12/1
Fewer hours of lighting are required if the dark period is interrupted in the middle of the night,. The light break in the middle of the night restores pfr phytochrome level. Since neither of the two dark periods before or after light break is very long, the pfr level does not diminish sufficiently to permit flowering. 12-1 plants stay in vegetative state, and grow bigger and better with tight nodes.
8 hour finnish
Since the dawn of time, farmers have understood the role of light in plant growth; it wasn’t until the beginning of the twentieth century that we began to understand the importance of darkness. In 1913, the French graduate student Julien Tournois discovered that hops and hemp grown under glass would flower precociously in winter. He also observed that the plants would flower most rapidly when allowed only eight hours of daylight.
Tournois’s research ended when he died on the front during World War I, but a few years later two American scientists, Wrightman Garner and Harry Allard, unwittingly expanded upon Tournois’ findings.
Wrightman and Allard discovered that certain plants bud more readily when they sense a change in seasons, or rather: Certain plants will begin to bud when they sense a change in the ratio of daylight hours to nighttime hours.
Garner and Allard immediately saw the implications for agriculture. They began experimenting on a range of plant species and discovered that day length influences many aspects of plant activity, including dormancy, flowering, and potential yield[2].
In 1920 they noted: “under the influence of a suitable length of day, precocious flowering and fruiting may be induced[3].”
Garner and Allard invented a word to describe a plant’s sensitivity to day length: Photoperiodism. Photoperiodism is a biological response to a shift in the proportions of light and dark in a 24-hour cycle.
Photoperiodic plants measure hours of darkness in order to keep track of the seasons and thus flower at an appropriate time of year. The two scientists began classifying plants as long-day plants (LDP), day-neutral plants (DNP), and short-day plants (SDP). Day-neutral plants can flower at any time of year, depending on other conditions.
Long-day plants flower naturally in high summer, when the nights are shortest.
Short-day plants flower naturally when the nights are long: either in early spring or in late summer and early autumn.
Short-day species include chrysanthemums, poinsettias, cosmos, globe amaranth, rice, hyacinth bean, and some varieties of marigold, orchid, and strawberry; as well as and a number of other high-value specialty crops.
Short-day is actually something of a misnomer: short-day plants sense darkness, not light.
When sensors in your plant’s leaves indicate that each 24-hour cycle includes 12 or more hours of sustained, uninterrupted darkness, your plant’s apical meristems (growing tips) will shift priorities: instead of producing more leaves and stems, the plant will begin to produce floral structure.
In Photoperiodism in Plants, Thomas and Vince-Prue expand upon the concept: ”Perhaps the most useful proposal is that of Hillman (1969), who defined photoperiodism as a response to the timing of light and darkness. Implicit in this definition is that total light energy, above a threshold level, is relatively unimportant, as is the relative lengths of the light and dark period. What is important is the timing of the light and dark periods, or, to think of it another way, the times at which the transition between light and dark take place.”
Biologist P.J. Lumsden also emphasized the importance of precise timing, noting: “…photoperiodic responses require a time-measuring mechanism, to which is closely coupled a photo perception system. Further, the time-keeping mechanism must operate very precisely and it must be insensitive to unpredictable variations in the environment.”
In other words: absolute darkness is not necessary to trigger a photoperiodic response in SDP, but consistency of dark-to-light ratios is essential.
During a 1938 experiment on the effects of light on xanthium, Karl Hamner and James Bonner discovered that the benefits of a long night could be reduced or abolished if the darkness was interrupted for even a few minutes[4].
The converse was not true: the flowering process was not reversed when the daylight hours were interrupted with darkness. Growers of SDP crops have been using light deprivation research to their advantage for decades. For example, poinsettia farmers use automated greenhouses to ensure that plants bloom for the Christmas season.
More recently, light deprivation technology has caught on in other specialty gardening industries. Light deprivation is an ideal method for farmers who want to bring a crop to market before the market floods during the harvest season. The method also allows farmers to avoid potential rain damage by harvesting when weather conditions are ideal. Perhaps more importantly, light deprivation offers the opportunity to plant and harvest twice during one growing season and thereby double annual yield.
To utilize light dep, farmers plant crops in hoop houses or greenhouses, which are covered with opaque material for a period of time each morning or evening. The goal is to block sunlight and increase the number of hours the crop spends in darkness: more than 12 hours of darkness will stimulate flower growth in most SDP plants.
The challenge is to keep the schedule consistent and to ensure that the darkness is not interrupted, either by unseen rips in the covering, shifts in the covering caused by wind, or human error.
As Hamner and Bonner demonstrated, interruptions or inconsistencies in the light deprivation cycle can confuse the plant and slow flower growth.
Why does 8 on 16 off work so well?
Cannabis can only uptake 8 hours of light energy for photosynthesis, its tanks are full.
When you give it more light energy, the plant goes into photosynthesis protection, which use up energy and shuts down CO2 intake.
So now you are using the energy received to its utmost potential, no energy wasted, no CO2 shutdown, the plant now has 16 hours to grow fatter buds and produce more resin than ever before. 8 on 16 off in flower is the game changer.
All they ever taught you was to spend thousands to make hundreds. 12-1 8-16 is direct aid to all growers. F%#k the status quo.
These methods claim to save 75% on lighting costs and a 30 to 40% more production and cut flowering time ny 25%
If I had the space i would love to experiment with this method.
