Farmer's cycle of the seeds.

Chapter 3, page 2.

3.2 3.1 Applications in agriculture.
3.2 The fats' cycle.
3.3 In the garden centers.
3.4 Viability variation: risks and benefits.

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The fats' cycle of the seeds.

.1 The sunflower seeds, and all the other seeds as well, are subjected to another cycle.

.2 I name it “fats' cycle”.

.3 I could well name it “farmer’s cycle” because the farmers of my region, Veneto, from time immemorial, have kept it in mind when they have to sow some kinds of seeds, to favour the development of specific parts of a plant.

The passagge of the seed spatiole.

.4 The fats’ cycle is characterized by the times of the passage of the seed spatiole, a mobile area on which, at a given time, the action by the Moon, on the EFAs molecules in the seeds, is best focused.

Virtual spatiole.

.5 A seed spatiole is virtual. It would become active, and induce configurational dissipative reactions, in the EFAs contained in the seeds, on condition that the excess energy be dispersed out of the system.

Quantity of heat dissipated.

.6 The first variable is the quantity of energy which can be dissipated. Indeed, the fats’ cycle becomes operative when the spatiole happens to be in the section of the day, when the temperature is decreasing. Then, many configurational dissipative reactions may take place, because their discard energy, most of it in the form of heat, is easily dispersed.

The variants of the seed spatiole.

.7 In a semi-diurnal system, where the spatiole comes two times a day, the spatiole in question has two main variants, called “spatiole A”, and “spatiole E”.

.8 (Letters B, C, D, F, G, H are reserved for other six variants, whose existence has not yet been ruled out; they could just remain artefacts in the “experiment B”).

.9 The “spatiole A” is also called “strong spatiole”, because it is then that the genetic characteristics seem better transferred, in the sense that then the part of the plant better served is the seed. Conversely, the “spatiole E” is also called “weak spatiole”, even if it could have to carry out important functions, as yet to be found.

.10 The aforesaid variants appear to depend on the positions taken by the Moon, in the retrograde sense.

The times of the passage.

.11 The times of the passage of the seed spatiole would depend on the location (assertion unsupported by experiments, which should be carried out in different parts of the Earth).

.12 The “spatiole A” is opposed to the “spatiole E”.

.13 For instance, in the locality of the experiments, when there is full moon, the passage of the “spatiole” is at around 4 o'clock p.m, if in context A, while it is at around 4 o'clock a.m., if in context E.

.14
Then, on the successive days, all the variants of the seed spatiole occur at earlier hours. Until, at the new moon, for instance, the strong spatiole will be found at around 4 o'clock a.m. in context A.

When the variants are active.

.15 Thus, in the locality of the experiments, the “spatiole A” is active above all during the period between new moon and full moon (in italian, crescer di luna).

.16 The opposing spatiole, “spatiole E”, will become active above all during the period between full moon and new moon (calar di luna).

.17 During some days, the spatiole may become active twice, in case each time there is sufficient dissipative flux.

The time windows.

.18 At present, one cannot rule out the existence of another cycle : the value of coincidence of one of the two spatioles (mobile elements) with one of the time windows (almost fixed elements).

At present, it is an hypothesis in limbo; see insert H.

.19 In my region, there would be 16 time windows per natural day, one every 90 natural minutes (not conventional).

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	Chapter 3, page 2.

3.2	3.1 Applications in agriculture. 3.2 The fats' cycle. 3.3 In the garden centers. 3.4 Viability variation: risks and benefits.
	\|\|\| contents



	The fats' cycle of the seeds.
.1	The sunflower seeds, and all the other seeds as well, are subjected to another cycle.
.2	I name it “fats' cycle”.
.3	I could well name it “farmer’s cycle” because the farmers of my region, Veneto, from time immemorial, have kept it in mind when they have to sow some kinds of seeds, to favour the development of specific parts of a plant.
	The passagge of the seed spatiole.
.4	The fats’ cycle is characterized by the times of the passage of the seed spatiole, a mobile area on which, at a given time, the action by the Moon, on the EFAs molecules in the seeds, is best focused.
	Virtual spatiole.
.5	A seed spatiole is virtual. It would become active, and induce configurational dissipative reactions, in the EFAs contained in the seeds, on condition that the excess energy be dispersed out of the system.
	Quantity of heat dissipated.
.6	The first variable is the quantity of energy which can be dissipated. Indeed, the fats’ cycle becomes operative when the spatiole happens to be in the section of the day, when the temperature is decreasing. Then, many configurational dissipative reactions may take place, because their discard energy, most of it in the form of heat, is easily dispersed.
	The variants of the seed spatiole.
.7	In a semi-diurnal system, where the spatiole comes two times a day, the spatiole in question has two main variants, called “spatiole A”, and “spatiole E”.
.8	(Letters B, C, D, F, G, H are reserved for other six variants, whose existence has not yet been ruled out; they could just remain artefacts in the “experiment B”).
.9	The “spatiole A” is also called “strong spatiole”, because it is then that the genetic characteristics seem better transferred, in the sense that then the part of the plant better served is the seed. Conversely, the “spatiole E” is also called “weak spatiole”, even if it could have to carry out important functions, as yet to be found.
.10	The aforesaid variants appear to depend on the positions taken by the Moon, in the retrograde sense.
	The times of the passage.
.11	The times of the passage of the seed spatiole would depend on the location (assertion unsupported by experiments, which should be carried out in different parts of the Earth).
.12	The “spatiole A” is opposed to the “spatiole E”.
.13	For instance, in the locality of the experiments, when there is full moon, the passage of the “spatiole” is at around 4 o'clock p.m, if in context A, while it is at around 4 o'clock a.m., if in context E.
.14	Then, on the successive days, all the variants of the seed spatiole occur at earlier hours. Until, at the new moon, for instance, the strong spatiole will be found at around 4 o'clock a.m. in context A.
	When the variants are active.
.15	Thus, in the locality of the experiments, the “spatiole A” is active above all during the period between new moon and full moon (in italian, crescer di luna).
.16	The opposing spatiole, “spatiole E”, will become active above all during the period between full moon and new moon (calar di luna).
.17	During some days, the spatiole may become active twice, in case each time there is sufficient dissipative flux.
	The time windows.
.18	At present, one cannot rule out the existence of another cycle : the value of coincidence of one of the two spatioles (mobile elements) with one of the time windows (almost fixed elements).
	At present, it is an hypothesis in limbo; see insert H.
.19	In my region, there would be 16 time windows per natural day, one every 90 natural minutes (not conventional).



	continued \|\|\| © copyright notice