hogbud
Well-Known Member
Both
Hey New Growers, Let's try this again?
- Thread starter hogbud
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TryN
Well-Known Member
That is exactly what I plan studying this summer. UVR on trichome "strength" and trichome quantity. I have read some fascinating research on it.
dannyboy602
Well-Known Member
Hey can u link me to your research? I'm fascinated by the subject. Thx.
hogbud
Well-Known Member
here is where Lumi started,,, in many parts LOL
marijuana OPTICS
An elaboration on the phytochemical process that makes THC
A Continuing updating manual
by Joe Knuc
The resin exuded by the glandular trichrome forms a sphere(1) that encases the head cells.(2)
When the resin spheres are separated from the dried plant material by electrostatic(3) attraction and placed on a microscope slide illuminated with a 100W incandescent bulb, they appear very dark when observed through a 300X microscope. Since orange, red, and infrared are the component wavelengths of incandescent light, and since the absorption of light makes an object dark or opaque to the frequency of the incoming wave, one can conclude that these wavelengths are probably not directly involved in energizing the cannabinoid pathway.(4)
However, the resin sphere is transparent to ultraviolet radiation.(5)
The author found through trial and error that only one glandular
trichome(6) exhibits the phytochemical process that will produce the amount of THC associated with pain relief, appetite stimulation and anti-nausea; euphoria and hallucinations are side-effects, however. This trichome is triggered into growth by either of the two ways that the floral bract is turned into fruit.(7)
Of all the ways that optics are involved in the phytochemical production of THC, the most interesting has to be how the head cells and cannabinoid molecules are tremendously magnified( by the resin sphere. These and other facts are curiously absent from the literature. The footnotes update the literature to include electrostatic separation of the resin sphere from the dried plant material and marijuana parthenocarpy.
(1) "For all spheres, a ray drawn perpendicular to the sphere's surface will intersect the center of the sphere, no matter what spot on the surface is picked, and the magnifying power(a) of a glass sphere is greater the smaller its size. A sphere of glass can also bring light that is heading to a focus behind it to a point within it, with freedom from two aberrations, spherial aberration and coma, but not from chromatic aberration. Chromatic aberration results when different wavelengths are focused on different planes and is the most difficult of the aberrations to correct. The human eye lens also exhibits chromatic aberration, but a yellow pigment(b) called the macula lutea in the fovea, an area at the rear of the eyeball, corrects this problem by the way it absorbs blue light."
(a)"The formula to calculate the magnifying power of a sphere is l=333/d, where l is the magnifying power and d is the diameter of the sphere expressed in mm."
(b)Interestingly, the resin exuded by drug-type flowering female marijuana plants has a yellow tint. Could this pigment work to correct chromatic aberration in the resin sphere like the macula lutea does in the fovea for the eyeball?
(2) Quoting from the Mahlberg and Kim study of hemp(a) "THC accumulated in abundance in the secretory cavity where it was associated with the following: cell walls, surface feature of secretory vesicles, fibrillar material released from disc cell wall, and cuticle. It was not associated with the content of the secretory vesicles."
The resin spheres contain the THC. It is not contained in the leaf or floral bract. After the resin spheres are dissolved in solvent or dislodged by electrostatic attraction, and a microscopic examination of the leaf or floral bract has revealed that only the glandular trichomes' stalks remain, no effect will be felt after smoking the dried plant material from which the resin spheres have been removed.
(3) The electrostatic collection of the resin spheres from dried marijuana plants with plenty of ripe seeds has been for hundreds of years the method indigenous people of North Africa and Lebanon have used to make hashish. Obtain a round metal can 8" or so in diameter x 3" or so in depth (the kind that cookies come in) with a smooth lid. Obtain 2 ounces of dried marijuana with plenty of ripe seeds in the tops. To remove the seeds and stems, sift the marijuana tops through a 10-hole-to-the-inch wire kitchen strainer into the can. Close the can with the lid and vigorously shake the closed can three or four times. This gives the resin spheres an excess negative charge. Let the can sit for a moment and then remove the lid. Opposites attract. The negative-charged resin spheres have been attracted to the metal surface of the can and lid which has a positive charge. Take a matchbook cover or credit card and draw the edge across the surface of the lid. Note the collected powder. Observed under 300X magnification, the collected powder from this "shake" is composed of resin spheres with an occasional non-glandular trichome. As the marijuana is shaken again and again, and more of the yellow resin spheres are removed from the plant material, the collected powder gradually becomes green-colored as the number of non-glandular trichomes increases in the collected powder. The greener the powder, the less the effect.
(4) "Cannabinoids represent a dimer consisting of a terpene and a phenol component. Cannabigerol (CBG) is the first component of the pathway. It undergoes chemical change to form either cannabichromene (CBC), or cannabidiol (CBD). Delta 9-tetrahydrocannabinol (THC) is derived from CBD."
(5) "Pate (1983) indicated that in areas of high ultraviolet radiation exposure, the UVB (280-320 nm) absorption properties of THC may have conferred an evolutionary advantage to Cannabis capable of greater production of this compound from biogenetic precursor CBD. The extent to which this production is also influenced by environmental UVB has also been experimentally determined by Lydon et al. (1987)."
The author's own experience allow for a more specific conclusion: If the UVB photon is missing from the light stream(a), or the intensity as expressed in µW/cm2 falls below a certain level(b), the phytochemical process will not be completely energized with only UVA photons which are more penetrating but less energetic, and the harvested resin spheres will have mostly precursor compounds and not fully realized THC(c).
(a)Examples of an environment where the UVB photon would be missing from the light stream include all indoor cultivation illuminated by mercury or sodium lamps and in glass, polyethylene or fiberglass covered greenhouses.
(b)"The maximum UVB irradiance near the equator (solar elevation angle less than 25 deg.) under clear, sunny skies is about 250 µW/cm2. It was observed that the daily solar UVB in Riyadh, Saudi Arabia (N24.4Lat.) decreased from September to December by about 40% (Hannan et al. 1984)." The further a person is from the tropics, the less UVB radiation there is: the average annual exposure of a person living in Hawaii is approximately four times that of someone living in northern Europe. "Some reptiles, mainly lizards, turtles, tortoises and crocodilians, require UVB to make vitamin D3. Green Iguanas will start to show signs of metabolic bone disease at 6 months of age if not exposed to UVB wavelengths. A rubber jaw, shaking and non-use of hind legs are all signs of metabolic bone disease. Metabolic bone disease is perhaps the most common nutritional deficiency affecting captive reptiles. UVA and UVB wavelengths help to prevent or reverse this disease which is commonly seen in young captive lizards; these wavelengths also help to increase appetite and activity in lizards and turtles who require more UVA and UVB than pythons and snakes to induce reproductive behavior. Even though snakes get their vitamin D3 from the livers of the animals they eat (mice, rats, etc.), snakes and amphibians benefit from the UVA wavelength." Below are some UVB readings taken in Hoyleton, Illinois, on a clear sunny day in June by David Krughoff as reported in Reptile Lighting 2000.
7am: 12 microwatts/cm2
8am: 74 microwatts/cm2
9am: 142 microwatts/cm2
10am: 192 microwatts/cm2
11am: 233 microwatts/cm2
12pm: 256 microwatts/cm2
1pm: 269 microwatts/cm2
2pm: 262 microwatts/cm2
3pm: 239 microwatts/cm2
4pm: 187 microwatts/cm2
5pm: 131 microwatts/cm2
6pm: 61 microwatts/cm2
(c)Cannabinoid pathway: Anywhere in this pathway UVB does a better job than UVA in energizing a phytochemical reaction that will produce more fully realized THC because "all cannabinolic compounds show an absorption maximum between 270 and 280 nm in the ultraviolet region."
(6) Capitate-stalked glandular trichome.
marijuana OPTICS
An elaboration on the phytochemical process that makes THC
A Continuing updating manual
by Joe Knuc
The resin exuded by the glandular trichrome forms a sphere(1) that encases the head cells.(2)
When the resin spheres are separated from the dried plant material by electrostatic(3) attraction and placed on a microscope slide illuminated with a 100W incandescent bulb, they appear very dark when observed through a 300X microscope. Since orange, red, and infrared are the component wavelengths of incandescent light, and since the absorption of light makes an object dark or opaque to the frequency of the incoming wave, one can conclude that these wavelengths are probably not directly involved in energizing the cannabinoid pathway.(4)
However, the resin sphere is transparent to ultraviolet radiation.(5)
The author found through trial and error that only one glandular
trichome(6) exhibits the phytochemical process that will produce the amount of THC associated with pain relief, appetite stimulation and anti-nausea; euphoria and hallucinations are side-effects, however. This trichome is triggered into growth by either of the two ways that the floral bract is turned into fruit.(7)
Of all the ways that optics are involved in the phytochemical production of THC, the most interesting has to be how the head cells and cannabinoid molecules are tremendously magnified( by the resin sphere. These and other facts are curiously absent from the literature. The footnotes update the literature to include electrostatic separation of the resin sphere from the dried plant material and marijuana parthenocarpy.
(1) "For all spheres, a ray drawn perpendicular to the sphere's surface will intersect the center of the sphere, no matter what spot on the surface is picked, and the magnifying power(a) of a glass sphere is greater the smaller its size. A sphere of glass can also bring light that is heading to a focus behind it to a point within it, with freedom from two aberrations, spherial aberration and coma, but not from chromatic aberration. Chromatic aberration results when different wavelengths are focused on different planes and is the most difficult of the aberrations to correct. The human eye lens also exhibits chromatic aberration, but a yellow pigment(b) called the macula lutea in the fovea, an area at the rear of the eyeball, corrects this problem by the way it absorbs blue light."
(a)"The formula to calculate the magnifying power of a sphere is l=333/d, where l is the magnifying power and d is the diameter of the sphere expressed in mm."
(b)Interestingly, the resin exuded by drug-type flowering female marijuana plants has a yellow tint. Could this pigment work to correct chromatic aberration in the resin sphere like the macula lutea does in the fovea for the eyeball?
(2) Quoting from the Mahlberg and Kim study of hemp(a) "THC accumulated in abundance in the secretory cavity where it was associated with the following: cell walls, surface feature of secretory vesicles, fibrillar material released from disc cell wall, and cuticle. It was not associated with the content of the secretory vesicles."
The resin spheres contain the THC. It is not contained in the leaf or floral bract. After the resin spheres are dissolved in solvent or dislodged by electrostatic attraction, and a microscopic examination of the leaf or floral bract has revealed that only the glandular trichomes' stalks remain, no effect will be felt after smoking the dried plant material from which the resin spheres have been removed.
(3) The electrostatic collection of the resin spheres from dried marijuana plants with plenty of ripe seeds has been for hundreds of years the method indigenous people of North Africa and Lebanon have used to make hashish. Obtain a round metal can 8" or so in diameter x 3" or so in depth (the kind that cookies come in) with a smooth lid. Obtain 2 ounces of dried marijuana with plenty of ripe seeds in the tops. To remove the seeds and stems, sift the marijuana tops through a 10-hole-to-the-inch wire kitchen strainer into the can. Close the can with the lid and vigorously shake the closed can three or four times. This gives the resin spheres an excess negative charge. Let the can sit for a moment and then remove the lid. Opposites attract. The negative-charged resin spheres have been attracted to the metal surface of the can and lid which has a positive charge. Take a matchbook cover or credit card and draw the edge across the surface of the lid. Note the collected powder. Observed under 300X magnification, the collected powder from this "shake" is composed of resin spheres with an occasional non-glandular trichome. As the marijuana is shaken again and again, and more of the yellow resin spheres are removed from the plant material, the collected powder gradually becomes green-colored as the number of non-glandular trichomes increases in the collected powder. The greener the powder, the less the effect.
(4) "Cannabinoids represent a dimer consisting of a terpene and a phenol component. Cannabigerol (CBG) is the first component of the pathway. It undergoes chemical change to form either cannabichromene (CBC), or cannabidiol (CBD). Delta 9-tetrahydrocannabinol (THC) is derived from CBD."
(5) "Pate (1983) indicated that in areas of high ultraviolet radiation exposure, the UVB (280-320 nm) absorption properties of THC may have conferred an evolutionary advantage to Cannabis capable of greater production of this compound from biogenetic precursor CBD. The extent to which this production is also influenced by environmental UVB has also been experimentally determined by Lydon et al. (1987)."
The author's own experience allow for a more specific conclusion: If the UVB photon is missing from the light stream(a), or the intensity as expressed in µW/cm2 falls below a certain level(b), the phytochemical process will not be completely energized with only UVA photons which are more penetrating but less energetic, and the harvested resin spheres will have mostly precursor compounds and not fully realized THC(c).
(a)Examples of an environment where the UVB photon would be missing from the light stream include all indoor cultivation illuminated by mercury or sodium lamps and in glass, polyethylene or fiberglass covered greenhouses.
(b)"The maximum UVB irradiance near the equator (solar elevation angle less than 25 deg.) under clear, sunny skies is about 250 µW/cm2. It was observed that the daily solar UVB in Riyadh, Saudi Arabia (N24.4Lat.) decreased from September to December by about 40% (Hannan et al. 1984)." The further a person is from the tropics, the less UVB radiation there is: the average annual exposure of a person living in Hawaii is approximately four times that of someone living in northern Europe. "Some reptiles, mainly lizards, turtles, tortoises and crocodilians, require UVB to make vitamin D3. Green Iguanas will start to show signs of metabolic bone disease at 6 months of age if not exposed to UVB wavelengths. A rubber jaw, shaking and non-use of hind legs are all signs of metabolic bone disease. Metabolic bone disease is perhaps the most common nutritional deficiency affecting captive reptiles. UVA and UVB wavelengths help to prevent or reverse this disease which is commonly seen in young captive lizards; these wavelengths also help to increase appetite and activity in lizards and turtles who require more UVA and UVB than pythons and snakes to induce reproductive behavior. Even though snakes get their vitamin D3 from the livers of the animals they eat (mice, rats, etc.), snakes and amphibians benefit from the UVA wavelength." Below are some UVB readings taken in Hoyleton, Illinois, on a clear sunny day in June by David Krughoff as reported in Reptile Lighting 2000.
7am: 12 microwatts/cm2
8am: 74 microwatts/cm2
9am: 142 microwatts/cm2
10am: 192 microwatts/cm2
11am: 233 microwatts/cm2
12pm: 256 microwatts/cm2
1pm: 269 microwatts/cm2
2pm: 262 microwatts/cm2
3pm: 239 microwatts/cm2
4pm: 187 microwatts/cm2
5pm: 131 microwatts/cm2
6pm: 61 microwatts/cm2
(c)Cannabinoid pathway: Anywhere in this pathway UVB does a better job than UVA in energizing a phytochemical reaction that will produce more fully realized THC because "all cannabinolic compounds show an absorption maximum between 270 and 280 nm in the ultraviolet region."
(6) Capitate-stalked glandular trichome.
hogbud
Well-Known Member
(7) #1: The ovum has been fertilized and there is a seed developing: In the areas of the Northern Hemisphere where indigenous people have grown heterozygous drug-type marijuana for hundreds of years, pollination is used to trigger the growth of the capitate-stalked glandular trichome on the floral bract and concomitant leaves of the flowering females before the autumnal equinox(a) so the majority of seeds will be ripe(b) by mid-October.
(7) #2: The floral bract has become parthenocarpic: Parthenocarpic fruits develop without fertilization and have no seeds. Except for transmutation and turning lead into gold, there has been more nonsense written about seedless marijuana than on any other subject. In marijuana parthenocarpy, the floral bract (the fruit) enlarges in size as though there were a seed growing inside, and the capitate-stalked glandular trichome is triggered into growth on the floral bract and concomitant leaves. "Most popular supermarket tomatoes are parthenocarpic which was induced artificially by the application of dilute hormone sprays (such as auxins) to the flowers." In a trial, marijuana parthenocarpy was not induced by the application of the spray used on tomatoes.
Only the photoperiod(c) will trigger parthenocarpy in flowering female marijuana plants. marijuana parthenocarpy occurring before the autumnal equinox is considered by the author to be "long-day" and marijuana parthenocarpy occurring after the autumnal equinox to be "short-day". The longest photoperiod that will trigger parthenocarpy in unfertilized flowering homozygous(d) Indica female marijuana plants is 13:00 hours, give or take 15 minutes. This effect can be obtained in the month of August at N35Lat, and because the capitate-stalked glandular trichomes received plenty of UVB during this month at this latitude, the harvested resin spheres had fully realized THC. Rating: euphoria and hallucinations, major appetite boost and pain relief, deep dreamless sleep. These plants seldom grow taller than four feet but potency makes up for the reduced harvest.
The gene pool is heterozygous if a flowering female marijuana plant is not parthenocarpic by the end of the first week in September in the Northern Hemisphere. If this is the case, pollination is used instead of parthenocarpy to trigger the growth of the capitate-stalked glandular trichome before the autumnal equinox to obtain as much fully realized THC as possible in the harvested resin spheres by the time the majority of the seeds are ripe.
The longest photoperiod that will trigger parthenocarpy in unfertilized flowering heterozygous female marijuana plants is 11:00 hours, give or take 15 minutes: This effect can be obtained in the month of November at N35Lat. Because of the low intensity of UVB radiation at this latitude at sea level during November, the harvested resin spheres evidenced only slightly more THC than precursor compounds. Rating: mild to medium euphoria, appetite boost and pain relief, good snooze.
(7) #2: The floral bract has become parthenocarpic: Parthenocarpic fruits develop without fertilization and have no seeds. Except for transmutation and turning lead into gold, there has been more nonsense written about seedless marijuana than on any other subject. In marijuana parthenocarpy, the floral bract (the fruit) enlarges in size as though there were a seed growing inside, and the capitate-stalked glandular trichome is triggered into growth on the floral bract and concomitant leaves. "Most popular supermarket tomatoes are parthenocarpic which was induced artificially by the application of dilute hormone sprays (such as auxins) to the flowers." In a trial, marijuana parthenocarpy was not induced by the application of the spray used on tomatoes.
Only the photoperiod(c) will trigger parthenocarpy in flowering female marijuana plants. marijuana parthenocarpy occurring before the autumnal equinox is considered by the author to be "long-day" and marijuana parthenocarpy occurring after the autumnal equinox to be "short-day". The longest photoperiod that will trigger parthenocarpy in unfertilized flowering homozygous(d) Indica female marijuana plants is 13:00 hours, give or take 15 minutes. This effect can be obtained in the month of August at N35Lat, and because the capitate-stalked glandular trichomes received plenty of UVB during this month at this latitude, the harvested resin spheres had fully realized THC. Rating: euphoria and hallucinations, major appetite boost and pain relief, deep dreamless sleep. These plants seldom grow taller than four feet but potency makes up for the reduced harvest.
The gene pool is heterozygous if a flowering female marijuana plant is not parthenocarpic by the end of the first week in September in the Northern Hemisphere. If this is the case, pollination is used instead of parthenocarpy to trigger the growth of the capitate-stalked glandular trichome before the autumnal equinox to obtain as much fully realized THC as possible in the harvested resin spheres by the time the majority of the seeds are ripe.
The longest photoperiod that will trigger parthenocarpy in unfertilized flowering heterozygous female marijuana plants is 11:00 hours, give or take 15 minutes: This effect can be obtained in the month of November at N35Lat. Because of the low intensity of UVB radiation at this latitude at sea level during November, the harvested resin spheres evidenced only slightly more THC than precursor compounds. Rating: mild to medium euphoria, appetite boost and pain relief, good snooze.
hogbud
Well-Known Member
Thai marijuana falls into this 11:00 hour category, and its parthenocarpy is characterized by an inflorescence in which many floral bracts are attached to an elongated meristem. It is these elongated meristems that are harvested to become a THAI STICK. On the other side of the world, Mexican marijuana grown around the same latitudes (Michoacan, Guerrero, Oaxaca) also falls into this short-day parthenocarpic category and the unfertilized marijuana will become "sensimilla" in the 11:00 hour photoperiod which begins in mid-December in that region. The winter sunshine in those latitudes has enough UVB intensity to produce fully realized THC--unlike the winter sunshine at N35Lat.
All unfertilized flowering female marijuana plants will become parthenocarpic in a 9:00 hour photoperiod (15:00 hour dark period): This can be obtained in the month of December at N35Lat. At this latitude in this month there is not even enough UVB in sunlight for precursor vitamin D3 to develop in human skin. The phytochemical process will not produce fully realized THC when UVB falls below a certain level of intensity expressed in µW/cm2. Rating: no effect.
(a)In the Northern Hemisphere above the Tropic of Cancer, the key to all marijuana potency is this: The more days of sunlight the capitate-stalked glandular trichomes' resin spheres accumulate before the autumnal equinox the more fully realized THC.
(b)It is recognized in the indigenous world that drug-type marijuana with a majority of ripe seeds will produce more euphoria, hallucinations, appetite stimulation, pain relief, and sleep aid than with a majority of unripe seeds.
(c)The photoperiodic response is controlled by phytochrome. "Phytochrome is a blue pigment in the leaves and seeds of plants and is found in 2 forms. One form is a blue form(Pfr), which absorbs red light, and the other is a blue-green form(Pr) that absorbs far-red light. Solar energy has 10X more red (660nm) than far-red (730nm) light causing the accumulation of Pfr." The first and last hour of a day's sunlight is mostly red light because of the scattering effect on blue light. "So at the onset of the dark period much of the phytochrome is in the Pfr form. However, Pfr is unstable and returns to phytochrome Pr in the dark." The red light in sunrise returns the Pr to the Pfr form. "Phytochrome Pfr is the active form and controls flowering and germination. It inhibits flowering of short-day plants (the long night period is required for the conversion of Pfr to Pr) and promotes flowering of long day plants."
Kelvin Temperature is an easy key to the efficiency of artificial light to fuel photosynthesis or to affect the phytochrome. The former is fueled very efficiently by 6500K light: this is a Kelvin Temperature the same color as the sky at noon on a clear summer day. Some Mercury Vapor HID bulbs are rated 6500K. Metal Halide HID bulbs are rated 4000K and can be used instead of the mercury vapor with good results. A less expensive alternative to HID lights that will produce the same results on a smaller scale is the GE Daylight ULTRA 40-watt 48" fluorescent tube which is rated 6500K. 160W will deliver the desired effect to eight sq ft (2'x4') if the ballast in the two-lamp holder is a "high power factor" standard size; the smaller, energy-saver ballast provides less luminosity. The fluorescent tubes have to be closer to the plant meristem than the HID bulb. To obtain the desired effect with the fluorescent tubes in an environment that receives no supplemental sunlight, the distance to the plant meristem should not be greater than 2" for seedlings or 6" for transplants in one gallon and larger containers.
All unfertilized flowering female marijuana plants will become parthenocarpic in a 9:00 hour photoperiod (15:00 hour dark period): This can be obtained in the month of December at N35Lat. At this latitude in this month there is not even enough UVB in sunlight for precursor vitamin D3 to develop in human skin. The phytochemical process will not produce fully realized THC when UVB falls below a certain level of intensity expressed in µW/cm2. Rating: no effect.
(a)In the Northern Hemisphere above the Tropic of Cancer, the key to all marijuana potency is this: The more days of sunlight the capitate-stalked glandular trichomes' resin spheres accumulate before the autumnal equinox the more fully realized THC.
(b)It is recognized in the indigenous world that drug-type marijuana with a majority of ripe seeds will produce more euphoria, hallucinations, appetite stimulation, pain relief, and sleep aid than with a majority of unripe seeds.
(c)The photoperiodic response is controlled by phytochrome. "Phytochrome is a blue pigment in the leaves and seeds of plants and is found in 2 forms. One form is a blue form(Pfr), which absorbs red light, and the other is a blue-green form(Pr) that absorbs far-red light. Solar energy has 10X more red (660nm) than far-red (730nm) light causing the accumulation of Pfr." The first and last hour of a day's sunlight is mostly red light because of the scattering effect on blue light. "So at the onset of the dark period much of the phytochrome is in the Pfr form. However, Pfr is unstable and returns to phytochrome Pr in the dark." The red light in sunrise returns the Pr to the Pfr form. "Phytochrome Pfr is the active form and controls flowering and germination. It inhibits flowering of short-day plants (the long night period is required for the conversion of Pfr to Pr) and promotes flowering of long day plants."
Kelvin Temperature is an easy key to the efficiency of artificial light to fuel photosynthesis or to affect the phytochrome. The former is fueled very efficiently by 6500K light: this is a Kelvin Temperature the same color as the sky at noon on a clear summer day. Some Mercury Vapor HID bulbs are rated 6500K. Metal Halide HID bulbs are rated 4000K and can be used instead of the mercury vapor with good results. A less expensive alternative to HID lights that will produce the same results on a smaller scale is the GE Daylight ULTRA 40-watt 48" fluorescent tube which is rated 6500K. 160W will deliver the desired effect to eight sq ft (2'x4') if the ballast in the two-lamp holder is a "high power factor" standard size; the smaller, energy-saver ballast provides less luminosity. The fluorescent tubes have to be closer to the plant meristem than the HID bulb. To obtain the desired effect with the fluorescent tubes in an environment that receives no supplemental sunlight, the distance to the plant meristem should not be greater than 2" for seedlings or 6" for transplants in one gallon and larger containers.
hogbud
Well-Known Member
Phytochrome, on the other hand, is very responsive to red and orange wavelengths. Because its light is saturated in these wavelengths, the ordinary household incandescent light bulb (2845K) is used as a cheap and effective way either to delay flowering in short-day plants with night-interruption lighting or to establish an artificial light "flowering photoperiod" using 2845K light of appropriate wattage for the square footage at the start and end of the photoperiod to simulate the red wavelength in sunrise and sunset. A 100W light bulb distanced 2' to 4' from the plants will deliver the desired effect to 16 sq ft (4'x4').
As an example: 8' x 8' garden plot divided into quads. The phytochrome of the plants is manipulated by 100 watts of 2845K light dangling over the center of each quad for a total of 400 watts. Photosynthesis for the entire garden plot is fueled by 1000 watts of 6500K Mercury Vapor light or 1000 watts of 4000K Metal Halide light dangling overhead at the center of the garden plot. To use the potent UVB photons in outdoor sunlight during July and August to fuel the phytochemical process that makes THC, a short-day flowering photoperiod for the indoor garden plot could be established on May 1st for potted marijuana plants that were germinated December 1st of the previous year.
FLOWERING PHOTOPERIOD
SUNRISE: One hour phytochrome (2845K light)
DAYTIME: 10:00 hours photosynthesis (6500K/4000K light)
SUNSET: One hour phytochrome (2845K light)
NIGHTTIME: 12 hours dark
PARTHENOCARPIC PHOTOPERIOD
SUNRISE: One hour phytochrome (2845K light)
DAYTIME: 9:00 hours photosynthesis (6500K/4000K light)
SUNSET: One hour phytochrome (2845K light)
NIGHTTIME: 13 hours dark
The change to a parthenocarpic photoperiod is made around the third week in June after the plants have fully flowered; then, beginning July 7 or so, the potted plants are moved outdoors into full sun from 9am until 4pm. Moving the plants from the indoor parthenocarpic photoperiod to outdoor sunlight takes advantage of the energy of the UVB photons during these months and should be continued for at least 30 days. This is the time necessary for the phytochemical process to make fully realized THC in the majority of the resin spheres. Manipulation of the photoperiod could be used to good effect in the South of England, for example, because it is only possible to get a sunburn there during July and August. This follows the author's naked caucasoid sunburn rule that states: If a naked caucasoid can go outside and get a sunburn, there are enough UVB photons of appropriate intensity to make fully realized THC at that time and place.
d)In Nepal and nearby areas of India where the capitate-stalked glandular trichome is triggered into growth by parthenocarpy rather than by fertilized ovum, great care is taken to make sure that all male marijuana plants are destroyed as soon as they reveal their sex. This is because unfertilized Indica flowering females can have both stigma and anther protruding from the floral bract. In the Indica gene pool, female-produced pollen carries an allele for long-day parthenocarpy, and seeds resulting from this female-produced pollen will produce another generation of female plants that will also exhibit long-day parthenocarpy during flowering. But if pollen from male plants is introduced into this gene pool, the resulting seeds will produce a generation of females that will exhibit short-day parthenocarpy instead. The allele for long-day parthenocarpy in the female-produced pollen is carried into the gene pool by self-pollination and cross-pollination, and perhaps homozygous is used too loosely here to describe the genetic result.
( It appears that the resin sphere acts as a magnifying lens.
As an example: 8' x 8' garden plot divided into quads. The phytochrome of the plants is manipulated by 100 watts of 2845K light dangling over the center of each quad for a total of 400 watts. Photosynthesis for the entire garden plot is fueled by 1000 watts of 6500K Mercury Vapor light or 1000 watts of 4000K Metal Halide light dangling overhead at the center of the garden plot. To use the potent UVB photons in outdoor sunlight during July and August to fuel the phytochemical process that makes THC, a short-day flowering photoperiod for the indoor garden plot could be established on May 1st for potted marijuana plants that were germinated December 1st of the previous year.
FLOWERING PHOTOPERIOD
SUNRISE: One hour phytochrome (2845K light)
DAYTIME: 10:00 hours photosynthesis (6500K/4000K light)
SUNSET: One hour phytochrome (2845K light)
NIGHTTIME: 12 hours dark
PARTHENOCARPIC PHOTOPERIOD
SUNRISE: One hour phytochrome (2845K light)
DAYTIME: 9:00 hours photosynthesis (6500K/4000K light)
SUNSET: One hour phytochrome (2845K light)
NIGHTTIME: 13 hours dark
The change to a parthenocarpic photoperiod is made around the third week in June after the plants have fully flowered; then, beginning July 7 or so, the potted plants are moved outdoors into full sun from 9am until 4pm. Moving the plants from the indoor parthenocarpic photoperiod to outdoor sunlight takes advantage of the energy of the UVB photons during these months and should be continued for at least 30 days. This is the time necessary for the phytochemical process to make fully realized THC in the majority of the resin spheres. Manipulation of the photoperiod could be used to good effect in the South of England, for example, because it is only possible to get a sunburn there during July and August. This follows the author's naked caucasoid sunburn rule that states: If a naked caucasoid can go outside and get a sunburn, there are enough UVB photons of appropriate intensity to make fully realized THC at that time and place.
d)In Nepal and nearby areas of India where the capitate-stalked glandular trichome is triggered into growth by parthenocarpy rather than by fertilized ovum, great care is taken to make sure that all male marijuana plants are destroyed as soon as they reveal their sex. This is because unfertilized Indica flowering females can have both stigma and anther protruding from the floral bract. In the Indica gene pool, female-produced pollen carries an allele for long-day parthenocarpy, and seeds resulting from this female-produced pollen will produce another generation of female plants that will also exhibit long-day parthenocarpy during flowering. But if pollen from male plants is introduced into this gene pool, the resulting seeds will produce a generation of females that will exhibit short-day parthenocarpy instead. The allele for long-day parthenocarpy in the female-produced pollen is carried into the gene pool by self-pollination and cross-pollination, and perhaps homozygous is used too loosely here to describe the genetic result.
( It appears that the resin sphere acts as a magnifying lens.
hogbud
Well-Known Member
A NOTE ABOUT marijuana OPTICS FROM THE AUTHOR: Joe Knuc is a pseudonym. If the paragraph or sentence has quotes around it then somebody with a degree wrote it. Otherwise, the author takes credit for it.
First published December 2002 and revised 2003, the author transferred the marijuana OPTICS copyright in May 2003 to D. Craig Steffens, a medical marijuana patient and activist.
marijuana Optics is available in two formats: PDF and HTML. But you'll have to get them from jknuc's Yahoo Briefcase because this free server does not allow downloads. Send this email message and a link to both file types will be sent to you by return email. The PDF file is compressed into a ZIP file. The HTML file is not.
In California, the San Diego city council recently passed guidelines for the cultivation of medical marijuana inside the city limits. Under these guidelines, only indoor cultivation is permitted. In Humboldt county medical marijuana grown outdoors must be beneath a canopy. These restrictions could be part of a ploy to downgrade the effectiveness of medical marijuana by removing the UVB photon from the light stream. In Canada, for example, the marijuana the government is providing to some patients is grown inside a former copper mine under artificial light. Is it any surprise that the patients' who signed up for the government program are dissatisfied with the government product and want their money back?
The "hide" is the toughest part of medical marijuana cultivation. How to get the UVB photon to the capitate-stalked glandular trichome without the police or the neighbors seeing the plants is a problem every medical marijuana grower faces if he or she is hip to the cannabinoid pathway. Shelter Systems sells a translucent woven ripstop film that transmits a percentage of the UVB radiation. On September 22 at N35Lat, the UVB reading at 11:00am of unfiltered sunlight was 300 microwatts/cm2 at a 1400' elevation. At the same time, the UVB reading inside a structure covered with the translucent woven ripstop film was 140 microwatts/cm2. 140 microwatts/cm2 may not seem like much compared to the 300 microwatts/cm2 contained in the unfiltered sunlight, but when you realize that there are zero UVB photons emitted by HID bulbs and zero UVB photons transmitted by corrugated fiberglass or other traditional greenhouse coverings, 140 microwatts/cm2 is quite a lot.
© May 2003 D. Craig Steffens
First published December 2002 and revised 2003, the author transferred the marijuana OPTICS copyright in May 2003 to D. Craig Steffens, a medical marijuana patient and activist.
marijuana Optics is available in two formats: PDF and HTML. But you'll have to get them from jknuc's Yahoo Briefcase because this free server does not allow downloads. Send this email message and a link to both file types will be sent to you by return email. The PDF file is compressed into a ZIP file. The HTML file is not.
In California, the San Diego city council recently passed guidelines for the cultivation of medical marijuana inside the city limits. Under these guidelines, only indoor cultivation is permitted. In Humboldt county medical marijuana grown outdoors must be beneath a canopy. These restrictions could be part of a ploy to downgrade the effectiveness of medical marijuana by removing the UVB photon from the light stream. In Canada, for example, the marijuana the government is providing to some patients is grown inside a former copper mine under artificial light. Is it any surprise that the patients' who signed up for the government program are dissatisfied with the government product and want their money back?
The "hide" is the toughest part of medical marijuana cultivation. How to get the UVB photon to the capitate-stalked glandular trichome without the police or the neighbors seeing the plants is a problem every medical marijuana grower faces if he or she is hip to the cannabinoid pathway. Shelter Systems sells a translucent woven ripstop film that transmits a percentage of the UVB radiation. On September 22 at N35Lat, the UVB reading at 11:00am of unfiltered sunlight was 300 microwatts/cm2 at a 1400' elevation. At the same time, the UVB reading inside a structure covered with the translucent woven ripstop film was 140 microwatts/cm2. 140 microwatts/cm2 may not seem like much compared to the 300 microwatts/cm2 contained in the unfiltered sunlight, but when you realize that there are zero UVB photons emitted by HID bulbs and zero UVB photons transmitted by corrugated fiberglass or other traditional greenhouse coverings, 140 microwatts/cm2 is quite a lot.
© May 2003 D. Craig Steffens
dannyboy602
Well-Known Member
That was a mouthful. Is there a readers digest version lol?
MightyMike530
Well-Known Member
Glad you're around still hogbud. Have you ever revegged flowering plants? If so, what were your results? The quote below led me to ask this question.
Have done topping, lst, supercropping, along with combinations of the three...I have found that supercropping doesn't produce the bud structure I desire, lst is too much trouble for what if any gain, but topping for 4 mains, a long veg and larger plants is the most productive and by far the simplest and have found it to yield better than au natural. Sog is of no interest as I prefer older plants and grow from seed as I prefer the variety and the "gems". I appreciate the info you shared but am already quite well versed on the hobby and all its variations. After I complete my all fem crossbreeding project my next methodology experiment will be monster cropping or revegging flowering clones as it looks as though it increases production as well as potency. My main goal is always potency and that tends to limit yield tyo a dgree so want to see if it is the best of both worlds.
Namaste'
MightyMike530
Well-Known Member
Hog, could you also elaborate more on the whole light leaks not causing hermies thing. I am growing in a small tent and am dealing with minor heat issues because I have the tent draped in blankets, albeit thin ones, to prevent light from getting into the tent along seams and zippers and also through the open vents. The first plant (currently in my 3rd grow) I grew hermied in a very few locations and I had assumed this was cause by light leaks. Though, I do understand that hermies can also be caused by other stresses as the temps outside the tent were low (near freezing) and the portions that hermied were in direct contact with the tent.
What's happenin' dude.
Always enjoy threads with botanical info and links thrown in, so do your thing dude.
/shrug
Show me some information about farmers breeding "light resistant" strains to combat the expanding "light pollution" that occurred during the last century with automobiles, billboards, streetlights and such, and then I'll be more receptive. However, as it stands now, I think the "light leak = hermi" paranoia is little more than stoner myth caused by bad genetics.
hogbud
Well-Known Member
I have re-vegged dozens of plants, is very easy, hell I've grown Zombies LOL
But Lumi was referring to monster cropping which I love !!! simply take clones at day 21 of flower and once rooted re-veg em it is an awesome technique, I have 8 going right now, the pics of the clone with trics is one of em
hogbud
Well-Known Member
from my nuggets LOL,,,,,
THE marijuana GROWER'S GUIDE
by Mel Frank and Ed Rosenthal
Sexual Variants in Cannabis
Cannabis has been studied for many years because of its unusual sexuality. Besides the normal dioecious pattern, where each plant bears exclusively male or female flowers, it is not uncommon for some plants to have both male and female flowers. These are called hermaphrodites, or monoecious plants, or intersexes. Hermaphroditic plants form normal flowers of both sexes in a wide variety of arrangements, in both random and uniform distributions.
Natural Hermaphrodites
Some hermaphrodites seem to be genetically determined (protogenous). That is, they naturally form flowers of both sexes given normal growing conditions. Possibly genes carried on the autosomes (the chromosomes other than the sex chromosomes) modify the normal sexual expression. Monoecious varieties have been developed by hemp breeders in order to ensure uniform harvests.
It is also possible that these particular are polyploid, which means they have more than the usual two sets of chromosomes. This kind of hermaphrodite may have XXY (triploid), or XXYY or XXXY (tetraploid) sex chromosomes. However, no naturally occurring polyploids have ever been verified (by observation of the chromosomes) in any population of Cannabis. Polyploids have been induced in Cannabis by using mutagens, such as the alkaloid colchicine.
Whatever then genetic explanation may be, one or more of these natural hermaphrodites may randomly appear in any garden. They are sometimes faster-maturing, have larger leaves, and are larger in overall size than their unisexual siblings. They usually form flowers of both sexes uniformly in time and distribution, and in some unusual patterns. For example, from Mexican seed, we have seen a plant on which separate flowering cluster consisted of both female and male flowers: and upper section of female flowers had upraised stigmas, and a lower section of male flowers dangled beneath the female flowers. In other plants from Mexican seed, the growing tips throughout the plant have female flowers; male flowers sprout from the leaf axils along the main stem and branches. Plants from "Thai" seed sometimes form male and female flowers on separate branches. Branches with female flowers tend to predominate, but branches having mostly male flowers are located throughout the plant.
Abnormal Flowers, Intersexes, Reversals
Gender is set in the new plant at the time of fertilisation by its inheritance of either the X or the Y chromosome from the male (staminate) plant. With germination of the seed, the environment comes into play. Heritage sets the genetic program, but the environment can influence how the program runs. (Sexual expression in Cannabis is delicately balanced between the two.) The photoperiod, for example, controls the plant's sequence of development. Also, the plant's metabolism and life processes are dependent on growing conditions. When the environment does not allow a balance to be maintained, the normal genetic program may not be followed. This is mirrored by abnormal growth or sexual expression.
{Figure 78. Upper left: Abnormal flowers. Lower left: Male flowers on afemale plant. Upper right: Sexes on separate branches. Lower right: Maleflower in female bud (reversing).}Abnormal Flowers
Abnormal sexual expression includes a whole range of possibilities. Individual flowers may form abnormally, and may contain varying degrees of both male and female flower parts. For instance, a male flower may bear a stigma; or an anther may protrude from the bracts of a female flower. Abnormally formed flowers are not often seen on healthy plants, although if one looks hard enough, a few may be found in most crops. When many of the flowers are abnormal, an improper photoperiod (coupled with poor health) is the most likely cause. Abnormal flowers sometimes form on marijuana grown out of season, such as with winter or spring crops grown under natural light.
Intersexes and Reversals Much more common than abnormally formed flowers is for the plant's sex to be confused. One may find an isolated male flower or two; or there may be many clusters of male flowers on an otherwise female plant, or vice versa. These plants are called intersexes (also hermaphrodites or monoecious plants). Intersexes due to environment causes differ from natural hermaphrodite in having random distributions and proportions of male and female flowers. In more extreme cases, a plant may completely reverse sex. For example, a female may flowers normally for several weeks, then put forth new, sparse growth, typical of the male, on which male flowers develop. The complete reversal from male flowering to female flowering also happens.
All other things being equal, the potency of intersexes and reversed plants is usually less than that of normal plants. If there are reversals or intersexes, both of the sexes will usually be affected. Female plants that reverse to male flowering show the biggest decline. Not only is the grass less potent, but the amount of marijuana harvested from male flowers is negligible compared to the amount of marijuana that can be harvested from a normal female. Plants that change from male to female flowering usually increase their potency, because of the growth of female flower bracts with their higher concentration of resin. Female flowers on male plants seldom form as thickly or vigorously as on a normal female. Between the loss in potency and the loss in yield because of females changing to males, a crop from such plants is usually inferior, in both yield and potency, to one from normal plants.
hogbud
Well-Known Member
con't,,,,,
Environmental Effects
Many environmental factors can cause intersexes and sexual reversals. These include photoperiod, low light intensity, applications of ultraviolet light, low temperatures, mutilation or severe pruning, nutrient imbalances or deficiencies, senescence (old age), and applications of various chemicals (see bibliography on sex determination).
The photoperiod (or time of planting using natural light) is the most important factor to consider for normal flowering. In 1931, J. Schaffner (105) showed that the percentage of hemp plants that had confused sexual characteristics depended on the time of year they were planted. Normal flowering (less than five percent of the plants are intersexes) occurred when the seeds were sown in May, June, or July, the months when the photoperiod is longest and light intensity is strongest. When planted sooner or later in the year, the percentage of intersexuals increased steadily, until about 90 percent of the plants were intersexual when planted during November or early December.
marijuana plants need more time to develop than hemp plants at latitudes in the United States. Considering potency, size, and normal flowering, the best time to sow for the summer crop is during the month of April. Farmers in the south could start the plants as late as June and still expect fully developed plants.
If artificial light is used, the length of the photoperiod can influence sexual expression. Normal flowering, with about equal numbers of male and female plants, seems to occur when the photoperiod is from 15 to 17 hours of light for a period of three to five months. The photoperiod is then shortened to 12 hours to induce flowering. With longer photoperiods, from 18 to 24 hours a day, the ratio of males to females changes, depending on whether flowering is induced earlier or later in the plant's life. When the plants are grown with long photoperiods for six months or more, usually there are at least 10 percent more male then female plants. When flowering is induced within three months of age, more females develop. Actually, the "extra" males or females are reversed plants, but the reversals occur before the plants flower in their natural genders.
Some plants will flower normally without a cutting of the photoperiod. But more often, females will not form thick buds unless the light cycle is cut to a period of 12 hours duration. Don't make the light cycle any shorter than 12 hours, unless the females have not shown flowers after three weeks of 12-hour days. Then cut the light cycle to 11 hours. Flowers should appear in about one week.
Anytime the light cycle is cut to less than 11 hours, some intersexes or reversed plant usually develop. This fact leads to a procedure for increasing the numbers of female flowers indoors. The crops can be grown for three months under a long photoperiod (18 or more hours of light). The light cycle is then cut to 10 hours. Although the harvest is young (about five months) there will be many more female flower buds than with normal flowering. More plants will develop female flowers initially, and male plants usually reverse to females after a few weeks of flowering.
Of the other environmental factors that can affect sexual expression in Cannabis, none are as predictable as the photoperiod. Factors such as nutrients or pruning affect the plant's overall health and metabolism, and can be dealt with by two general thoughts. First, good growing conditions lead to healthy plants and normal flowering: female and male plants occur in about equal numbers, with few (if any) intersexes or reversed plants. Poor growing conditions lead to reduced health and vigour, and oftentimes to confused sex in the adult plant. Second, the age of the plants seems to influence reversals. Male plants often show female flowers when the plant is young (vigorous) during flowering. Females seven or more months old (weaker) often develop male flowers after flowering normally for a few weeks.
Anytime the plant's normal growth pattern is disrupted, normal flowering may be affected. For instance, plant propagated from cuttings sometimes reverse sex, as do those grown for more than one season.
the whole book can be read here,
http://www.marijuanagirls.com/Mariju...GrowGuide.html
Environmental Effects
Many environmental factors can cause intersexes and sexual reversals. These include photoperiod, low light intensity, applications of ultraviolet light, low temperatures, mutilation or severe pruning, nutrient imbalances or deficiencies, senescence (old age), and applications of various chemicals (see bibliography on sex determination).
The photoperiod (or time of planting using natural light) is the most important factor to consider for normal flowering. In 1931, J. Schaffner (105) showed that the percentage of hemp plants that had confused sexual characteristics depended on the time of year they were planted. Normal flowering (less than five percent of the plants are intersexes) occurred when the seeds were sown in May, June, or July, the months when the photoperiod is longest and light intensity is strongest. When planted sooner or later in the year, the percentage of intersexuals increased steadily, until about 90 percent of the plants were intersexual when planted during November or early December.
marijuana plants need more time to develop than hemp plants at latitudes in the United States. Considering potency, size, and normal flowering, the best time to sow for the summer crop is during the month of April. Farmers in the south could start the plants as late as June and still expect fully developed plants.
If artificial light is used, the length of the photoperiod can influence sexual expression. Normal flowering, with about equal numbers of male and female plants, seems to occur when the photoperiod is from 15 to 17 hours of light for a period of three to five months. The photoperiod is then shortened to 12 hours to induce flowering. With longer photoperiods, from 18 to 24 hours a day, the ratio of males to females changes, depending on whether flowering is induced earlier or later in the plant's life. When the plants are grown with long photoperiods for six months or more, usually there are at least 10 percent more male then female plants. When flowering is induced within three months of age, more females develop. Actually, the "extra" males or females are reversed plants, but the reversals occur before the plants flower in their natural genders.
Some plants will flower normally without a cutting of the photoperiod. But more often, females will not form thick buds unless the light cycle is cut to a period of 12 hours duration. Don't make the light cycle any shorter than 12 hours, unless the females have not shown flowers after three weeks of 12-hour days. Then cut the light cycle to 11 hours. Flowers should appear in about one week.
Anytime the light cycle is cut to less than 11 hours, some intersexes or reversed plant usually develop. This fact leads to a procedure for increasing the numbers of female flowers indoors. The crops can be grown for three months under a long photoperiod (18 or more hours of light). The light cycle is then cut to 10 hours. Although the harvest is young (about five months) there will be many more female flower buds than with normal flowering. More plants will develop female flowers initially, and male plants usually reverse to females after a few weeks of flowering.
Of the other environmental factors that can affect sexual expression in Cannabis, none are as predictable as the photoperiod. Factors such as nutrients or pruning affect the plant's overall health and metabolism, and can be dealt with by two general thoughts. First, good growing conditions lead to healthy plants and normal flowering: female and male plants occur in about equal numbers, with few (if any) intersexes or reversed plants. Poor growing conditions lead to reduced health and vigour, and oftentimes to confused sex in the adult plant. Second, the age of the plants seems to influence reversals. Male plants often show female flowers when the plant is young (vigorous) during flowering. Females seven or more months old (weaker) often develop male flowers after flowering normally for a few weeks.
Anytime the plant's normal growth pattern is disrupted, normal flowering may be affected. For instance, plant propagated from cuttings sometimes reverse sex, as do those grown for more than one season.
the whole book can be read here,
http://www.marijuanagirls.com/Mariju...GrowGuide.html
Screaming trees
Well-Known Member
What's the latest you could clones from a flowering any? And once you cloned what hours of light, temp and humidity would have to be set in place? Thanks in advance.
Cheers
Screaming trees
Well-Known Member
Thanks! Loving your post.
- Status