the same field;

this practice is better described as continuous cropping, or
continuous monocropping.

180
Cropping Systems

Monocropping

Advantages Disadvantages
Treat the whole area the it is difficult to maintain cover
same on the soil;
Fewer kinds of equipment it encourages pests, diseases
needed and weeds; and
Economically efficient it can reduce the soil fertility
system and damage the soil
structure

181
Cropping Systems

Multiple Cropping or Polycropping

It is a cropping system where
two or more crops are grown
annually on the same piece of
land.

182
Cropping Systems

Multiple Cropping or Polycropping Advantages

maximizing returns from limited resources
Increase food security and farm income
Improve soil cover
Increase soil fertility
Biodiversity enhancement

183
Cropping Systems

Multiple Cropping or Polycropping Advantages

Erosion control
Reduced downstream flooding/siltation
Reduced groundwater pollution
Control pest
Increase crop yield

184
Cropping Systems

Multiple Cropping or Polycropping Disadvantages

Competition is higher
Increase labor constraints
Require skilled workers
Requires better knowledge
Crop choice
Possible Allelopathy

185
Cropping Systems

Types of Multiple Cropping or Polycropping
Intercropping
Crop rotation
Sequential cropping
Multi-storey cropping
Contour cropping
Alley cropping
Sorjan cultivation
SALT cropping system

186
Cropping Systems

Intercropping

This means growing a two or more crops simultaneously in
alternate in rows or sets of rows in the same piece of land.

It is possible to do this in different ways:
a. Row intercropping
b. Mixed intercropping
c. Strip intercropping
d. Relay intercropping

187
Cropping Systems

Intercropping
Row intercropping - growing two or more crops in well-defined
rows

Mixed intercropping - the seeds of two or more crops are sown
in a field without any particular arrangement

188
Row intercropping Mixed intercropping

189
Cropping Systems

Intercropping
Strip intercropping - is the production of more than one crop in
strips that are narrow enough for the crops to interact, yet wide
enough to permit independent cultivation

Relay intercropping - is a kind of intercropping in which two or
more crops grow simultaneously during part of the life cycle of
each

190
Strip intercropping Relay intercropping

191
Cropping Systems

Crop Rotation

This means changing the type of
crops grown in the field each
season or each year (or changing
from crops to fallow)

192
Crop Rotation Pattern
Cropping Systems

Sequential cropping

Growing of two or more crops in sequence on the same field
within a 12 month period, with the succeeding crop planted only
after the preceding crop has been harvested such that a farmer
managed only one crop at any time on the same field.

194
Sequential Cropping Pattern

195
Cropping Systems

Multi-storey Cropping

to accommodate two or more crops of different heights, canopy
patterns and rooting system, to maximize the use of available
sunlight, nutrients, moisture and land area the fundamental
objective is to increase the yield and income

196
Multi-storey Cropping

197
Cropping Systems

Sorjan cultivation

System of crop cultivation in parallel beds and sinks wherein
lowland crops are planted in the sinks and upland crops are
grown in beds

Two successive upland crops can be grown in beds during the
year and the rice crops in the sinks

198
Sorjan Cropping

199
Cropping Systems

SALT Cropping System (Sloping Agricultural Land Technology)

Can prevent soil erosion, improves soil fertility and provides a
continuous income from diverse crops planted on the hilly land

200
SALT Cropping System 201
Cropping Systems

Alley Cropping

defined as the planting of rows of trees (nitrogen-fixing plants)
at wide spacings, creating alleyways within which agriculture or
horticultural crops (annual or perennial) are produced

is a simple technique that restores nitrogen to the top layer of
soil so that farmers can use the same piece of land year after
year to grow their crops.

202
Alley Cropping
203
Postharvest Handling

204
 Postharvest Handling

Covers the series of procedures, operations, steps or
movements undertaken in order to control changes in harvested
crops, including the technological aspects of marketing and
distribution.

205
Farm to market value chain

206
Postharvest Handling
Importance of proper postharvest management
Reduce postharvest losses:
a. 10-50% of production (average of 35% = 35.52 billion PHP)
b. 1% loss reduction=355.2 million PHP gain in productivity

Causes of loss:
a. Technical – improper handling, high temperature, diseases
b. Non-technical – lack of infrastructure, inadequate policies, socio-
economic factors

207
Postharvest Handling

Proper postharvest management contributes to

food security
increasing income and employment opportunities
reducing price volatility of fruits and vegetables
reducing the impact of increasing urbanization
meeting consumers’ needs

208
Postharvest Handling

Harvest maturity

Essential to optimize quality for consumers and postharvest life
Harvest too immature:
poor taste and flavor
fruit will not ripen-susceptible to water loss
susceptible of damage
susceptible to pathogens

209
Postharvest Handling

Harvest maturity

Harvest too mature
short shelf life
poor texture; soft fruit
overripe taste and off flavor
susceptible to pathogens

210
Postharvest Handling

Types of Maturity

Physiological maturity

state of development when the commodity has attained maximum
growth and development

Commercial maturity
state of development when the plant part possesses the necessary
characteristics preferred by consumers.

211
 Growth Maturation Ripening Senescence

Inflorescence
Fully developed fruits
Broccoli, cauliflower,
Tips and Tops Tomato, pineapple, banana,
banana blossom, squash
sweet potato, kangkong, squash
asparagus, celery, pechay,
squash Partially developed fruits
Sprouts Cucumber, green beans, sweet Storage roots and seeds
mungbean, radish, peas, okra, sweet corn, jackfruit,
sweet potato, sugar
mustard squash
beet, radish

Farm to market value chain
Source: Esguerra and Bautista, 2007
APO National Training Courses on
Postharvest Operations for Vegetables, Fruits and Meat 212
Postharvest Handling

Maturity Indices

Signs or indications of the readiness of the plant for harvest

Types of indices:
a. Subjective – uses the senses, appearance, touch, smell, resonance, sweetness
b. Objective – measurable indices, chemical constituents, computation,
dimensional fullness of finger (banana)

213
Different types of maturity index

214
Postharvest Handling

Maturity Indices

Skin color
This factor is commonly applied to fruits, since skin color changes as
fruit ripens or matures. Some fruits exhibit no perceptible color change
during maturation, depending on the type of fruit or vegetable.

215
Postharvest Handling

Maturity Indices

Shape
The shape of fruit can change during maturation and can be used as a
characteristic to determine harvest maturity.

For instance, a banana becomes more rounded in cross-sections and
less angular as it develops on the plant.

216
Change in Shape

Light Light full Full three Full Immature Mature
three three quarters quarters
quarters

Banana hand Banana caliper

217
Postharvest Handling

Maturity Indices
Aroma
Most fruits synthesize volatile
chemicals as they ripen.

Such chemicals give fruit its
characteristic odor and can be used
to determine whether it is ripe or
not.

218
Postharvest Handling

Maturity Indices
Abscission
As part of the natural development of a
fruit an abscission layer is formed in the
pedicel.

219
Postharvest Handling

Maturity Indices

Acoustics (Resonance)
Watermelon, jackfruit or durian
produced hollow sound when gently
tapped by hand; commercial
acoustic and resonance detectors
developed for mechanical grading.

220
Postharvest Handling
Minimum SSC (%) for selected fruit

Apple 10
Cherry 14-16
Maturity Indices Kiwifruit 6.2
Soluble solids content (SSC) Litchi 16-17
Papaya 15
sugar content; use of refractometers Pineapple 12
ranges 0-5, 0-20, 10-50; need regular Watermelon 10
calibration

221
Postharvest Handling

Maturity Indices

Acidity
measured by titration; sugar to acid ratio (SSC:acid) often better related
to fruit palatability than either SSC or acid level alone.

222
Postharvest Handling

Maturity Indices
Firmness
Use of penetrometer/pressure
tester; best to automate to
remove bias of individual
testers For sweet corn

For mangoes For apples plus starch test

223
Postharvest Handling
1 = Full starch (all blue-black)
Maturity Indices 2 = Clear of stain in seed cavity
and halfway to vascular area
Starch content 3 = Clear through the area
including vascular bundles
Iodine test (iodine reacts with 4 = Half of flesh clear
starch resulting in blue to black 5 = Starch just under skin
color); 2% iodine solution 6 = Free of starch (no stain)

Source: Sivakumar and Korsten, 2007 224
Postharvest Handling

Harvesting method

Proper harvesting/picking essential to avoid physical injury

Use appropriate harvesting tools and containers

Educate pickers about techniques and safety during harvesting

225
Postharvest Handling

Manual harvesting

common in Asian countries

labor and time consuming

advantageous to minimize physical injury & for selective harvesting

226
Postharvest Handling

Mechanical harvesting

shake and catch action
could save labor and management costs as high as 30-45%
increases physical injury
increases cost in culling undesired produce and foreign matter
only recommended for large-scale operations where labor is
scarce & expensive.

227
Postharvest Handling

Harvesting Time
The time of the day when harvesting is done has impact on
produce quality.

Harvesting at cooler time of the day minimizes product heat load &
increases worker efficiency.

Harvesting when sun is up exposes produce to high temperature,
so they must transfer to a shaded area and allowed to dissipate
heat.

228
Packinghouse Operations
Freshly
Cooling
harvested fruit

Air-drying
Unloading
Hot water
treatment

Reject fruit in
Sizing
plastic crates

Empty
bamboo
Maturity baskets
testing
Empty plastic
Packed fruit
crates Packaging for
transport to
market

Immature
batch of fruits
Sorting / trimming/
Weighing delatexing Temporary
holding
229
Thank You for Listening

230