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Tomato
Cultivation (Lycopersicon esculentum Mill.)
I.
INTRODUCTION
1.1.
History of Tomato Dissemination
The
word tomato originates from the Aztec language—one of the Native
American tribes—from the terms xitomate or xitotomate. Tomato
plants originated in Peru and Ecuador, then spread throughout the Americas,
especially in tropical regions, as weeds. Their dissemination was facilitated
by birds that consumed tomato fruits and dispersed the seeds through their
droppings. Tomatoes were later introduced to Europe and Asia by the Spanish. In
Indonesia, tomatoes began to be cultivated following the arrival of the Dutch.
Since then, tomato plants have spread across the world, both in tropical and
subtropical regions.
1.2.
Major Production Centers
Major
tomato cultivation centers worldwide include Japan, China, and Taiwan, while in
Indonesia the primary center is the Malang area. The adjacent image shows an
example of tomato cultivation in a greenhouse in Gunma Prefecture, Japan.
1.3.
Plant Types
Tomato
is an annual plant with a lifespan of approximately four months.
The
botanical classification is as follows:
- Division: Spermatophyta
- Subdivision: Angiospermae
- Class: Dicotyledonae
- Order: Solanales
- Family: Solanaceae
- Genus: Lycopersicon
- Species: Lycopersicon
esculentum Mill.
Among
the many available tomato varieties, the ones most commonly cultivated by
farmers include Ratna, Berlian, Precious 206, Kingkong, and Intan. Field
surveys indicate that Artaloka is the variety most frequently used.
1.4.
Benefits of Tomatoes
Tomatoes
provide significant health benefits because they contain essential vitamins and
minerals needed for growth and overall well-being. Tomato fruits also contain
carbohydrates, proteins, fats, and calories. As a versatile commodity, tomatoes
are used as vegetables, culinary spices, fresh fruits, appetite enhancers,
beverages, food colorants, as well as ingredients in cosmetics and
pharmaceuticals.
II.
GROWTH REQUIREMENTS
2.1.
Climate
- The optimal annual rainfall
for tomato growth is 750–1,250 mm. This is closely related to soil water
availability, especially in areas without proper irrigation. Excessive
rainfall may hinder pollination.
- Insufficient sunlight
increases the plant’s susceptibility to diseases, both parasitic and
non-parasitic. High-intensity sunlight enhances the production of vitamin
C and carotene (provitamin A). Maximum nutrient absorption occurs when
tomatoes receive 12–14 hours of light per day, with a preferred intensity
of 0.25 mj/m² per hour. The image above shows two Indonesian trainees
working in a tomato farm in Gunma Prefecture, Japan.
- The optimal daily temperature
for tomato growth is 18–29°C during the day and 10–20°C at night. In
countries with four seasons, heaters are used during winter; the warm air
is distributed through flexible white ducts inside the greenhouse.
- A high relative humidity of
around 25% stimulates growth in young tomato plants because CO₂
assimilation is improved by wider stomatal openings. However, high
humidity also promotes the development of plant pathogens.
2.2.
Growing Media
- Tomatoes can grow in various
soil types—from sandy soils to fertile sandy loam soils—provided they are
friable, rich in organic matter, contain sufficient nutrients, and allow
good water percolation. Tomato roots are sensitive to oxygen deficiency;
therefore, stagnant water must be avoided.
- Soil pH between 5.5 and 7.0 is
ideal for tomato cultivation.
- Tomato cultivation should
preferably be carried out on flat land, eliminating the need for terraces
or embankments.
2.3.
Altitude
Tomatoes
can grow at various altitudes—both in highlands and lowlands—depending on the
variety. Suitable highland varieties include Berlian, Mutiara, and Kada.
Suitable lowland varieties include Intan, Ratna, Berlian, LV, and CLN. Some
varieties perform well in both lowland and highland areas, such as GH 2, GH 4,
Berlian, and Mutiara.
III.
TECHNICAL GUIDELINES FOR CULTIVATION
3.1.
Seedling Preparation
3.1.1.
Seed Requirements
Technical
criteria for selecting tomato seeds include:
a)
Choose intact seeds without defects or injuries, as damaged seeds generally
show poor germination.
b)
Select healthy seeds free from signs of pest or disease infestation.
c)
Ensure seeds are clean and free of impurities.
d)
Avoid wrinkled seeds.
3.1.2.
Seed Procurement
Tomato
seeds may be obtained by purchasing certified high-quality seeds from reputable
agricultural suppliers or by producing seeds independently.
3.1.3.
Seed Nursery Techniques
Selected
seeds must be disinfected before sowing by soaking them in a fungicide solution
to eliminate pathogenic microorganisms. There are several nursery methods:
- Method 1: Seeds are evenly broadcast on
the nursery bed surface and covered with a thin layer of soil.
- Method 2: Seeds are sown in furrows
spaced 5 cm apart and 1 cm deep.
- Method 3: Seeds are planted directly in
polybags filled with a 1:1 mixture of soil and manure, with one seed per
polybag.
After
sowing, the medium should be moistened.
3.1.4.
Nursery Maintenance
Nursery
maintenance must be carried out intensively during early growth. Activities
include:
- Watering twice daily (morning and
afternoon) using a fine-holed sprinkler.
- Weeding by manually removing weeds as
needed.
- Fertilizing with additional NPK after
seedlings emerge.
- Pest and disease control, including soil sterilization
and the application of insecticides (for insects) and fungicides (for
fungal infections). Examples: Furadan 3G, Dithane, Hostathion, and
Antracol.
3.1.5.
Transplanting
Seedlings
can be transplanted 30–45 days after sowing. Select seedlings that are
vigorous, upright, fresh-looking, and free from pests and diseases.
Transplanting should be done in the morning or late afternoon to prevent
wilting.
Transplanting
methods:
- Pull-out method — seedlings are carefully
uprooted after moistening the bed.
- Soil-ball method — seedlings are lifted with
surrounding soil after watering.
- Polybag method — seedlings are removed along
with the soil by tearing the polybag.
3.2.
Soil Preparation
3.2.1.
Timing
Soil
preparation must align with nursery duration. Nursery takes 30–45 days, while
intensive soil preparation requires 21 days. Begin land preparation 1–2 weeks
after sowing seeds.
3.2.2.
Land Preparation
Three
stages are involved:
- First stage: Deep plowing (25–30 cm) using
animal-drawn plows or tractors. Soil is left for one week for aeration and
oxidation.
- Second stage: Shallow hoeing to achieve
friable soil structure; leave for another week.
- Third stage: Application of
well-decomposed manure (15–20 tons/ha), followed by shallow hoeing to mix
thoroughly.
3.2.3.
Bed Formation
Beds
are oriented east–west for optimal sunlight distribution. Bed size: width 1–1.2
m, height 30–45 cm (higher during rainy season). Furrows: width 20–30 cm, depth
30 cm. Surrounding drainage canals: width 50 cm, depth 50 cm.
3.2.4.
Liming
Apply
lime (quicklime, carbonate lime, or hydrated lime) to acidic soils during land
preparation. Liming improves soil structure, stimulates microbial activity,
reduces toxic substances, and adjusts soil pH. Dosage depends on the initial
soil pH.
3.2.5.
Fertilization
Fertilization
methods:
- Broadcasting compost/manure and TSP evenly
over beds and mixing thoroughly.
- Hole application: Dig 15 cm deep holes (20 cm
diameter), apply 0.5 kg manure and 5 g TSP, then cover and mix.
3.2.6.
Mulching
Silver-black
plastic mulch is commonly used due to its practicality compared to using crop
residues.
3.3.
Planting Techniques
3.3.1.
Planting Patterns
Two
spacing systems:
- Pruned system (single stem):
Spacing:
50×50 cm or 60×60 cm. Side shoots are removed early.
- Free-growing system:
Spacing:
80×80 cm, 80×100 cm, or 100×100 cm. Side shoots are allowed to develop.
3.3.2.
Planting Holes
Prepare
planting holes (7–8 cm diameter, 15 cm deep) on mulched beds one day after
watering.
3.3.3.
Planting Method
During
the dry season, use silver-black plastic mulch; during the rainy season,
install transparent plastic roofs over the beds.
3.4.
Plant Maintenance
3.4.1.
Thinning and Replanting
Replace
dead, weak, or abnormal plants within one week after planting using reserve
seedlings of the same age.
3.4.2.
Weeding
Weeding
is necessary to prevent nutrient competition and reduce pest habitats. Weeding
frequency: 3–4 times depending on field conditions.
3.4.3.
Earthing Up
Earthing
up improves soil aeration, reduces toxic gases, and encourages healthy root
growth. Avoid damaging roots.
3.4.4.
Pruning
- Remove axillary shoots weekly
to maintain single-stem growth.
- Prune in the morning to allow
wounds to dry quickly.
- Larger shoots require clean,
sharp tools.
- Limit plant height by cutting
the top after 5–7 fruit clusters form.
3.4.5.
Fertilization
- First application: 1 week after transplanting,
apply 1–2 g of a 1:1 mixture of urea and KCl around each plant (3 cm from
stem).
- Second application: 2–3 weeks after
transplanting, apply 5 g of the same mixture (5 cm from stem).
- Third application: At 4 weeks if growth is poor,
apply 7 g (7 cm from stem).
3.4.6.
Watering and Irrigation
Tomatoes
require moderate water. Excess water causes excessive vegetative growth,
nutrient deficiency, disease susceptibility, and flower drop. Prolonged drought
causes cracking fruits and flower drop.
3.4.7.
Staking
Stakes
prevent plants from falling over.
- Stakes made of bamboo or wood
(100–175 cm).
- Install early to avoid root
damage.
- Keep stakes 10–20 cm from the
stem.
- Tie plants with the figure-8
method to avoid abrasion.
3.5.
Pests and Diseases
3.5.1.
Pests
1.
Tomato Fruit Borer (Heliothis armigera Hubner)
Characteristics:
Larvae
are approximately 4 cm long and grow longer at lower temperatures. Their color
varies from green, yellowish-green, brownish-green, brown to black. On the
sides of the body, there is a wavy longitudinal line of lighter color. The
larvae possess many tubercles and fine hairs. Eggs are round, shiny yellowish,
and after 2–4 days turn brown. Adult moths have a wingspan of about 4 cm and a
body length of 1.5–2.0 cm. The forewings are brown while the hindwings are
white with brown edges.
Symptoms:
Larvae
attack leaves, flowers, and fruits. They often bore holes into tomato fruits
and move from fruit to fruit. The damaged fruits usually become infected and
rot.
Control:
- Moths are attracted to
ultraviolet light, so UV traps can be used.
- Eggs and larvae can be
hand-collected and destroyed.
- Planting maize around the plot
helps reduce infestation.
- Remove weeds around the tomato
field.
- Spray insecticides such as
Diazinon or Cymbush.
2.
Green Aphids
Aphids
belong to the family Aphididae (order Hemiptera), often called tomato aphids,
tobacco aphids, or potato aphids. They act as vectors for viral diseases in
tomatoes.
Characteristics:
Some
individuals are winged while others are wingless. Winged aphids measure 2–2.5
mm, with brown to black head and thorax and a yellowish-green abdomen. Their
antennae are as long as their bodies. Wingless aphids measure 1.8–2.3 mm and
are yellowish-green.
Symptoms:
Aphid-infested
leaves become deformed, curled, stunted, narrowed like a ribbon, chlorotic,
mosaic-patterned, and brittle.
Control:
- Using reflective paper mulch
repels aphids by reflecting sunlight.
- Remove weeds that serve as
shelter for aphids.
- Mechanical control can be done
by squashing aphids manually.
- Chemical control using
insecticides.
3.
Whiteflies
Whiteflies
belong to the family Aleyrodidae (Hemiptera) and disperse like a cloud of white
dust when disturbed.
Characteristics:
Adults
measure about 1 mm, are yellowish-white, and covered with white waxy powder.
They have two pairs of white wings (span ± 2 mm) and red eyes. Females are
larger than males. Eggs are elliptical (0.2–0.3 mm), and pupae are about 0.7 mm
long and look like scales on the leaves.
Symptoms:
Infested
plants appear covered with white powder that disperses when touched. Plants
become stunted, leaves shrink and roll upward.
Control:
- Use natural enemies
(parasitoid wasps, predatory insects).
- Remove weeds around the field.
- Uproot and burn virus-infected
plants.
- Use straw or yellow plastic
mulch.
- Spray insecticides such as
Diazinon, Malathion, or Azinphos-methyl.
4.
Thrips
Thrips
belong to the family Thripidae (order Thysanoptera).
Characteristics:
Adults
are 1–1.2 mm long, black with or without red streaks. Nymphs are white to
yellowish and wingless. Adults have fringed wings. Eggs are kidney-shaped or
oval.
Symptoms:
Thrips
suck leaf sap, causing leaves to appear silvery due to air entering the
tissues. Severe infestation causes drying and plant death.
Control:
- Water plants sufficiently
because drought increases thrips infestation.
- Remove weeds.
- Apply insecticides such as
Diazinon, Malathion, or Monocrotophos.
5.
Fruit Flies
Fruit
flies belong to the family Trypetidae (Tephritidae), order Diptera.
Characteristics:
Adults
have transparent wings (5–7 mm) and body length of 6–8 mm. The abdomen is light
brown with dark bands. Larvae are white to yellowish and live inside fruit
flesh.
Symptoms:
Fruits
rot due to secondary infection. Larvae (maggots) are visible inside the fruit
and can “jump” up to 30 cm when disturbed.
Control:
- Turn the soil to expose pupae
to sunlight.
- Use attractant traps for
males.
- Destroy infested fruits.
- Remove weeds.
6.
Two-Spotted Mite
Belongs
to the family Tetranychidae (Acarina).
Characteristics:
Oval-shaped,
eight-legged mites, 0.3–0.4 mm long, pale yellow with two dark spots. They live
on the underside of leaves and produce webs.
Symptoms:
Leaves
and shoots turn yellow, then brown and dry.
Control:
- Rainfall reduces mite
populations.
- Remove weeds.
- Plant resistant varieties.
- Apply acaricides such as Omite
or Kelthane.
7.
Red Spider Mite
Also
from family Tetranychidae.
Characteristics:
Eight-legged
mites, 0.3–0.5 mm, reddish to brownish. Causes rust-colored spots on leaves.
Symptoms:
Leaves
turn rust-colored, dry, and plants become stunted.
Control:
- Remove weeds.
- Plant resistant varieties.
- Utilize natural predators.
- Rain reduces population.
- Apply acaricides.
8.
Root-Knot Nematodes
Characteristics:
Small
worm-like nematodes (200–1000 µm), requiring microscopic observation.
Symptoms:
Roots
develop galls, reducing water absorption. Plants show chlorosis, stunting,
wilting, and reduced yield by up to 50%.
Control:
- Crop rotation with Tagetes.
- Soil solarization.
- Flooding soil.
- Apply nematicides (Furadan,
Curater, etc.).
- Plant resistant varieties.
- Remove and burn infected
plants.
- Remove weeds.
- Apply organic matter.
3.5.2.
Diseases Caused by Fungi
1.
Fusarium Wilt
Infection
begins at roots, spreads through xylem, causing blockage of water transport.
Symptoms:
Plants
wilt during the day and recover at night, then wilt permanently.
Control:
- Plant resistant varieties.
- Apply transparent plastic
mulch.
- Use nematode-free soil.
- Use clean tools.
- Avoid planting Solanaceae
repeatedly.
- Remove and burn infected
plants.
- Graft tomatoes onto Solanum
torvum or S. macrocarpon.
2.
Septoria Leaf Spot
Caused
by Septoria lycopersici.
Symptoms:
Small
watery circular spots on lower leaves, later turning gray with dark edges.
Control:
- Remove plant debris.
- Crop rotation.
- Plant resistant varieties.
- Apply fungicides (zineb,
maneb).
3.
Leaf Mold
Caused
by Fulvia fulva or Cladosporium fulvum.
Symptoms:
Pale
chlorotic patches on upper leaf surfaces; olive-brown spores on undersides.
Control:
- Plant resistant varieties.
- Avoid planting in rainy
season.
- Use fungicides (Mancozeb,
Benomyl).
- Biological control with Penicillium,
Trichoderma, etc.
- Crop rotation.
4.
Early Blight
Caused
by Alternaria solani.
Symptoms:
Brown
concentric leaf spots; severe infection causes leaf drop and fruit rot.
Control:
- Use disease-free seeds.
- Remove infected plants.
- Do not bury Solanaceae
residues.
- Crop rotation.
- Use clean irrigation water.
- Good drainage.
- Weed control.
- Avoid dense planting.
- Apply fungicides.
5.
Late Blight
Caused
by Phytophthora infestans.
Symptoms:
Dark
lesions on leaves and fruit.
Control:
- Remove and burn infected
plants.
- Do not bury infected material.
- Plant resistant varieties.
- Crop rotation.
- Soil solarization.
- Use fungicides.
6.
Rhizoctonia Fruit Rot
Caused
by Thanatephorus cucumeris.
Symptoms:
Sunken
brown circular lesions with concentric rings.
Control:
- Use clean irrigation water.
- Avoid deep planting.
- Use stakes.
- Apply plastic mulch.
- Plant resistant varieties.
- Crop rotation.
- Remove plant debris.
- Apply fungicide
(chlorothalonil).
7.
Anthracnose
Caused
by Colletotrichum coccodes.
Symptoms:
Sunken
brown circular fruit lesions with concentric rings; root and stem infection
causes browning and wilting.
Control:
- Do not bury infected residue.
- Rotate crops for 1–2 years.
- Use mulch and stakes.
- Plant resistant varieties.
- Apply fungicides
(captan/captafol).
3.5.3.
Bacterial Diseases
1.
Bacterial Wilt
Caused
by Pseudomonas solanacearum.
Symptoms:
Rapid
wilting with green leaves, downward leaf rolling, stunting, adventitious roots,
plant collapse.
Control:
- Crop rotation; avoid
Solanaceae.
- Weed removal.
- Plant resistant varieties.
- Grafting.
- Apply antibiotics.
- Burn infected plants.
- Soil solarization.
2.
Bacterial Canker / Bacterial Spot
Symptoms:
Small
water-soaked lesions on leaves and stems; sunken gray lesions; curling leaves;
gray stem streaks; corky fruit spots.
Control:
- Crop rotation.
- Use healthy seeds.
- Plant resistant varieties.
- Remove and burn infected
plants.
- Do not bury infected residues.
- Use clean irrigation water.
Additional
diseases:
Tomatoes
may also be affected by viral diseases (tomato mosaic, cucumber mosaic) and
physiological disorders such as blossom end rot, sunscald, cracking, puffiness,
and nutrient imbalances.
The
major disease affecting Artaloka tomato variety is late blight.
3.6.
Harvesting
3.6.1.
Harvest Signs and Age
Tomatoes
can be harvested at 60–100 days after planting depending on variety.
Indeterminate varieties mature at 70–100 days.
Optimal
harvest indicators:
a)
Fruit skin turns from green to yellowish.
b)
Edges of older leaves dry.
c)
Stem turns yellowish or dry.
Harvesting
is best done in the morning or afternoon during clear weather. Midday
harvesting reduces quality due to high respiration and transpiration.
3.6.2.
Harvesting Method
Fruits
are harvested by gently twisting them until the pedicel breaks. Harvest only
mature fruits and place them into baskets in a shaded collection area.
3.6.3.
Harvest Period
Tomatoes
ripen unevenly, so harvesting is done 2–3-day intervals for up to 10 harvest
rounds.
3.7.
Postharvest Handling
3.7.1.
Collection
Tomatoes
must be cleaned immediately from dust, soil, pesticide residues, etc. Washing
may use neutral cleaners (Brogdex, Britex wax).
3.7.2.
Sorting and Grading
Sorting
separates large, healthy fruits from small or defective ones.
3.7.3.
Storage
Storage
aims to reduce respiration and transpiration.
Methods:
a)
Cold storage (48–50°F; 85–90% humidity).
b)
Ventilated room storage.
c)
Vacuum storage.
d)
Submerging in running or static water.
e)
Ice storage.
3.7.4.
Packaging and Transportation
Packaging
and transportation are two closely related activities aimed at protecting
tomatoes from mechanical damage (such as abrasion or impact during transport).
Therefore, both processes must be carried out carefully to ensure that the
fruit quality—maintained during cleaning, sorting and grading, and
storage—remains preserved during packaging and transport.
Important
considerations in packaging include:
a)
Packaging containers must be clean.
b)
Packaging containers should be made of strong yet lightweight materials.
c)
The volume of tomatoes must not exceed the container’s capacity.
d)
Avoid protruding nails or uneven wooden boards inside the packaging container.
e)
Provide protective padding on the bottom and sides of the container using dry
straw or shredded paper.
f)
The packaging container must have ventilation holes on its walls.
g)
Arrange tomatoes neatly inside the container according to its capacity.
h)
Close the container securely by tying or nailing it.
IV.
ECONOMIC ANALYSIS OF TOMATO CULTIVATION
4.1.
Overview of Agribusiness Opportunities
Tomatoes,
as one of the major vegetable commodities, have promising market prospects.
This can be observed from the wide range of tomato-based uses in society.
Market potential is also supported by tomato prices that remain affordable for
all economic levels, thus increasing market absorption. Population growth,
improved education, greater nutritional awareness, and rising incomes further
contribute to increased tomato demand. In addition, advances in the
food-processing industry significantly enhance market absorption, while
improvements in transportation systems provide stronger support for
distribution and marketing.
V.
PRODUCTION STANDARDS
5.1.
Scope
This
standard covers the classification and quality requirements, methods of quality
testing, sampling procedures, and packaging methods for tomatoes.
5.2.
Description
Quality
standards for fresh tomatoes are specified in the Indonesian National Standard
(SNI) 01-3162-1992.
5.3.
Classification and Quality Standards
According
to quality grade, fresh tomatoes are classified into two categories: Grade I
and Grade II.
- Varietal characteristics:
- Grade I = uniform
- Grade II = uniform
- Maturity level:
- Grade I = mature, not overly
soft
- Grade II = mature, not overly
soft
- Size:
- Grade I = uniform
- Grade II = uniform
- Foreign matter:
- Grade I = none
- Grade II = none
- Damage (% by count):
- Grade I = max. 5%
- Grade II = max. 10%
- Decay (% by count):
- Grade I = max. 1%
- Grade II = max. 1%
5.4.
Sampling Procedure
Samples
are taken randomly from a number of packaging units as specified below. From
each unit, 20 heads (krop) are taken from the top, middle, and bottom sections.
For testing damage and decay, the final number of samples examined is 100
heads. Sampling is conducted in the field.
The
number of packaging units examined in each lot is as follows:
a)
For 1–100 units: 5 samples
b)
For 101–300 units: 7 samples
c)
For 301–500 units: 9 samples
d)
For 501–1000 units: 10 samples
e)
For more than 1000 units: minimum 15 samples
Sampling
personnel must meet the following requirements: experienced or previously
trained individuals who are affiliated with a legal entity.
5.5.
Packaging
Products
are typically packaged using perforated polyethylene. These smaller packages
are then placed into cardboard boxes or plastic crates.
VI.
REFERENCES
1. Cahyono,
Bambang. Tomat:budidaya dan
analisis usaha tani.Yogyakarta:Kanisius,1998.
2. Pracaya. Bertanam tomat. Yogyakarta :
Kanisius,1998.
3. Balai Penelitian Tanaman Sayuran. Budidaya Tanaman
Tomat. Malang: Balitsa,1997.
RESOURCE:
Budidaya Tomat Lycopersicon esculentum
Mill. https://atanitokyo.blogspot.com/2008/12/budi-daya-tomat-lycopersicon-esculentum.html
#TomatoFarming
#Lycopersicon
#AgriTech
#Horticulture
#HighYield
