Easy ...
-Computers are everywhere .Literally speaking.
-I'm kinda in "tight" economic situations.Not many "exits " ....
-There's no girlfriend around ..(at least for time being ) ...
-I "smoke" a lot..
..
And plenty more
Anyway, my best veg results have come from 2 pure blue T5 lamps mixed with 2 pure blue red lamps. The plants stay extremely short and extremely healthy. I get much better growth under this heavy blue mixture than I do from a 1000w Hortilux blue MH. The main stem is has already turned completely woody after only 2 weeks from seed. They have around 20 nodes stacked in only 12in of height.
Approx the same , is easily doable with less than 10% at blue range ,with leds ....
I know you can grow with HPS because that's all I used at one time full cycle for hydro growing. Now that I've been using the blue/red t5s I will never go back to HPS for vegging.
One major fail a MH light has is the amount of green light present especially the 1000w Hortilux blue. The green peak in the lamp dominates the spectrum and accounts for nearly 30% of the overall light power.
Green light is good at signaling plants and telling them when to stop growing.
...A link ?
I totally disaggree on that ....
You mentioned that you think it's blue light that's responsible for slowed growth in winter, but it's actually the amount of green light present relative to the rest of the spectrum.
At winter ?
Green light at winter ?
An over abundance of red light will also stunt plants. An over abundance of blue light will not on the other hand. I'm talking 460nm and lower.
An
over abundance of blue light
460nm and lower will fry the plants .Period .
Simple Physics and Plant Biology .
From ~280 nm up to ~400 nm overall power density of sunlight (noon,tropics ) is ~
5 Watts per square meter .
When the power of 400-700 nm range is
~400 Watts (~2000 umol/sec ) .
Blue light along with UV is known to boost flavonoids, etc. It's the essence of the plant world.
Agreed .Through plant's defence (photo-protection) mechanisms ....
Anti-oxidants ,waxes,resins ,etc ....
Plants trying to protect themselves from UV radiation .Affects greatly yields and plant mass .
Great example ,sun grown tomatoes -tasty,delicious,red but small sized - and green house (no uv ) grown tomatoes ...
Great taste of nothing ,no aroma but huge ...Pumped up tomatoes ...Plants didn't have anything (uv ) to protect from ....
But ....A lot remains unknown about effects of UV at plants ....
Little we know ....
For bloom I like to use white light, but only for the blue, 565nm and >590nm.
The amount of green and yellow light needed by plants is almost nil.
Based on what ?
Hard claim ....
Proofs ,please ....
I say the opposite ....
(*And along with me ,almost every plant biologist .... )
Quantum efficiency is based on the overall amount of photons delivered, not on how much is used or absorbed by plants.
??????
Don't bother ....
The Quantum yield (quantum efficiency) is variously and rather confusingly defined for photosynthesis
as:
• “
The number of photochemical products” [such as moles of CO2 assimilated or O2 evolved] divided by
the
“Total number of quanta absorbed”, or
• “The fraction of excited molecules” [i.e., excited by the
absorption of a photon] that decay via a
designated pathway [such as via photochemistry, apparently no matter how small the effect produced
per quantum] , or
• The number of times that a defined event occurs
per photon absorbed by the system.
So even though the RQE is higher for green light does not mean the plant still uses 98% of the light like it does with blue/red light.
Anyway, some food for thought.
Green window :
Leaves Absorb all light from ~350 nm up to ~750 nm .Period .Science says so .
Green/cyan range is reflected more from red or blue ,at about ~4% up to 10%.
This detrimental difference allows for the " green window ".
Older leaves or lower leaves or leaves deep in a thick canopy ,receive the green "leftovers " from the rest of the canopy .
They do photosynthesize with those cyan-green-yellow photons ,at ~85 % average efficiency ....
..........
Meaning
The number of photochemical products : set to 100 ....
“Total number of quanta absorbed = 100 / 0.85 = 117.64 green photons
For 100 glucose (example) molecules 117.64 green photons are needed .....
Efficiency of blue at ~430 ..0.76 ..
For 100 glucose molecules 100/ 0.76 =131.57 blue 430 nm photons are needed ......
The plant needs less green photons than blue ones to produce same amount of energy/mass ...
Green window ....
Once more (it became my favourite ....) :
http://www.heliospectra.com/sites/www.heliospectra.com/files/field_page_attachments/what_light_do_plants_need_2012-10-05.pdf
fr or the same thing will occur.