HISTORY OF echo $weed_WORD3;?>
Acidity - Defines the measure
for the uptake of nutrient salts by the plant. Acidity is indicated by the pH
A pH value of 5.8 is ideal for the cultivation of echo $weed_word2;?>.
B - Abbreviation for boron, a material necessary in very small quantities for
the growth of echo $weed_word2;?>.
Blue light - Light given out by mercury-iodide lamps which is necessary for the
formation of chlorophyll in plants. Blue light has a wavelength of approximately
Ca - Abbreviation for calcium, necessary for osmotic processes in the plant
Chlorophyll - The official name for 'leaf-green'. Chlorophyll gives the plant
its green color, and is important in the conversion of CO2 and H2O into
Clones - Weed-growers' jargon for cuttings.
CO2 - The chemical formula for carbon dioxide, next to water, the most important
basic material for the growth of plants.
C6H12O6 - Chemical formula for glucose, the basic material used by plants for
growth and flowering.
Dark Part of photosynthesis. During response, the dark reaction, the actual
formation of glucose from water and carbon dioxide takes place.
Deficiency Plant disease brought on by the disease-application of too little of
a certain fertilizing material.
EC - Electrical conductivity. The electrical conductivity standard of water,
which can be measured with an EC meter, tells whether or not the composition of
the fertiliser is correct
Fe - Abbreviation for iron, an element in the nutrient solution.
Generative phase - The flowering phase of plants. When echo $weed_word2;?> is cultivated
indoors, this phase begins, at maximum, one week to ten days after a clone with
roots is planted, and continues, depending on the variety,
two to three months.
GH - Abbreviation for 'German hardness', a scale for the hardness of water
(namely the quantity of calcium) indicated in degrees.
High- Cultivation under artificial light pressure makes use of high-pressure
gas lamps. They give out the desired quantity of light with the desired
wavelength. (High-pressure sodium lamps - red light for growth, mercury-iodide
lamps -blue light for the formation of chlorophyll.)
H2O - Chemical formula for water, consisting of two parts
hydrogen), and one part oxygen (O).
Hygrometer - A meter with which the relative humidity can be established.
Hygrostat - An apparatus which maintains correct relative humidity. A good
hygrostat keeps the relative humidity constant in a room.
Internode - The distance between the leaves and the tops of a plant. When light
only from the red spectrum is applied during the generative phase, the
internodes become longer.
K - Abbreviation for potassium, which is, next to nitrogen and phosphate, one of
the primary nutrients for plants.
Light Part of photosynthesis in which response photolysis takes place.
Photosynthesis also includes the dark response, in which the actual formation of
Lumen - The international measure for luminosity from a light source.
Ma - Abbreviation for manganese, an element used in very small quantities by
Membrane- Membrane allowing small molecules to pass through but not the larger
Mg - Abbreviation for magnesium, an element plants need for the build-up of
chlorophyll, and for osmotic processes.
Micro-element - Nutrients the plant only barely needs, for example, copper and
Millisiemens- The international measure for electrical conductivity.
Nanometer - Measure of length used to express the wavelength of light. Red light
travels at a wavelength of approximately 650 nanometers(nm), blue light at
approximately 450 nm. A nanometer is one thousand millionth of a meter(10-8m).
NPK - Abbreviation for nitrogen (N),phosphate (P), and potassium(K), the three
primary nutrients for plants.
Osmosis - The phenomenon in which water containing a dissolved substance of a
low concentration is absorbed via a membrane into water which contains
substances of higher concentrations (for example in plants). Osmosis is very
important to plants for sturdiness, and for the transport of water and nutrient
materials. Pressure is built up by osmosis, making the plant sturdy. If this
pressure falls, the plant loses its sturdiness.
P - Abbreviation for phosphate, one of the three primary nutrients.
pH - The pH is a measure of the acidity of a solution (for example, water with
nutrients). The pHscale goes from 0 to 14. The lower the pH value, the more
acidic the solution.
Photolysis - Part of photosynthesis, in which water (H2O) is split up into
hydrogen (H), and oxygen (O).
This occurs during the light response.
Photosynthesis - The chemical process in plants, in which carbon dioxide and
water are converted into glucose by the influence of light energy.
Phototropism- The inclination, which plants have, to grow towards light.
Physiology - The science of growth. (Plant physiology is the science concerned
with the growth and flowering of plants).
ppm - 'Parts per million'.
The amount of material in the air, of CO2, for example, is expressed not only in
percent, but also in ppm. 0.03% CO2 in the air is equivalent to 300 ppm.
Predator - A predator is an insect that protects plants against other insects
such as spider mites, white flies, and thrips.
Red light - Light needed by plants in order to grow. Red light has a wavelength
of approximately 650 nanometers.
RH - Abbreviation for relative humidity. The relative humidity is expressed in
%, and measured with a hygrometer.
S - Abbreviation for sulphur, a nutrient which plants need only in small
Salts - Nutrients, such as NPK, but also other materials (Ca, Mg, etc.) which
are dissolved in water so they can be fed to the plant. We call the solution of
such materials salts.
Semi-permeable walls/membranes permeable - Play a role in osmotic processes in
plants by which the transport of water and nutrients takes place, and the plant
gets its strength.
Skuff - Sifted tops, from which you get as-pure-as-possible THC.
Stoma - An organ in the leaves of plants. The stomata allow the plant to
breathe. Oxygen and excess water are released through the stomata.
Substrate - The 'soil'. Thus rockwool substrate means 'soil of rockwool' the
T-44, T-77 - Measures for sieves with which you can sift out THC resin.
THC - tetra-hydro-cannabinol.
Trace-element - Another
name for micro-element, nutrients the plant needs in only minute quantities,
such as boron and manganese.
Vegetative- The growth phase of plants.
This lasts phase - only a short while in the cultivation of echo $weed_word2;?>, from one
week to ten days maximum.
Zn - Abbreviation for zinc, a nutrient which plants need in small quantities.
PART I: Introduction
1: A Short History of Hemp in the Netherlands
This book is not about the
enjoyment of smoking or eating echo $weed_word2;?> and hash. We can conclude that the home
grower knows how to estimate the value of his or her own product, can't we?
We'll just leave those stories about the nice feeling for what they are. We
spend no time on the effects of echo $weed_word2;?> products. Everyone knows what a good
'high' feels like, what you have to do, and what you sometimes have to allow to
happen. This first chapter deals with the history of echo $weed_word2;?> in the
Netherlands. This way, you get a little insight into how the plant has come
about in the Netherlands, and what purposes the cultivation of echo $weed_word2;?> has
served in the last centuries.
1.2. The journey
China is known principally
for its tea and opium, the great number of its people, and the huge amount of
Chinese restaurants, also hemp originates from China. The Chinese were already
cultivating echo $weed_word2;?> 4500 years BC. They were able to spin yarn for clothing,
and make fishing nets and rope with it. The first medicinal applications were
described two thousand years later. It was used for rheumatism, gout, malaria,
and a number of other disorders.
From China, hemp travelled to Arabia, and appeared in the writings of the Greek
philosopher Herodote. He describes ritual use of burning hemp by the Syrian
Hemp grows everywhere. It came to Europe via India and the Roman Empire. In the
Middle Ages, hemp's intoxicating effect was described by Boccaccio and Rabelais,
among others. Later, it was used by Victor Hugo, Honoré de Balzac, and
Alexandre Dumas in the Latin Quarter in Paris.
Scholars do not agree as to whether the Spaniards were the original importers of
echo $weed_word2;?> to America. It is certainly true that Colombus' ships were outfitted
with hemp rope, and sails made from hemp cloth. The plant spread quickly in
America, and at the beginning of the seventeenth century, large-scale hemp
plantations proceeded in order to supply the needs of the ship - and clothing
1.3. History of echo $weed_Word1;?> in the
It wasn't any different in
the Netherlands. It's not exaggerated to suggest that a considerable portion of
the wealth of the Golden Age came from the cultivation of hemp. Some 11,000
ships sailed at that time, rigged with rope and sails made of hemp. Hemp was the
leading agricultural product in the Netherlands, the stalk was primarily valued.
The stalk, only from the male plant, was processed into hemp fiber. The female
plants were used for other purposes. These were harvested later, and then
threshed. The seed was used as bird feed, or was processed into oil, green soap,
and raw material for paint. For the latter application, a thick pulp remained
which served as animal food. After the Golden Age, less and less hemp was
cultivated in the Netherlands. Competition arose from cheaper Russian hemp,
along with other fibrous materials such as coconut and sisal. The steam engine
made its entry, so less rope and sails were needed in the shipping industry.
Just as in other countries, the medicinal effects of the plant did not go
unnoticed by its growers. Rumours had it that witches used hemp in their
witches' salves. The effects of hemp had already been described in "The
Herb Book" by Rembert Dodoens in the sixteenth century.
Using echo $weed_word2;?> products for pleasure really didn't come about in the Netherlands
until after the Second World War. After jazz, and later the hippie influences,
echo $weed_word2;?> smoking blew over from America. In 1962, Simon Vinkenoog a Dutch
liberated poet, wrote: 'In ten years, this will be as common as drinking whiskey
or beer, or just as normal as an ordinary cigarette. And it doesn't give you
lung cancer. In the first decades, people smoked imported hash other than 'Nederweed'.
Still, growing at home was so energetically pursued, that, thirty years later,
Dutch weed ranks as the best in the world. There has been improvement, cross
breeding, and cloning, fighting the currents, at first. Until the mid-Seventies,
growing, possessing, and use of soft drugs was still punishable. Not until after
the mid-Seventies tolerated points of sale originated - the coffeeshops.
CO2 intake in the leafs Light, air and water, the bare
And now it seems there's no stopping it. More and more of people use soft drugs,
and more and more people try to hold down the costs of soft drug use by going to
work for themselves. Sometimes, purely for their own use, sometimes to earn a
few cents, sometimes to get rich.
This book has been written for the growing group of people who want to apply
themselves to home cultivation. Now, this is the place to give a few warnings.
In the first place, it may be generally presumed that smoking is not considered
the best thing for your health. In the second place, even though the Dutch
government has become more open-hearted in its tolerance of the growth,
possession, and use of echo $weed_word2;?>, the substance still stands on List 2 of the law
Chapter 2: History of echo $weed_Word1;?> - Physiology of
To achieve good results, a
home grower must know about plant physiology. Plant physiology is the part of
biology which is concerned with the way plants grow and flower. In this chapter,
the priciples of plant physiology are discussed. With the growth and flowering
of plants, it involves a select combination of light, air, and water. For light,
it's about sunlight for outside growing, a combination of sunlight and
artificial light for greenhouses, and just artificial light for inside growing.
For air, the amount of carbon dioxide (CO2) is of principal importance. Water
performs various functions. Plants need water (H2O) for the growth process, but
also to transport other important materials.
Plants change CO2 and H2O
into glucose under the influence of light. Glucose is the chemical building
block for the structure and sturdiness of the plant. From glucose, the plant
makes cellulose, the material which gives plants their fibrous structure.
(Glucose is, in fact, stored light energy). The chemical process in which carbon
dioxide and water are converted into glucose is called photosynthesis (from the
Greek 'photos' = light, and 'synthesis' = to compose). Chlorophyll, which also
gives plants their green color, is indispensible for this process. If all the
conditions are right, the following chemical reaction occurs:
2.2. echo $weed_Word1;?> History - Principles of growth
6CO2 + 12H2O = C6H12O6 (glucose) + 6O2 (oxygen) + 6H2O
We can deduce a number of things from this formula. To get one part glucose, we
need six parts CO2 and 12 parts H2O. It would seem that less water is necessary.
When we look at the chemical formula, six parts water are also produced next to
the 6 parts oxygen, and 1 part glucose. However, research has shown that in the
chemical process, 12 parts water are needed. The 'excess' water is used in the
intermediate steps. The water does not re-appear until the end of the process.
CO2 is a gas in the atmosphere. There must always be sufficient carbon dioxide
available, otherwise, plant growth will reduce. Everyone knows that plants need
water From CO2 and H2O, not only glucose, but also oxygen is made under the
influence of light, by the plants with the help of chlorophyll. For plants,
Oxygen is a by-product of growth. For people and most animals, it's the primary
condition of life. This is a good combination. In fact, in their metabolism,
animals do the converse of what plants do. They convert glucose and oxygen into
carbon dioxide and water to be able to move, and to allow the heart and lungs to
work, etc. CO2, a gas which is exhaled by people, can again be used by plants
for photosynthesis. It can be thought of as a cycle. The glucose made by plants
is an energy source for the plant. Some processes, such as the intake of water,
require energy. Next to that, glucose forms the building material for all kinds
of other processes with which the plant lets all its specific properties show.
It would go to far beyond the pupose of this book to look into all those
chemical processes. For the reader of this book, it's about getting good results
growing echo $weed_word2;?> at home A plant cannot grow without light, air (which contains
CO2), water, and various nutrients. The chemical process in which CO2 and H2O
are converted into glucose and oxygen under the influence of light is called
photosynthesis. When we look at this process a little closer, it actually
involves two different chemical reactions. The first is called photolysis. In
photolysis, water is broken down into oxygen (O), and hydrogen (H). Both light
and chlorophyll are necessary for photolysis. This is called the light response.
The second chemical reaction is called the dark response As the term suggests,
no light is necessary for the dark response. With dark response, carbon dioxide
is converted into glucose, with the help of the hydrogen produced during the
light response. The distinction between the light and dark reaction is of
interest to the echo $weed_word2;?> home grower in order to gain insight into the manner in
which the plants must be illuminated (and sometimes kept in darkness). The
plants grow optimally only when a good balance is found between the light and
2.3. Osmotic processes
With osmosis, we mean the
processes in which water and nutrients are absorbed by plants. Osmosis is based
on the principle that the plant's walls permit some materials to pass through,
and others not. Cell walls are semi-permeable. An example: when we place a
bladder with a sugar solution in a tank of water, the bladder swells. The sugar
solution attracts the water. The more sugar in the solution in the bladder, the
more water will be absorbed, and the pressure in the bladder will rise, but
don't try this at home! Among other things, osmosis provides for the sturdiness
in plants' cells. So much water is taken in that the plant cells become
saturated, and the stalk and the leaves stand upright. If too little water is in
supply, the plant cells give off the water; slowly, but surely. The strength is
lost, and the plant wilts. Another way for a plant to lose its sturdiness is for
osmosis to work in the reverse direction. If there is too high a concentration
of materials in the water fed to the plant, the plant will not absorb water. It
will release water, and become less sturdy. An example is the addition of too
high a dosage of fertilizer to plants. With over-fertilization, plants dry out
and burn. A second important function of osmosis is the 'hitch-hiking' of salts
(nutrients) together with the water that, through osmosis, ends up in the plant
cells. Nutrients are necessary to allow certain growth processes to take place.
The salts also cause various kinds of plants to develop various properties. That
brings flowers, fruit, and fragrances to mind. In general, plants need the
following materials in a water solution: - nitrogen, phosphorus, and sulphur for
the construction of cells, - magnesium to manufacture chlorophyll, - potassium,
calcium, and magnesium for osmotic processes, - water for growth, for the
transport of nutrients, and for sturdiness: - iron, boron, copper, manganese,
and zinc as building materials. Most of the nutrients for plants are
sufficiently present in our ordinary tap water. But not all The law of minimums
plays a great role in the feeding of plants. Material that is present in too
small a quantity is a limiting factor on the plant's health. So-called
'deficiency disease' appears when a plant does not receive one or more
nutrients. For example, a shortage of iron causes rather white leaves, while a
shortage of nitrogen causes reduced growth and yellowed leaves. 'Deficiency
disease' involves not only the direct effect (an unhealthy plant doesn't grow
well), but also impaired resistance. If needed materials are lacking, the chance
for infection by moulds and vermin increases. We will discuss plant diseases
more extensively in a later chapter. In order to raise healthy plants, we need
further amplification of the materials which, by nature, appear in our water.
This involves primarily nitrogen (N), phosphate (P), and potassium (K). A
formulated combination of these materials is available in shops, and is called
'NPK solution'. We differentiate the different nutrients in order of importance.
We call the most important the primary nutrients: - the NPK combination just
mentioned. The secondary nutrients follow, namely magnesium (Mg), and calcium
(Ca). Finally, there is a group of micro-nutrients, also called trace elements.
Sulphur (S), iron (Fe), manganese (Ma), boron (B), zinc (Zn), and copper (Cu)
belong to this group, among others.
2.4. Intake and transport
Water, and the nutrients
dissolved in it (salts), is absorbed through the root hairs of the plant. The
condition of the soil plays an important role. Hard dirt allows little space for
water to reach the root hairs, a looser soil has much more space, while rockwool
substrate can guarantee a good water supply. Root hairs are very important. When
they don't work well, the plant receives too little water and food. Growth is
retarded. Root hairs are very sensitive, they can easily be damaged by exposure
to air and light. Moreover, you can ruin them by careless transplanting, or just
by exposure. The intake of water and nutrients requires energy from the plant,
so oxygen and glucose are necessary. Ultimately, temperature is a limiting
factor. Even if you take care to provide sufficient water and nutrients, the
growth of the plant will be impeded if the ground temperature is too low. This
is one of the reasons why most plants outside grow very slowly during the
winter. The transport of water and nutrients insures that these materials end up
in the leaves. Two forces are responsible for this:- the suction power of the
leaves, (they lose moisture by evaporation, causing suc-tion to occur), and
so-called root pressure. Root pressure can be observed when we cut off a branch
of a tree in the spring. Moisture comes from the 'wound', and we call this the
plant's sap. The suction force of the leaves depends on the evaporation of water
through the leaves. Stomata are responsible for this evaporation process. The
stomata can open and close. Next to the evaporation of water, they provide
principally for the intake of carbon dioxide (CO2) from the air. They also issue
the oxygen which is produced. In the previous paragraph, we have seen that
plants lose their sturdiness if they lose too much water. The stomata dispose of
a mechanism to prevent that, they can close. Generally, a stoma will be open if
there is light, (thus providing for CO2 intake, and for optimal suction power of
the leaves), and closed if it's dark (when no CO2-intake, or evaporation is
necessary). If the air is extremely dry (dry, hot, mid-summer days!), the
stomata can also close during the day. For stomata to work properly, a clean
surroundings is necessary, since a stoma can become blocked with dirt particles.
Sufficient potassium (nutrients!) are also needed.
2.5. Factors influencing
the growth of plants
We conclude this chapter
with a sum - up of the principal concerns for the optimal growth and flowering
of plants. The following factors are the most important ones: - the correct
temperature: - the correct CO2 content in the air: - the correct light
intensity, with the correct wavelength of the light:- the correct amount of
water and nutrients - the right soil:- (for echo $weed_word2;?> growers) the right seeds or
cuttings/clones. In 'green fingers' in the second part of this book, we discuss
which materials you need for growing at home. We take a deeper look into the
different factors which influence growth and flowering. Summing up this comes
down to an optimal control of climate.
PART II: echo $weed_Word1;?> History of Necessities and
Chapter 3: Necessities
and Basic Installations
In this chapter, everything
necessary for home-growing is discussed. After describing the conditions
required for your grow room, we pay some attention to the materials you need to
get started. Two things are always important: proper climate control, and
complete safety. Growing plants indoors roughly involves three things: light,
air, and water. After listing the necessary materials and equipment, we reveal
the most important aspects about how you can achieve the best results.
3.2. The grow room
The history of echo $weed_word2;?> reveals the first requirement for
a grow room is that it must enable you to know how best to control the
temperature, air circulation, and humidity. In any case, for good climate
control, it is necessary prevent draught. For this reasons, a garage or a shed
are often less suitable. If you see possibilities to make a garage or shed free
of draught, then, of course, there is no objection. The grow room must be
completely screened off. Make sure that everything not directly involved with
growing is removed. That way, you prevent the chance for moulds and insects as
much as possible. In fact, the grow room should be just as sterile as the
operating room in a hospital You can only expect optimum climate control if the
room is totally sealed. In practice, that means taping up windows and don't
forget aal the gaps and narrow openings around doors and windows . In some cases, it is advisable to place a wall as a screen between the other activities in a room. When growing under artificial light, it is important that the walls of the grow room absorb as little light as
possible. Experiments have proved that flat-white paint has the best light-reflecting properties. So, cover the walls of the grow room with matt white paint. This will maximize the light-yield per lamp. The space must also be arranged in such way that everything is within reach.
That means you have to have room to walk around the tanks or tables where you're growing. It also means leaving enough space to take care of your lamps, and be able to water all the plants. A garden measuring 3x3 meters needs 200 liters of water per week, or more. All that water
is not absorbed by the plants' roots, thus a drainage system is needed. The floor must be a smooth material; concrete is ideal. With other kinds of floor surfaces, it is advisable to use (white) vinyl or linoleum. Also consider an upright brim, so that water cannot leak to lower
stories of the building. Finally, it's handy to have a place to store the tools you're using. A small cupboard (painted matt white!) in the grow room is best. There's another reason to work in a well-sealed grow room: your activities should not
be seen. Also, make sure that the bright lights you'll be using aren't visible from outside . . .
inletbox / outletlattice
3.3. The shopping list
You don't need a lot of
equipement to grow echo $weed_word2;?> on a (very) small scale. A grow tank, soil,
nutrients, enough light, and an agreeable temperature make growing hemp indoors
quite possible A good alternative for growing in soil is to fill planting pots
with lava stone granules, or with rockwool flakes. In order to achieve a smooth
growth- and floweringprocess you must pay a lot of attention to ventilation,
regular watering, proper lighting, etc. Without appliances, you have to care for
the plants every day. Therefore, you have to choose between growing in soil or
in rockwool. Working on rockwool is advantageous because you don't have to drag
bags of soil around Still, some weed growers swear by soil, because they think
the quality of weed isn't as good if you grow on rockwool. Others see no
difference. They would rather grow on rockwool, because they can achieve a
greater yield. There are, however, many factors which affect the healthy growth
and flowering of echo $weed_word2;?>. 'Green fingers' are certainly not the least important
We've made a shopping list for (semi-) professional growing on rockwool
substrate. Cheaper alternatives can be devised for many of the articles. We'll
return to the three aspects light, air, and water later in greater detail. The
materials listed below will cost between 2250, and 3000 guilders for a grow
space slightly larger than two square meters:
- 3 armatures for high-pressure gas lamps;
- relay box for the lamps;
- 12 libra trays with water drainage;
- 12 rockwool slabs;
- 36 rockwool blocks 7.5 x 7.5 x 6.5 cm;
- irrigation system with an immersible pump, electric timer clock, water reser
voir, air pump, heating element
- ventilator for the intake and outlet of fresh air and the discharge of
- measuring cups (100 and 500 ml);
- pH meter;
- EC meter;
- thermometer with indications for minimum- and maximum temperatures;
- saltpeter/phosphoric acid.
Unfortunately, you're still not ready, even with the materials listed above.
Optimum climate control is needed for growing indoors. A ventilation system can
(and in some cases, must) be added; varying from a simple bathroom ventilator to
a more expensive carbon dioxide box ventilator with a humidifying system. You
can go for a larger-scale approach by providing a system to keep the CO2 content
optimal, by installing air-conditioning, or your own water purification
regulated by osmotic filters, or by using a computer to regulate feeding. You
can easily spend more than 20,000 guilders for a complete home-grow system if
you want .
3.4. Grow room layout
First, the lamps are
installed. It's important to ensure enough power capacity. The three lamps
together require 1200 watts of power, while the pump and the ventilator also
draw current. The safest manner is to allow a separate circuit in your tool
cabinet. With a 16-ampere circuit, you have 2800 watts at your disposal. The
circuit does provide more power than that, but you cannot use it all. When the
lamps are turned on, they use more power than the 400 to 600 watts they give
off. Too high a current drain will blow the fuse The lamps must be distributed
so that the entire growing surface will be evenly illuminated.
It's a good idea to build a wooden frame to hang the lamps, and to hold the
libra-trays. Other devices can be fastened to the frame later. Second, the libra
trays are arranged. libra trays are well-suited for growing indoors, because
they provide drainage for water run-off. We can also use so-called drainsets.
These should be assembled first. When they're assembled, they can be snapped
onto the trays. If you don't have access to a drain, it's wise to build a
drainage tank. As an alternative to libra trays, you can, of course, use
ordinary pots. If you don't want to use drain sets, you can drain water via
gutters. The growing trays are filled with rockwool slabs. Holes are cut into
the slabs for the rockwool blocks. The blocks are fastened to the slabs with
pins. The rockwool blocks are saturated with water and fertilizer. After laying
out the irrigation system, the rockwool slabs are then cut on the underside in
order to allow excess water to drain. We'll set up the irrigation system. First,
make an electrical outlet (earth ground!). The outlet should be conveniently
located, right next to the fertilizer tank. We'll put the fertilizer tank just
next to, or even underneath, our grow-table(s). The immersible pump is placed in
the fertilizer tank to pump the fertilizer to the plants. The pump is turned on
and off by a timer switch. This way, we make sure the plants get their water and
nutrients on time. A tube is attached to the pump. This tube is connected to a
flexible polyethylene hose. This polyethylene hose is suspended over the middle
of the libra trays. The end of the hose is sealed with a cap. Punch holes for
the sprinklers. The next step is the installation of an air pump with an
aerator. The aerator is placed in the nutrient tank so algae won't grow so
rapidly. The air bubbles generated by the pump and the aerator take care of
that. This way, you also insure that sufficient oxygen gets in the water, and
that the fertilizer components remains in motion. Next, put a heating element in
the nutrient tank. The element has to maintain the water temperature. To be able
to check the temperature, we place a thermometer in the tank. Watering can now
begin; the nutrient tank may be filled with water and the proper amount of
fertilizer. Pay attention when you mix the fertilizer. Follow the directions on
the package accurately. They describe the correct amounts of fertilizer to
Ph and Ec meter
With too little feeding, the law of minimums comes into play; delayed growth and
flowering; unhealthy plants. With over-feeding, the plants will burn . When you
apply various kinds of fertilizer (also called A- and B-nutrients), make sure
the materials don't make contact with each other. If that happens, then a
chemical reaction occurs between the phosphate in the one, and the calcium in
the other. Calcium phosphate forms, and the fertilizer loses potency To find out
whether or not the fertilizer you're using has the right concentration, we use
an EC meter (see the chapter about water). With too low an EC measurement, you
should mix in more fertilizer. With too high a reading, you should dilute the
solution with more water. In addition, the acidity of the water - the pH value -
is important. We measure this with a pH meter (see the chapter on water). When
the pH value is too high, we can lower it with saltpetre/phosphoric acid. When
the pH value is too low, we can raise it with a solution of calcium carbonate.
You must be very careful with concentrated saltpetre/phosphoric acid. It will
burn holes in your clothes, and it will seriously burn your skin, too The
irrigation system is now ready to be tested. Always make sure the water pump is
never turned on in the absence of water. This can burn up the pump's motor.
Place a sprinkler in one of the measuring cups and determine how much time it
takes to pump approximately 50 cc of water and nutrient into the measuring cup.
Program this time into your timer. It's intended that each plant gets around 300
cc water and fertilizer, divided over at least 6 feeding times. If you have a
timer which can be switched on and off more often, then you can spread the 300
cc over more feeding times. As an example, we'll consider 6 times. The first 50
cc feeding is given at the moment the lights are turned on, and the last, two
hours before the lights are turned off. The other four feedings are neatly
divided, via the timer clock, among the periods in between. Plants take in water
and nutrients only under the influence of light. This is the reason for giving
water and nutrients when the light is on. The last feeding is given
approximately two hours before turning the lights off; in order to give the
plants the chance to absorb the water before the dark period. The quantities we
refer to in this book are average values. The starting point of every grower
must ultimately be raising healthy plants. So you also have to have green
fingers as you do the watering and feeding
Chapter 4: Light
Watertank with the needed
Plant growth involves the
conversion of light energy into plant-building materials (photosynthesis, see
chapter 2). Two factors are important for optimal growth. In the first place,
the light intensity. Light intensity is expressed in 'lumens'. At least 50,000
lumens are needed for growing indoors. It's not sufficient to add up the number
of lumens listed by the manufacturer for each lamp. The total number of lumens
given off is depends strongly upon good reflection, and proper connecting
fixtures and starter ballasts for the lamps. The quality of the reflector used,
and the connecting fixtures and ballasts determine the light yield for the
greatest extent. For those reasons, self-built sets and home-designed
illumination often deliver a lot less light yield than lamps being used in
professional horticulture. We can improve the light yield in our grow room by
applying reflective material. We haven't painted the walls of the room matt
white, and used reflector caps for the lamps for nothing! The second important
factor is the wavelength of the light. For the production of chlorophyll, and an
optimum photosynthetic reaction, light from the blue spectrum (445 nanometers),
and light from the red spectrum (650 nanometers) is necessary. Blue light
ensures optimal phototropism. Phototropism is the phenomenon which causes plants
to grow towards the light, and to spread their leaves in such a way to receive
the most light.
4.2. Choices for lamps
In this book, we prefer
high-pressure sodium lamps, and mercury-iodide lamps for illumination. Ordinary
light bulbs are not suited for echo $weed_word2;?>-growing due to their considerably short
life span, and principally due to their low light yield. Halogen lamps are not
advisable for the same reasons. Fluorescent lamps are not appropriate for home
growing. They do serve well, however, to stimulate seedlings and cuttings to set
root. For actual growing, we stick to gas discharge lamps in the form of
high-pressure- sodium, and mercury-iodide lamps. There are lamps being sold
which emit both the wavelengths needed (blue and red) but we prefer installing
seperate lamps in a 1:3 proportion (1 lamp for blue light with 3 for red light).
The combination lamps give off a lower amount of lumens, since they have to emit
different wavelengths. This counts for growing: the more lumens, the greater the
yield. This doesn't mean we can install an unlimited number of lamps. Other
factors must be considered. Using many lamps means a higher temperature (the
heat must be discharged of), a greater need for fresh air (containing CO2), and
a greater need for water and feeding. Always remember the law of minimums
Depending on the size of the garden, we use 400 Watt lamps or 600 Watt lamps.
This choice is made in such a way that all the plants in the garden area can be
illuminated as evenly as possible. By using 400 W lamps, you can put up
one-and-a-half times as many lamps for the same electricity use as when using
600 watt lamps.Also 1000 watt lamps are being sold but proper reflectors for
these types of lamps are not available. The result is a disproportionately large
loss of yield. Moreover, 1000 Watt lamps give off more heat. Therefor they must
be hung high above the plants, and this means more loss of light yield plays in
the question. 1000 Watt lamps, with respect to 400 and 600 Watt lamps, mostly
cause pain in your wallet, because the electricity bill gets higher.
In practice, it is possible to reach a light yield of 70-90% of the lumens which
are emitted. For that, (it can't be stressed enough), good reflection is
necessary. Below is a chart with data for several reflective materials:
Reflectivity in % - Reflective plastic sheet 90-95 - matt white paint 85-90 -
semi-matt white paint 75-80 - matt yellow paint 70-80 - Aluminium foil 70-75 -
Black paint less than 10 Using proper reflective material, proper connecting
fixtures ballast equipment, proper reflector caps with the lamps, and a distance
from the lamps to the plants of 40 to 60 centimeters, 400 Watt lamps deliver, on
average, between 35,000 and 47,500 lumens, and 600 Watt lamps between 60,000 and
80,000 lumens (at a distance of 50-70 centimeters). The distance between the
plants and the lamps differs because 600 W lamps give off more heat. Ifthe
plants are to close to the lamps, they will dry out and burn 600 Watt lamps are
preferred, because you get the highest light yield for the lowest electricity
cost. Though they do require more careful climate control The life span of a
high-pressure gas lamp is approximately 2 years when it's used 18 hours a day.
The lamps are, however, subject to decay, which lessens the light yield.
In practice, it appears that high-pressure gas lamps give optimal results for 4
to 5 harvests. After those, it's advisable to replace them. It seems that the
installation of one 600 Watt sodium lamp per square meter is enough to achieve
the best results. Principally one can say 'the more light, the better', but with
more illumination, the control of other factors (namely, temperature control)
becomes a problem. Indoor growers work with their light source close to the
plants. Considering the light yield of the sun, (hundreds of thousands of
lumens, but a little further away), fewer lumens are needed for growing indoors.
A simple formula shows that you can also use three 400 W lamps for two square
meters. The sodium lamps provide light from the red spectrum. This light is used
principally during growth. A mercury-iodide lamp fills in the blue spectrum. For
reflection, growers use wide-angle reflectors with sodium lamps, and
super-wide-angle reflectors with mercury-iodide lamps. Super-wide-angle
reflectors spread the light over a greater surface area. We use the proportions
of 3 red lights to 1 blue. So, the light from the blue lamp must be spread over
a larger surface area.
High-pressure gas lamps may only be used in the fitting meant for that
particular lamp type. High-pressure gas lamps all have their own start-up
conditions, voltages, characteristics, and shapes. Using lamps with improper
sockets can cause electrical shorts! Therefore, it's recommended that you buy
all the parts of a pressurized gas lamp from the same dis- tributor. The
sockets, ballasts, and connectors must always be protected from humidity;
otherwise, electrical shorts occur. As stated earlier, high-pressure gas lamps
have a long life span. You must be careful when replacing these lamps. They are,
as the name implies, under pressure, and they explode when you destroy them.
When you do that yourself, you must always wear gloves and safety glasses. In
addition, you have to protect yourself against the poisonous materials found in
these kinds of lamps. The heat given off by high-pressure gas lamps, and their
accompanying starter ballasts, must be completely ventilated. This means that
the lamps shouldn't hang too close to the plants (hence drying and burning
occurs), but also not too close to (flammable) ceilings and walls. Place a piece
of non-flammable material (not asbestos!) between the lamp and ceiling or wall.
Furthermore t's necessary to discharge of excess heat by using a ventilator.
Finally, it's important to keep high-pressure gas lamps clean. Dirty lamps
provide much less light yield than clean ones. The lamps should be polished now
and then with some glass- cleaning agent. That should be done only when the
lamps are turned off, and well-cooled.
4.3. Using high-pressure gas lamps
The use of gloves to protect the lightbulb cloning accessories
Be especially careful with water. Lamps which are still hot, or even
warm, can explode when touched, and that's not funny. Also, take care never to
touch these types of lamps with your fingers. Just like halogen lamps, bodily
acids can burn through, causing the lamp to fly to pieces.
4.4. Proper lighting for echo $weed_word2;?>
The advantage of growing echo $weed_word2;?> indoors is the fact that you can give the
plants the feeling that it's their flowering season all year round. You're not
dependent on the weather or the season. We distinguish two separate phases in
plant cultivation: the growth- or vegetative phase, and the flowering- or
generative phase. We've already made sure the lamps are installed in such a way
that all the plants can be optimally illuminated. A light period of 18 hours and
a dark period of 6 hours is ideal for the vegetative phase. We're assuming that
you already have cuttings with roots. With proper care, a healthy echo $weed_word2;?> plant
can grow up to 5 centimeters per day. It's very easy to cause the plant to
flower. We only have to give the plants the idea that the days are getting
shorter ('autumn'; for echo $weed_word2;?>, the sign to flower). We do that by making the
light and the dark periods the same length; - 12 hours. In principle, echo $weed_word2;?>
is an annual plant. The entire life cycle, from seed to death, takes place in
one year in nature. When growing echo $weed_word2;?> under artificial light, it is possible
to force flowering earlier than in nature. After 4 or 5 days vegetative phase,
flowering can be 'provoked'. We do that the moment the clones have visibly
started to grow. Two or three weeks after the light period is reduced to 12
hours, the plants begin to flower. It's very important not to interrupt the dark
period. If the plants receive light during the 12-hour dark period, they 'get
confused'; they want to continue growing, and the blooming phase is postponed.
The generative phase lasts 60 days or longer, depending on the variety you're
growing. When working with cuttings, it's possible to harvest four to five times
The cutting or clipping of a clone and the motherplant and its
clone on a rockwool plug.
Chapter 5: Air
Almost all living beings are
dependent on light of satisfactory quality. For humans, that means that
sufficient oxygen must be present in the air, and that the air is not too
polluted. For plants, and thus also for echo $weed_word2;?>, it means good air quality,
enough carbon dioxide (CO2), and not to much pollution. Relative humidity (RH),
and temperature also play a large role in the growth of plants.
5.2. Influencing air
The amount of CO2 in the open
air is appoximately 0.03 to 0,04%. The amount of carbon dioxide is also
expressed in parts per million; ppm. 0.03% is equal to 300 ppm. There are
differences in the CO2 needs among plants. By raising the CO2 content, growth
can be accelerated. The law of diminished returns still holds true, however.
Raising the CO2 level has limits, but at approximately 1400 ppm (0.14%), good
results (a faster growth) are generally achieved. Above 1400 ppm, the effect of
a higher percentage of CO2 decreases. A high concentration of CO2 is poisonous
even for plants. A CO2 concentration of 1800 ppm or more is deadly for most
plants. A simple method for guaranteeing the supply of carbon dioxide is to
ventilate the room. Sufficient ventilation must be provided, so the plants keep
getting enough fresh CO2. A second and just as important reason for ventilation,
is to dispose of excess heat. If the temperature gets too high, (see Section
5.4), growth is stunted. This counts not only for the temperature in the grow
room, but also for the temperature in the plant itself. When the plant's
temperature is too high (humans get a fever), there is less sap flow, causing
growth distubances. There is no standard solution for refreshing the air. The
need for fresh air is, for a large part, dependent on the size of the grow room
in cubic meters. In principal, the total air content of the room must be
exchanged every 2-3 minutes. Using for example a grow room 3 meters long, 2
meters wide, and 2 meters high (12m3), this means that the ventilator capacity
must amount to 30 x 12 = 360 m3 per hour. A standard bathroom ventilator can
only handle up to 100 m3 per hour Many growers ventilate their rooms with table
fans. The point is the control of the temperature as well as the circulation of
the air with sufficient carbon dioxide. Table fans are primarily intended to
keep people comfortable on a hot summer day. They are much less suited to run
continually for heat removal, and for CO2-content maintenance. Table fans have a
tendency to melt with intensive use. You can imagine the consequences: not only
the danger of fire, but also massive plant death . . . There are, of course,
plenty of fans on the market which will take care of proper ventilation. These
have been specifically designed to be able to run continually. The CO2 content
in the grow room can also be heightened by adding CO2 from a tank. If the system
is set with a timer clock, the desired amount of CO2 can be regularly released.
Work with care, because you don't know how much CO2 is in the room at any given
moment. An overdose can easily occur To prevent this, it's sensible to ventilate
the area well before each CO2 'injection'. The most professional option is to
use a CO2 controller. This apparatus continually measures the CO2 content in the
room. When the programmed minimum value is reached, CO2 is automatically added.
If the programmed maximum is exceeded, the controller turns on the ventilating
system. If CO2 is added to the room via a tank, or a controller, cultivation can
take place at a higher temperature. (More about this aspect in Section 5.4.)
Ultimately, attention must be given to the relationship between ventilation, and
the relative air humidity. The humidity of the air is dependent, among other
things, on the amount of air moved through the room. Changing the air draws more
moisture out of the plants, because the stomata release more moisture. If the
relative humidity of the air drops too low, the stomata close, delaying the
5.3. Relative humidity (RH)
The relative humidity of the
air influences the functioning of the stomata, among other things. echo $weed_Word1;?>
flourishes the best with an RH of 60-70%. At higher RH percentages, the stomata
have problems getting rid of excess water. At a lower RH, the stoma keep
releasing water until the plant dries out. At that moment, the stomata close.
Then, the intake of CO2 stagnates, and plant growth is impaired. The relative
air humidity is also influenced by the temperature in the growing space. In the
chart below, you can see the number of grams of water which can be absorbed in a
25 m3 room (for example: 3 x 3 meters, and 2.5 meters high). Absorption in grams
of water (degrees C) 0 degrees 120 10 degrees 240 20 degrees 460 25 degrees 630
30 degrees 840 35 degrees 1120 40 degrees 1460 It may be concluded from this
chart, that with every rise of 10 degrees in temperature, the air humidity
doubles. Ventilation influences the relative humidity. Ventilating a space makes
the RH fall. In some cases it's necessary to install a humidifier in the grow
room. The best results can be achieved by using a discharge fan with a variable
speed control. This way, you can easily regulate the quantity of air to be
removed. When the plants are in the dark, the temperature is lower (the lamps
don't give off any heat). So, you would expect the relative humidity to fall
(less moisture can be absorbed by the air). But this is not the case; RH
increases in the dark. The plants breathe out water in darkness. Therefore,
sufficient ventilation must be provided. Too high a humidity level provides
considerable risks for the health of the plants. Generally, pests and diseases
(see Chapter 8) have a better chance with a high humidity level. Too low an RH
is also risky; the plants can easily dry out. Prevention is better than cure . .
. Finally, it should be stated that young seedlings and clones generally perform
better at a humidity level of 65-70%. Their root systems are not yet developed
well enough to take in water fast enough. A higher humidity insures that the
young plants will be protected from drying out.
The high-pressure gas lamps
we use for cultivation cause a considerable amount of heat in our closed-off
grow space. This heat can be damaging to the plants. In the first place, we have
to make sure the plants are not too close to the lamps. A distance of
approximately 40 centimeters (for 400 Watt lamps), or 50 centimeters (for 600
Watt lamps) is good. The lamps also warm the air in the room. This heat must be
discharged via the ventilation system. echo $weed_Word1;?> seems to grow best at a
temperature of 25 to 26 degrees Celsius. This temperature must not be allowed to
rise any higher in grow rooms where no CO2 enrichment takes place. When working
with bottled CO2, or even a CO2 controller, the temperature can be a little
higher; 27 to 29 degrees. When working at higher temperatures, the RH must be
closely monitored. Every 10 degree rise in temperature means that the absorption
capacity of the air nearly doubles (see Section 5.3). In the dark period, the
temperature may drop a little, but not too much. If the temperature is too low
during the dark period, moulds have a better chance A temperature of
approximately 20 degrees Celsius is ideal for darkness. In order to maintain an
optimal temperature, you need a discharge ventilator. The discharge ventilator
has a double function: refreshing the air, and drawing off the heat. As
described earlier, the capacity has to be great enough to replenish the air
content of the grow room at least thirty times every hour. Accordingly, when
working at higher temperatures (by adding CO2), the plant needs more water and
more feeding. Remember the law of minimums. We can raise the CO2 supply, but if
we don't give extra water and extra fertilizer, plant growth adapts itself to
the aspect of poor care.
Chapter 6: The history of hemp - Water.
With the short description of
plant physiology, we already looked into the function of water in plants. Water
has three functions: it is a building material (together with CO2 and light
energy, glucose is produced), it makes the plant sturdy (the plant cells fill
themselves with water, giving the plant a firm structure), and it transports
nutrients throughout the plant. Water is indispensable for the existence of
plants. Remember that the law of minimums plays a crucial role here also: too
little water, but sufficient light, CO2, and nutrients, produces unfit plants.
Too much water, with respect to the other criteria, produces just as poor
results. Therefore it's important to find an optimal balance, so the plants will
6.2. Water quality
It probably goes without
saying, but the water you use must be as clean as possible. For plants, however,
'clean' is a relative concept. Nutrients such as nitrogen, phosphate, potassium,
etc. are always dissolved in water used for plant food. In any case, the
concentrations the plants need of these materials make the water undrinkable for
humans. In contrast to 100% distilled water, 'pollutants' are found in ordinary
tap water. You can request a chart with data about the quality from the company
that produces your drinking water. The hardness in degrees - the GH (German
Hardness) - is also given. This is a measure for the amount of calcium in the
water. Below, you have an example of this kind of water chart. Some of the
'pollutants' aren't 'pollutants' to plants, but actually fertilizing materials.
To determine the water quality (and the plant foods you add), you need two types
of meters. The first is an EC meter. 'EC' is the abbreviation for 'Electrical
Conductivity'. Pure water, also called demineralized water, does not conduct
electricity. When we add fertilizer to the water, or the water is 'polluted' in
some other way, the water will indeed conduct electricity. Fortunately, home
growers can make use of this property of water. With the EC meter, we can
determine whether or not the concentration of nutrients in the water will
provide for optimum plant growth. A high EC value means a high concentration of
fertilizing materials, and a low EC value, a low concentration. Too high a
concentration shows that you're over-fertilizing. As a result, your plants will
dry out and burn. (By osmotic processes, water is drawn out of the plant; the
leaves curl upwards or downwards.) The fertilizer concentration must be lowered
by further diluting with water. Too low an EC value means a shortage of
fertilizer. This decreases the growth on rockwool substrate. The EC value is
given in millisiemens. 1.8 millisiemens is the optimal value for growing
echo $weed_word2;?>. The second type of meter is the pH meter. With a pH meter, you can
determine the acidity of water. Most of us have measured the acidity of a
solution at one time or another in high school. We did it with a litmus test.
But the litmus test is not suitable for measuring acidity when growing hemp at
home. The accuracy of this test leaves something to be desired. Actually, we can
only estimate the pH value, to the accuracy of one pH point. We need greater
accuracy for cultivating echo $weed_word2;?>. The average pH meter used by aquarium owners
is relatively cheap, and meets the requirements well. Generally, they're up to
0.02 pH points accurate. The ability to absorb nutrients depends on the acidity
of the water. If the pH is too high or too low, the plants can't absorb some
nutrients properly. Then deficiency disease occurs . The pH scale goes from 1 to
14. A solution with a pH between 1 and 7 is called 'acid', a pH of 7 is called
neutral, and between 7 and 14, 'basic'. The lower the pH, the more acidic the
solution (in our case: water). On the next page, you have a chart showing which
nutrients plants can absorb best at each pH. You can read from the chart that
echo $weed_word2;?> plants like it if they receive water which is slightly acidic. The home
grower must make sure that the pH of the water being used is approximately 5.8.
The EC meter, as well as the pH meter, must be adjusted now and then. Special
calibrating fluids are available for this operation. The temperature is also an
important factor when calibrating an EC meter. The correct temperature is listed
on the package of calibrating fluid. A pH meter has two set screws, and it must
be adjusted to two values. The probe of the pH meter is first dipped into a
calibrating fluid with a pH value of 7.0. Then, this value is set using one of
the set screws. After that, the probe must be cleaned well, otherwise deviations
will occur with the second calibration. Next, the probe is dipped in a
calibrating fluid with a pH value of 4.0, and this value is set using the other
set screw. It's important that the pH meter probe is kept moist. Depending on
the type of pH meter, it may be stored in ordinary tap water, or in a special
fluid supplied by the manufacturer. In the story about the EC meter, we've
already indicated that the temperature of the nutrient solution influences plant
growth. echo $weed_Word1;?> grows best with a water temperature of 25 degrees Celsius.
Below this temperature, the roots of the plant have more trouble taking up water
and nutrients. Too high a temperature is not good either. That will kill the
plants Tap water must be warmed up to 25 degrees C. Use a water thermometer to
keep an eye on the water temperature. Warming the water is easy with the
installation of a heating element in the nutrient tank. This equipment also
comes from the aquarium world. Quality heating elements with thermostats are
available for aquariums. For a 100 liter nutrient tank, you need a 100 Watt
heating element; with a 200 liter tank, we recommend a 250 Watt element. Make
sure the heating element is always kept under water; otherwise it will be
destroyed. This means that you must never pump all the water out of the nutrient
tank to the plants. When you want to take the heating element out of the water,
always disconnect it first. Then, let it cool off for at least 15 minutes. Only
then can you carefully take it out of the water. Any other way, you run the risk
the element will crack. To prevent algae growth in the nutrient tank, it's
important to add air to the water. We do that by means of an aquarium pump with
an aerator attached. The aerator is connected to the pump, and placed at the
bottom of the nutrient tank. The water in the tank becomes rich in oxygen by
aeration, and is also kept in motion. This way, algae have much less chance to
6.3. The irrigation
We do everything we can to
promote plant growth. We provide optimal lighting and sufficient CO2. As a third
component, regular irrigation is an essential link. This way the plants receive
their water and nutrients in time. The easiest way is to water by hand several
times a day. But, in the first place, that involves carrying a lot of watering
cans around, in which you've dissolved the correct amount of fertilizer every
time. In the second place, watering by hand requires enormous discipline. Giving
water regularly on time will quickly 'water' YOU down You can't skip a few days
here and there, and leave your plants to themselves. Finding a babysitter for
echo $weed_word2;?> plants is often more difficult than finding a babysitter for your kids
. . . So, we prefer to give water regularly with an irrigation system controlled
by a timer clock. This way, we can rest assured the plants get their wet and dry
periods on time. In Chapter 3, we've given a lot of attention to the
installation of an irrigation system. Now, we'll go a little deeper. In its
simplest form, an irrigation system consists of an immersible pump, controlled
by a timer clock, which has hoses with sprinklers attached to it. The sump pump
is placed in a nutrient tank with a capacity large enough to make refilling
necessary only two times per week. We're talking about a tank with a contents of
at least 25 liters per square meter of garden space. 5 to 7 liters of water with
nutrients are used every day for each square meter. So, refilling the tank every
3 or 4 days is enough. Remember, there must always be enough water in the tank
to cover the heating element and the pump. Both instruments will be ruined if
they are left without water. Preferably, the nutrient tank should sit on the
floor. There are two important reasons for this. In the first place, it saves
space. The tank can also be underneath the tables. In the second place, it
prevents the natural working regarding water levels between communicating
vessels. If the nutrient tank is placed too high, the water will flow through
the hose without the aid of a pump. This goes on until the water level in the
tank reaches the same level as the lowest point of the connected irrigation
hose. Solutions can be devised for the problem of 'communicating' vessels, -
coupling an electric faucet between the nutrient tank and the irrigation hose,
for example. This solution is unnecessarily expensive. The problem of
communicating vessels can be prevented by placing a sprinkler outlet on the top
of the hose. The sump pump must be powerful enough to send water to all the
sprinklers that will be installed. For a garden 2 to 10 m2 in size an immersible
pump with performance capability of 7 meters is enough, if used with a 1-inch
irrigation hose. Also, the pressure of the pump should not be too high,
otherwise the sprinklers (also called capillaries) won't drip, but spray. Most
sprinklers function at a pressure from 0.5 bar on up. To the immersible pump, we
connect an irrigation hose (polyethylene or PE- hose). The irrigation hose goes
through the middle of the grow trays. Then we make holes in the polyethylene
hose and insert the sprinklers. We install one sprinkler for every plant. We
have to prevent dirt and other materials from clogging up the narrow openings of
the sprinklers. We take two measures: first, we keep a lid on the nutrienttank
so nothing undesirable falls in the water. Second, we place a filter between the
pump and the irrigation hose. In an ideal situation, plants should get water and
nutrients spread evenly throughout the day. We can arrange for this by
connecting a timer clock to the irrigation system. A suitable timer clock must
also have a minute setting, and must be able to switch on and off at least 6
times a day. Modern timer clocks are digital. These clocks have a memory to
store the desired times. If the electricity goes off, batteries usually supply
current to preserve the memory. The disadvantage is that batteries run down. If
the battery is dead, and the electricity goes off, the memory is erased. The
steady watering stops, and the garden is damaged. The recommended choice is a
timer clock with a good car battery for backup. Now, our irrigation system
ensures that the plants get the correct amount of water and fertilizer on time.
The sprinklers evenly distribute the nutrient solution. We prefer growing in 'libra
trays'; - so-called 'growing trays' which have been especially designed for
growing on rockwool slabs. There are other methods, of course. You can also lay
rockwool slabs on corrugated roofing sheets, for example. This does give
problems with drainage water . It's more hygienic, and more practical to work
with growing trays. They're not expensive, and it's simple to connect a drainage
system to them. Easier still is snapping drainage spouts onto the growing trays.
Then the water can be drained into a gutter. We divide the irrigation of the
plants into 6 periods during the 18-hour light cycle. The first feeding takes
place when the lights are switched on. A feeding session follows every 3 hours,
until 3 hours before the lights go off again (the plants can take in nutrients
only during the light period!). In the beginning, we don't let the irrigations
periods last more than one minute, because otherwise, problems with root
development can occur. We stick to short feeding periods. Throughout the entire
vegetative phase. During the generative phase (12-hour light cycle), we also
divide the 6 feeding sessions so the plants will get water every two hours.
Since the plants have grown a little by then, and they need more water, we let
the irrigation periods last for two minutes. When irrigating the plants, you
must make sure the nutrient solutions soaks through thoroughly. Thorough
watering means that about one-third of the water applied drains off. Thorough
watering is important to prevent the accumulation of the nutrient salts in the
rockwool slabs. If watering is not sufficiently thorough, it's sensible to raise
the number of irrigation sessions. Finally, another word about safety. Everyone
knows that water and electricity are equally related as water and fire. The sump
pump, as well as the thermostatic heating element, work with use electric
currency and under water. Use only equipment of wich you are sure it is
well-insulated. Moreover, it's sensible to disconnect the plugs before you put
your hands in the nutrient tank. This can save you from a possibly shocking
A shocking experience.
Chapter 7: Clones and
In the previous chapter,
we've told you what equippment you need to grow hemp. Furthermore you've been
initiated into the secrets of good climate control to reach an optimal result.
Up until now, we haven't said a word about the living material you can use to
'rise high'(!) . . . In this chapter, we'll look at the actual cultivation.
We'll leave sprouting echo $weed_word2;?> from seed for what it is. We'll talk about
starting with clones. It's not completely clear why the word 'clones' has been
adopted by the weed grower; we're talking, in fact, about 'cuttings'.
7.2. Cloning hemp
Cloning hemp is a cheap,
quick way to get plants. The average gardener has taken cuttings from his/her
house plants at one time or another. It's not much different with hemp. We only
have to make sure the carefully removed cuttings from the mother plant are
brought to root. A healthy mother plant can pass on her THC-producing properties
from generation to generation by means of cuttings. Each cutting has the same
properties as the mother plant. A cutting can be taken from a cutting. And from
that cutting, yet another. There are growers who have raised 20 generations from
a mother plant this way, without diminishing the growing power of the plants.
The yield from the 20th generation is just as good as the yield from the first
one! By then, the original mother plant is long past use. Taking cuttings causes
trauma to a plant. The plant reacts by taking on a deviant form, and by starting
male branches. A third problem is regressive mutation. The mother plant has been
developed by cross breeding. With regressive mutation, the carefully bred
properties (to a degree) are lost. The quality of the plant (and, of course, the
quality of the harvest!) decreases. For this reason, we replace the original
plant with one of her fresh, healthy daughters after 12 weeks at maximum. The
ease with which hemp can be cloned makes planting echo $weed_word2;?> seed less attractive.
In the first place, sowing seed takes a lot more time than growing from clones.
An advantage not to be underestimated is the fact that you can harvest much more
often if you raise clones rather than grow from seed. On top of that, you get
males as well as female plants from seed. The chance that a seed produces a male
plant is just as great as the chance a female will appear: 50% . . . To make
hemp cuttings/clones we need: - a high-quality mother plant; - sharp scissors,
or a sharp knife; - any commercial hormone mixture to promote root growth, -
something to start the cuttings in (a cutting tray with rockwool plugs, a small
grow-tank with washed, rough sand, fine vermiculite, a soil-free mixture, or
potting soil), - phosphoric acid - a 'cool white 33' fluorescent tubelight with
the proper armature, - ventilation, - clean working methods, and clean
surroundings, - 'green fingers' In contrast to raising echo $weed_word2;?> plants, for
which we use 400 Watt or 600 Watt high-pressure gas lamps, clones develop their
roots best under fluorescent light. Fluorescent tubes emit light primarily in
the blue spectrum. Controlling the temperature when using fluorescent lights is
also less complicated, because fluorescent tubes give off little heat. The
fluorescent tube armature is mounted approximately 25 cm above the tops of the
clones. We're going to illuminate the cuttings 18 or 24 hours per day. We keep
the light on 24 hours a day during the cold months. The illumination times
suggested here are a guide. What it actually involves is allowing the
climatological conditions to vary as little as possible. You get the best
results with an even climate. It requires some experience to create the optimum
conditions. The hemp cuttings form their roots best at a temperature of 25 to 26
degrees Celsius, and a relative air humidity of 70-75%. Just as is the case with
actual growing, climate control is very important for cuttings. Moulds and pests
insects must never get a chance. Above all, mould spores can cause problems if
the climatic conditions aren't optimal. In principle, every part of a hemp plant
is suitable to use as a cutting. But a single leaf with a few roots is of no use
of course In any case, a good cutting has a growth-point. The size of the
cutting doesn't matter so much; a 2 cm cutting can grow to be a top-quality
plant, just like a 10 cm cutting. Before you put the cutting in the growth
medium, you have to make preparations. We're talking about raising cuttings in
rockwool substrate. First, the growing tray should be soaked in a nutrient
solution. The pH value must be 5.8, the EC value 0.8 to 1.0. To reach a pH value
of 5.8, your best to use phosphoric acid. The advantage of phosphoric acid is
that it helps the cuttings develop roots. We fill the tray for the cuttings with
the nutrient solution and drain it off again. We do this several hours before
taking cuttings from the mother plant. The cuttings are clipped, or cut with a
sharp knife or scissors. Take care not to leave the ends frayed. A clean cutting
loses less sap than a cutting with a frayed end. Moreover, there's the risk that
ravelled parts of the plant will rot. Directly after clipping or cutting, we dip
the clone first in water, and then in rooting hormones. Then we stick the
cutting into the rockwool plug. The growing tray for the cuttings must then be
saturated for 3 or 4 days with nutrient solution. Good hygiene is very important
when getting echo $weed_word2;?> cuttings to root. Work as clean as possible. Always clean
your scissors, knife and growing trays with a medical disinfectant (i.e. Dettol)
after you've used them. Check the clones daily for possible rotting parts.
Rotting leaves or stems must always be removed, so that moulds won't get a
chance. It's also important not to put the clone tray in a bed of water. That
makes rooting more troublesome, and the roots will be of less quality. Also, a
too wet clone tray causes root rots such as pythium a fungus on the roots. Just
like all plants, hemp cuttings also need fresh air containing CO2. We have to
ventilate the clone room, too. Sometimes, ventilation is necessary to keep the
temperature stable. When using a ventilator, you must try to create an optimal
climate without exposing the plants to gale force 9. The cuttings can dry out as
a consequence of too much air movement. When you have all the climatic
conditions under control, you can start waiting for roots to develop. It takes
about 10 days before you see the first results with healthy plants. After a
fortnight, healthy cuttings will have enough roots to be transplanted. In
principal, approximately 80% of the cuttings will root, if you control the
climate well. Allow the cuttings which have no roots after a fortnight one more
week. These cuttings can produce a plant of lesser quality. If no roots have
grown after 3 weeks, you can throw those cuttings away. Don't count on all the
cuttings taking root; plant about 20% more than you ultimately intend to keep.
Planting rooted clones is a tedious job. The root systems of the young plants
are very tender, and can easily be damaged. The extremely small root hairs are
very important for a healthy plant. Many splendid cuttings have been ruined by
rough transplanting. The roots of plants don't like light (they grow in the
dark), and air (they dry out quickly). The young plants will now go to the spot
where they will spend the rest of their lives. For plants, transplanting more
than once is just as traumatic as making people move house twice a month! Now,
the plants must become accustomed to their new surroundings. They must get
sufficient water, but not yet the full amount of light. After a few days, the
real irrigation schedule can begin, and the plants go under the full light of
the high-pressure gas lamps. The vegetative, or growth phase begins.
7.3. The vegetative phase
In this phase, the plants are
illuminated 18 hours per day, and kept in darkness 6 hours per day. If all
aspects are in order, (sufficient light, proper ventilation, good temperature,
enough water and nutrients, in short, complete climate control), the plants will
grow quickly; up to 5 cm per day. The duration of the vegetative stage is
strongly dependent on the control of climate. The better the climatic
conditions, the earlier the cutting takes root. The vegetative phase lasts from
3 to 10 days at maximum. We'll discuss growing 15 plants per square meter. If we
want to use the surface area to the maximum, then we must prune the plants, -
break off the uppermost part. pruning is possible only with plants that have
rooted and begun to grow. If this is not the case, breaking or clipping the tops
off should be postponed for a couple of days. By pruning the plants, we ensure
that they not only grow tall, but wide, as well. After cutting off the tops, we
leave the plant in the vegetative stage (18-hour cycle) for a few more days.
When the off-shoots have grown 3 - 4 cm, we start the generative phase. If all
goes well, three or four large tops will then form on each plant. Then we're
ready to get around 50 tops per square meter. To get a wider plant, you can now
break off the top-most part of the plant. Further pruning is not necessary.
Pruning makes the plant grow fuller. That's not to say you get a bigger plant,
because you've also taken something away. Since the vegetative phase lasts only
a short time, the plant must quickly make up for the damage. After pruning the
top, two new branches will appear from the budding site just under the spot
where the top was. Be very careful with pruning! It's a more painful experience
for a plant than trimming your own nails. After pruning, it's not unlikely for
growth to be delayed for a few days. It needs no further explanation that a
clean, razor-sharp knife or garden scissors should be used. Actually, we can
only think of one good reason for pruning. When branches don't grow well, or are
sickly or too thin, in short; unhealthy, you can, of course, carefully remove
them. With pruning, it always involves the removal of the whole branch. Take
care to touch the leaves as little as possible. That can easily disturb the
workings of the stomata in the leaves. Some people swear by removing leaves in
order to allow more light to reach other leaves. This is necessary, moreover,
part of the growth capacity is lost. It's also unnecessary to remove dying
leaves. You only have to clear these away after they've fallen off the plant.
Picking them off earlier might again cause damage to the plant.
7.4. The generative phase
After one week at maximum, we
will shorten the illumination time, and adapt the irrigation schedule
accordingly. We keep giving water 6 times per light cycle. Give water and
fertilizer during the period that the light is on, and not during the dark
period. In the flowering, or generative phase, the plants are in the light for
12 hours, and in darkness for 12 hours. We imitate a shortening of the day in
autumn, a sign for the plant to start flowering and forming seeds during its
last phase of life. In the generative phase, the plant's emphasis is less on
growth. Less chlorophyll is produced and in the flowering phase, we often see
fewer fingers forming on the echo $weed_word2;?> leaf. The plant needs less blue light
during the flowering phase (that was important for chlorophyll production in the
leaves), and it needs more red light. The autumn sun produces more red light,
because the autumn sun is lower in the sky.That doesn't mean that you must now
use only the sodium lamps. With only red light, the plants lose their vegetative
leaves (they turn yellow and fall off easily), while the stem of the plant is
lengthened. The distance between the branches (also called the 'internode')
increases. When we just let the mercury-iodide lamps supply the plants with blue
light, this effect won't occur so easily. The supply of water and nutrients
continues. The time between irrigations is shortened, so that the plants are
still irrigated during each light cycle. Not in order to push the plants to grow
as fast as possible, but to keep the metabolism at level, and to produce resins.
The female plants will show their first flowers after a week or two. The
following period lasts at least 60 days, depending on the variety. With some of
the plants, the blooming period lasts up to 90 days. It's worth the trouble to
be patient for the full flowering period before you start harvesting. Harvesting
during that time stresses the plants, which can ultimately cause a decreased
7.5. Harvesting and
In this book, we assume
you've raised female echo $weed_word2;?> plants from clones. When you've sprouted male as
well as female plants, there will be some work sorting them out. The males
flower earlier than the females. If you leave the males with the females, the
females will be fertilized. The females then form seed, causing the tops to be
smaller. The yield is lower (why did we start growing in the first place?). If
you've sprouted males, you have to be sure to harvest them before the pollen
reaches the female plants. When you grow only females, you don't have this
trouble. There are various methods to harvest echo $weed_word2;?>. Some people cut the
whole plant down, then hang it up to dry. Others break the largest leaves off
several days before harvest, so there will be less waste. Hanging the plants, or
the tops, upside down has no effect on the THC content in the tops. The resin
doesn't flow. What's important with echo $weed_word2;?> is the even drying of the THC -
containing parts of the plant. What's also important is patience. Generally,
drying goes quicker if you remove the stems which contain the most moisture.
Using a microwave, or an ordinary oven, a hair dryer, or a fan does make drying
faster, but usually also causes a (much) sharper taste. Even drying in air
prevents as much as possible the loss of THC, and produces evenly dried buds
with a soft taste. Controlling the climate also remains important after the
harvest. Many harvests have been lost due to spider mites and mould. For the THC
glands so important to us, light, heat, and friction are the most important
things to avoid. Once dried, echo $weed_word2;?> can best be kept air-tight in a
reasonably cool, dark place. Air-tight glass jars are ideal.
We'll talk about 'skuff'.
This is the sifting of dried tops. When you sift your dried harvest first
through a rough, then through a fine sieve, you remove all the remaining plant
remnants, and get balls of resin (thus; THC) left on the sieve. It's a fairly
simple, but time consuming job. Sift the dried harvest first through a size T-44
sieve. The THC falls through (with a little extra material). We have a T-77 size
sieve under the T-44. You must carefully rub your harvest through the T-77
sieve. Then you have THC in it's pure form without chemical processing
7.7. Setting up the
After the harvest, you must
make sure you can literally start the following growth with a clean slate. First
remove all the leftover plant parts. These go in the trash or in the organic
waste, unless you have a compost heap. Then remove all the rockwool material.
The rockwool still contains a lot of water.
Tip: see if you can
use an old wringer, or a centrifuge. That will decrease the volume of the
disposed rockwool by half. The following step is to disinfect the equipment. Any
commercial disinfectant will do. Read the label to see how much to dilute it.
Clean your irrigation system with disinfectant, and always thoroughly rinse
afterwards. Possible calcium build-up on your humidifier should be removed.
Cleaning lamps and reflective material is the next step. The lamp should be off,
and completely cooled. Don't touch the lamp with your hands, because bodily
acids can easily burn them. Resulting in shorter lamp life. Everything is now
ready for the next growth. Lay out new rockwool material and wet it. It's time
for new planting, so the timer clock goes back to 18 hours, and the irrigation
to once every three hours.
old rockwoolslab in the wringer
Chapter 8: echo $weed_Word1;?>
Diseases Pests and Plagues
echo $weed_Word1;?> plants are living
material. They'll stay healthy if we make sure all the climatological conditions
are right. We've already stated earlier that this involves light, air, water,
clean surroundings, and green fingers. Controlling the climate, in all its
aspects, is the best way to prevent echo $weed_word2;?> diseases and insects. That doesn't
mean that the careful echo $weed_word2;?> weed grower, who has everything well in order,
will never be bothered by echo $weed_word2;?> plant diseases and pests. We do want to say
that good climate control considerably reduces the risks of echo $weed_word2;?> disease.
8.2. echo $weed_Word1;?> Diseases
An easily preventable form of
disease is deficiency- or deprivation illness. The echo $weed_word2;?> plants lack some
necessary ingredient in their feeding. A shortage of iron produces yellowed (and
falling) echo $weed_word2;?> leaves. The pH value plays an important role in the prevention
of deficiency disease. Keep the pH value around 5.8. If this value is too low,
the plants can't absorb calcium as well. Consequence: the osmotic processes are
impeded. Too low a pH number causes less iron in-take, with the well- known
results. A second form of deficiency disease is caused by a shortage of the
primary nutrients (NPK). It often involves a lack of nitrogen (N). A nitrogen
shortage delays echo $weed_word2;?> growth, and makes the lower-most echo $weed_word2;?> echo $weed_word2;?>
leaves turn yellow and drop off. Less often, we see a shortage of phosphate (P).
With a phosphate shortage, the echo $weed_word2;?> echo $weed_word2;?> leaves turn deep green, and
they remain small. Yellowing and dying lower echo $weed_word2;?> echo $weed_word2;?> leaves happen
here, also. Potassium shortage (potassium is 'K') is another seldom-occuring
problem. The noticeable feature is first the yellowing of the point of the
echo $weed_word2;?> leaf, after which the whole echo $weed_word2;?> leaf turns yellow and brown, and
dies off. A lack of potassium is more often caused by an acidic soil than by an
actual potassium shortage. So, make sure to maintain an optimal pH! The remedy
advised for these kinds of deprivation sicknesses: use NPK fertilizer. We don't
encounter deficiency disease as a consequence of a shortage of the secondary
nutrients very often. This usually involves a lack of magnesium and/or calcium.
It can usually be remedied by using an NPK mixture containing trace elements.
The same counts for the micro-elements. We must make an exception for iron,
since there is rarely too little iron. In that case, the pH value is usually too
high. Moulds can completely destroy a garden in a short time. If the climate in
the echo $weed_word2;?> grow room is well-controlled, moulds, in general, have little
chance. Moulds and fungi thrive very well under hummid conditions, preferably
without much air circulation. Under these circumstances, mould spores, which are
always present in the air, search for a spot to grow into mould cultures. If you
don't succeed in preventing mould growth, then you must do something about it as
quickly as possible. With light mould growth, immediately remove the affected
plant parts, and then create a climate in which echo $weed_word2;?> does well, and moulds
don't (good ventilation, control of humidity and temperature, and putting your
plants on a medium which is not too wet). If there's already too much mould
present, you don't have much choice but to spray with poison (fungicide). Repeat
the treatment after a few days, even if you think the first application has
definitely helped. Still, improve climate control and groth conditions.
Fungicide treatment should always be a last resort. It's not healthy for
echo $weed_word2;?> young plants or people, so here, it's also: 'prevention is better than
cure' An often-occuring mould affecting echo $weed_word2;?> is pythium. This mould causes
root-rot, and rot in the lowest part of the stem. It appears most in young
echo $weed_word2;?> plants, and in cuttings. Larger, healthy plants are less sensitive to
pythium. Plants get 'falling-over disease' with a serious pythium attack. We
don't have to explain what that means Pythium is recognizable by the bark at the
base of the stem turning brown. In the beginning, the 'brown attack' is easily
removable. Later, the rotting process eats deeper into the base of the plant.
Pythium is a fungus which flourishes best in wet and humid environments. Pythium
spores spread only through water. Two kinds of spores are formed, Swarming ones
and stable ones. The swarming spores germinate best at a temperature of
approximately 15 degrees Celsius, while the stable spores germinate if it's
relatively warm, around 28 degrees C. To prevent a pythium attack, a constant
temperature of the soil or rockwool is needed. Large fluctuations in temperature
should be avoided. Pythium can only be fought in a limited manner with
chemicals. A proper relative humidity must also be maintained (not too high).
Leaf moulds, such as mildew, and thread moulds occur less frequently than
pythium. Mildew can cause tops to rot, among other things. Also here counts:
ensure optimal climate control. Contrary to other moulds, mildew flourishes well
at a low relative humidity. Mildew can be more easily fought with chemicals, and
fortunately, is not often found with echo $weed_word2;?>. Rotting tops occur mainly at the
end of the flowering phase. The more compact the plant, the bigger the chance
for tops to rot. You can identify toprot by the sudden yellowing of the top-most
echo $weed_word2;?> leaves. These yellow echo $weed_word2;?> leaves are fairly loose on the plant, and
can be easily removed. To prevent the whole plant from being affected, you must,
unfortunately, remove the whole top. The appearance of toprot can be prevented
in some cases, by lowering the relative humidity during the dark period.
8.3. Plagues and Pests
The most frequently occuring
plague in echo $weed_word2;?> cultivation is spider mite. A spider mite isn't an insect, as
many people think, but actually a tiny spider. A spider mite is small, and
difficult to discover for the inexperienced eye. But the damage caused is
certainly visible. The mite feeds on the sap of the plant, mostly underneath
echo $weed_word2;?> leaves. White specks appear on the upper side of the leaf. After that,
you can find spider mites on the undersides of the echo $weed_word2;?> leaves, and on the
stem of the plant. Spider mites make small webs, which you can detect by
spraying with water. If there aren't to many spider mites, you can try to get
rid of them by removing them by hand. A tedious job.
Treating with insecticide generally gives a better result. In any case, repeat
the application after a few days, otherwise, you risk the chance that the whole
garden will be eaten. Spider mites can also be controlled with their natural
enemy Phytoseiulus persimilis; a predator mite which feeds on spider mites.
White flies are also a formidible opponent of the weed grower. It can't be
repeated enough, control the climate, and take care of healthy plants. Then,
insects will have the least chance to propagate.
White flies behave just like spider mites. The insect hides underneath the leaf,
and sucks it's dinner from it. Result: white spots on the top side of the leaf.
White flies are easily spotted with the naked eye. If you shake the plant a
little, they'll fly around. They look like little white moths, around 2
millimeters in size. A sizeable infestation can be combatted with insecticide.
If you're not so anxious to use such strong methods, you can purchase a certain
type of 'assassinator' wasp, the ichneumon fly (the Latin name is Encarsia
formosa). This natural enemy doesn't sting people, but works well at eliminating
white flies. Since it's only a small wasp (smaller than the white fly itself),
it takes a while before all the white flies have disappeared. Additionally, you
have to put new assassinator wasps out approximately every two weeks.
Another common herbivore are thrips. They are small, fast-moving insects with
wings. They rasp, or grate the echo $weed_word2;?> leaves open, and then suck the sap out.
Thrips prefer bloom tops, and fresh, young echo $weed_word2;?> leaves. Affected echo $weed_word2;?>
leaves have shiny, silvery spots. This is caused by the thrips, which suck the
chlorophyll out of the echo $weed_word2;?> leaves. In spite of the fact that they're small,
you can see thrips marching in columns on an infested plant. Thrips can be
fought with insecticide. It's more environmentally friendly however to unleash
the thrips' natural enemy, the predator Amblyseius cucumeris. Lice are found
inside as well as outside. During the summer, when lice do the best outside,
they also do as well inside. Lice are the most interested in plants with
questionable health. There are two methods to kill lice, spraying with
insecticide, and setting out assassinator wasps. The problem with most flying
pest- destroyers is that they're attracted by the high-pressure gas lamps, which
draw them to a fiery death.
The starting point for
cultivating echo $weed_word2;?> is successful climate control. This goes two ways, the
plants do well and produce the greatest possible yield, and diseases and pests
get the least possible chance. So, create a good climate, and don't forget
hygiene If you're bothered by diseases and/or insects, preferably use natural
methods of control rather than chemical remedies. You can fight your pests by
releasing their natural enemies, or by spraying with organic solutions for
diseases and/or pests. Use chemical pesticides only if nothing else works.
Always stop using pesticides a few weeks before harvest, otherwise, you'll be
smoking some of the poison later. Ultimately, fighting diseases and pests works
best only if you know how to optimally control the climate at the same time.
Along with climate control, the prevention (and if necessary, curing) of
deficiency disease demands an optimal mixture of fertilizers, and the control of
Absorption power - of echo $weed_word2;?> leaves
Air - intake of water
Air exchange ventilator
Air humidification Air pump Algae growth, - prevention of Amblyseius cucumeris
America Bird feed Boccaccio Boron Box ventilator Buyer Calcium Capillaries
Carbon dioxide Carbon filter ventilator Cellulose China Chlorophyll Clean-up
Climate control, - after harvesting - with regards to diseases and insects CO2,
- controller - enrichment and growing tempe rature - necessary for echo $weed_word2;?> -
raising the content of Combination lamps Communicating vessels Cuttings, - and
climate control - and hygiene - illumination period - necessities for -
transplanting - waiting time for Cutting tray Dark period, - and relative
humidity Dark response Decontamination Deficiency disease, - and the pH value -
due to improper feeding - prevention of Diseases Dodoens Drain sets Drain water
Drying Dumas Electrical ballast equipment Electrical conductivity (EC), -
calibration of EC meter - EC meter - EC value - optimal EC value - optimal EC
value for cuttings Encarsia formosa Fertilization, - influence on THC production
Floor Fluorescent lamps Flowering period Flowering phase Fungicides Generative
phase Glucose Golden Age growing space, - contents of - layout Growth, -
principals of Growth phase Growth point of cuttings Halogen lamps Harvesting, -
female plants - male plants - methods of Heating element Herodote High-pressure
gas lamps, - and safety - cleaning - life of - use of Hugo Illumination period,
- in the flowering phase - in the growth phase Immersible pump Insecticides
Insect pests Internode Iron Irrigation system, - construction of - testing of -
with timer clock Lace -wing flies Ladybugs Lamps, - 1000 Watt - choice of -
distance from the plants - light yield - power Law of minimums Law on narcotics
Leaf green Libra trays Lice Light, - blue - red - wavelength of Light bulbs
Light intensity Light response Magnesium Manganese Matt white paint Medicine, -
hemp as Mercury -iodide lamps Moulds, - sprays against Mother plant, - for
cuttings Necessities for home growing Netherlands, The NPK, - remedy for
deficiency disease Nitrogen Nutrients, - micro - primary - secondary Osmosis
Osmotic filter Outside air, - CO2 content in Over-fertilization Paris
Polyethylene filter Polyethylene hose pH meter, - calibration of pH value, - for
the roots of cuttings - ideal Phosphate Photolysis Photosynthesis Phototropism
Phytoseiulus persimilis Plant physiology Potassium Predator Pruning Pythium
Rabelais Reflective value Relative humidity, - for cuttings - for the roots of
cuttings Remedies, - for diseases and pests Rockwool blocks Root hairs Safety, -
and high-pressure gas lamps - and use of electrical power - and water -
'invisible' cultivation Saltpetre/phosphoric acid Salts, - and osmosis Sap flow
Semi-professional, - growing Shopping list Sifting Skytes Skuff Sodium lamps
Soil -the conditioning of Sowing Spider mite Sprinklers Stomata, - function of -
vulnerability of Storing, - of the harvest Sulphur Super-wide -angle reflectors
Table fan Temperature, - and air exchange ventilator - for rooting clones -
ideal - in the dark period - in the growing space - in the plant - of the ground
- of the nutrient water - when calibrating EC and pH meters Thermometer Thrips
Timer switch Topping Toprot Trace elements Vegetative phase Ventilation, - and
CO2 needs - and relative humidity - capacity - drawing off heat - for rooting
clones Ventilation system, - construction of Vinkenoog Water, - functions of -
quality of Water purification White flies Wide-angle reflectors Zinc
echo $weed_WORD3;?> HISTORY