7 horas de sol, Floranova Grow y Armour Si de GH, agua de grifo. Le sentó bien el corte ápical. Le podé el piso inferior, tal vez hice apical tarde. Apliqué LST.

Got better at week 8 end. Finally lots of trichomes, buds are gettin denser last couple days. Made a couple of pure water waterings between nutrition. Defoliated hard and seems like this is last time before harvest. Please share any thoughts/tips on better growing this baby👇 Peace🙏

These ladies are starting to turn hairy and frosty real quick. Can't walk by tent without the sweet smell hitting my nose. They are also getting more thirsty by the day, had to top up my water reservoir after 6 days this week. So that's good news as it means their roots are very well established and they are just soaking up everything they need. The two plants on the right side looks like it went into a bit of re-vegging for some sorts as it just kept on shooting upwards but it seems it's finally slowing down.

The focus is just on the red phenos. Although the green version smoke and smell great too. It was the Reds For me.

Ultima semana de la etapa vegetativa, próxima semana empieza fotoperiodo 12/12 me impresiona la asimilación de nutrientes de la G13 que no muestra ninguna deficiencia y gran frondosidad, se hace destacar entre estas sativas una planta sumamente vigorosa con un crecimiento increíble tiene bien puesto su nombre. High Level 😍

Find out that the plants are male and female. Balls right under the female butts. So, it's easy to get rid of the male parts haha

Culminando semana 3, este es mi segundo cultivo, creo que se ven mejor que mi primer cultivo.

Really happy with how things are looking, despite expecting slightly larger buds. I think next time, I'll defoliate and lollipop a bit more to focus the plants energy on the main tops. It stinks like mint, skunk, and sweet. Really nice trichome coverage, lots of dank buds in the mix here. Even the lowers that aren't getting as much light are looking dank. I started the week out around 500ppm and steadily dropped to below 400ppm. The ppms kept creeping up every time I'd drop them...so I kept dropping them to see where it would stabilize. I ended the week at 381ppm. In preparations for harvest, I'll plan to steadily reduce the ppm to about 200ppm, rather than doing a flush with RO. I'm working with really great starting water between 50-80ppm, which absolutely requires CalMag at .5 to .75 tsp/g.

End of Week 12 (Fifth week of flower) The ladies are smelling reDANKulous and are so frosty and sticky I can't remove fan leaves without getting my hands sticky. Next level terpene profiles. I did a final increase in CO2 to 1500ppm. The main top-sites are taking shape. I have been keeping a cooler average temperature - and also keeping the relative humidity lower. Pest Report: None

Week 5 day 1. I have a favourite for next run. I’m very happy, I haven’t really defoliated at all this grow, just letting it grow. Wish I was going for mains(topping) but still very good. Going to wait around week 9 so seeds will be good for next run. I have decided to do very hard hst next round to show max potential. Very happy with supercropping so will do it very heavy with scrog. I will try to reveg the one I really like but it is difficult having only 1 set of lights and 1 tent. Plants are about 7ft tall, might just run 2 next round in 4x8 or will still continue to go 4 in the 4x8.

Week went again very uneventful, she is not very hungry anymore and had to constantly refill the reservoir with water to keep the ec in check. Trichomes are all cloudy and start to turn amber. She has developed that amazing purple hue and is sticky to the max, so definitely showing her glue heritable ;) I will continue to feed her until Wednesday this week and then start the flushing and darkness. Harvest will be next week end.

Il fumo è leggero e buono ma piuttosto blando se si parla di densità e sapori. Del resto cime dure come la roccia e molto resinose. Aggiornamento: dopo più di un mese di concia le cime hanno una consistenza veramente cremosa. Il fumo è terroso, liscio all'espirazione ma dopo lascia una senso di affanno dovuto alla sua pesantezza. Per gli intenditori molto buono.

Start of week 4 of flower! Off to a troubling start, as the light switched on over 1 hour ealiere than scheduled. I took a spare timer, and set it up to continue it's 12/12 schedule, but now moved one hour back. I cross my fingers they forgive me for this error.🙏 👽👉31/10 The day after watering and the day my timer messed up my 12/12 schedule. But hope it brings no problems. I defoliated lightly and only removed most under the SCROG line. Even a couple of underdevoloped branches that stretched below SCROG-net got cut. 👽👉 1/11 Been having a battle with humidity after watering, but upped my air circulation to help. 👽👉 2/11 Waterday* Upped my nutes on BioHeaven, BioGrow and BioBloom. 👽👉 3/11 They seem to be responding good to the upped nutrients. 👽👉 4/11 Humidity under control. 👽👉 5/11 The VPD on point, has really speed up the trichome production. 👽👉 6/11 Waterday* Stayed on the same schedule, as last watering. They seem very satisfied and no signs of mistreatment.

Two phenotypes - one purple and one white/green. The purple was very difficult to train and resulted in a couple inadvertent breaks - luckily it was repairable. The other trained very well, very flexible and worked very good for SCROG. Both produced heavily and are beautiful. The purple tends to be much more fluffy, with very long pistil hairs - the longest of any grow I have done. The white was super dense, very crystally and sticky. It will be very interesting to see how they smoke. Also, the purple tended to do very well with some nute mistakes I made as well as fluctuating pH in my water feeding. The white did not do as well in this regard but was able to get to harvest fine. Wet bud weight is prior to trimming. The buds off of these plants were HUGE!!!! Plant #1: (Purple): Wet weight - 76.58oz prior to trim; 15 colas; Terps: White - 60%, Clear - 20%, Amber - 20% Plant #2: (White): Wet weight - 71.65oz prior to trim; 16 colas; Terps: White - 70%, Clear - 30%, After 3 days of drying, took them down to trim for my jars. After a few hours filled mostly quart jars 3/4 full but also tried an Infinity jar and a gallon mason jar to minimize the number of smaller jars. Dry weights into jars: Plant #1: 14.79 oz Plant #2: 11.76oz I did pull them after a day to dry rack them for 12 hours due to a little bit higher moisture content then I would have liked ( 70%rH). Re-jarred on 6/1/23 and now holding steady at around 60% rH. Cure Check In (Week 2): 6/10 - 6/12/23: rH ~ 63 - 66%. Daily air exposure & fanning. Very smelly. Looking good - another couple weeks and will be ready.

Buenos humos jardineros💚💚💚💚 Aquí os traigo la acualizacion de estas gigantes q no paran de crecer!! Tened esto en cuenta a la hora de plantarlas en interior, a mi me está dando la lata totalmente, jajajaj Pero bueno, q todos los dramas sean esos, que las plantas crezcan mucho! Para la semana más! Pensad en verde😘😘😘😘😘🌱💚

Plant streached out a bit more this week not sure if it is over yet. Flower is coming along and the buds are starting to form. Now the fun part starts. I'm sure everyone loves the flower phase. Did a defoliation, seemed to work the first time so I will keep doing it. Took two of the three plants an put them in a tent. There is no space in the flower room and did not want to compromise the grow. I guess I was a little over anxious and poped these seeds a bit early. No big deal, a tent is always good. It will be interesting to see the difference between the two areas flowering. This will come down to cheap led fixture vs 1100 true watts of the timber grow vero 29 3000k cobbs. Fornthe cheap led fixtures I have 2- 1600 watt, a 1000 watt and a 600 watt. Ok this is the advertised watts and not true watts. I don't know the true watts either. I have to say they seem to work great for veg and thats what I used them for until I ran out of room. I am hoping the reflective tent will help. Any comments or tips are greatly appreciated. Happy growing. Cheers!

Just germinated the 3 OG Kush seeds, only one had a tap root. Decided to soak my White Widow just in case only one OG plant makes it. 6 plants in total (if the other 2 OG makes it)

( RUNTZ X F1DURB X GUSHERS )🍬🌈🍨🍧 PURP KICKIN INN END #WEEK4 CANT WAIT TILL THE BUDS SWELL UPP!! SUPA INTENSE CANDY TERPS THIS ROUND NOT BIG BUDS BUT SUPA HIGH IN BRIXX LEVEL WITH ALL THE ORGANIC CARBON INPUTS!! PPM 900/1200 1.2 max (Face Off OG x Watermelon Zkittlez) X (Runtz x F1 Durb x Gushers) 🍉🍬🌈🍧🍨🍦 LIL PRUPLE TINT WIT MOUTH WATERING SUGARY TERPS KICK INN END #WEEK4 BY WEEK 7/8 SHE WILL BE PURPLE PURPLE WIT SUPER INTENSE CANDY MOUTH WATERING TERPS CANT WAIT TILL SEE THEM BUDS SWELL UPP!! PHENO A/B NOT BIG BUDS BUT SUPA HIGH IN BRIXX LEVEL WITH ALL THE ORGANIC CARBON INPUTS!! PPM 900/1200 1.2 max

Green light is radiation with wavelengths between 520 and 560 nm and it affects photosynthesis, plant height, and flowering. Plants reflect green light and this is why they appear green to our eyes. As a result, some growers think that plants don’t use green wavelengths, but they actually do! In fact, only around 5 – 10% of green light is reflected from leaves and the rest (90 – 95 %) is absorbed or transmitted to lower leaves [1]. Green wavelengths get used in photosynthesis. Chlorophyll pigments absorb small amounts of green wavelengths. Light that doesn’t get absorbed is transmitted to leaves that are shaded out from direct light. This means that leaves at the bottom of the canopy get more green light than leaves at the top. A high proportion of green wavelengths compared to other colors tells lower leaves that they are being shaded out, so they are able to react accordingly. Lower leaves may react by opening or closing their stomata or growing longer stems that help the leaves reach brighter light [1, 2, 3]. When it comes to growing cannabis, many cultivators are interested in the quality of light used for the flowering stage. In many plants, flowering is regulated by two main photoreceptors: cryptochrome and phytochrome. Both photoreceptors primarily respond to blue light but can also respond to green, although to a lesser extent. Green can accelerate the start of flowering in several species (although cannabis has yet to be tested) [1, 4, 5]. However, once flowering has begun, it’s important to provide plants with a “full spectrum” light that has high amounts of blue and red light, and moderate amounts of green, in order for photosynthesis to be optimized. Green light mediates seed germination in some species. Seeds use green wavelengths to decide whether the environment is good for germination. Shade environments are enriched in green relative to red and blue light, so a plant can tell if it is shady or sunny. A seed that senses a shaded environment may stay dormant to avoid poor growing conditions [1]. Some examples of plant species where researchers have documented this response are: ryegrass (a grass that grows in tufts) and Chondrilla (a plant related to dandelion) [1, 6]. Although green wavelengths generally tell plants NOT to germinate, there are some exceptions! Surprisingly, green wavelengths can stimulate seed germination in some species like Aeschynomene, Tephrosia, Solidago, Cyrtopodium, and Atriplex [1, 6, 7]. Of course, light is not the only factor affecting seed germination – it’s a combination of many factors, such as soil moisture, soil type, temperature, photoperiod, and light quality. When combined with red and blue light, green can really enhance plant growth [1, 8]. However, too much green light (more than 50% of the total light) can actually reduce plant growth [8]. Based on the most current research, the ideal ratio of green, red, and blue light is thought to be around 1:2:1 for green:blue:red [9]. When choosing a horticultural light, choose one that has high amounts of blue and red light and moderate amounts of green and other colors of light. Not many studies can be found about the effect of green light on cannabis growth or metabolism. However, if one reads carefully, there are clues and data available even from the very early papers. Mahlberg and Hemphill (1983) used colored filters in their study to alter the sunlight spectrum and study green light among others. They concluded that the green filter, which makes the environment green by cutting other wavelengths out, reduced the THC concentration significantly compared to the daylight control treatment. It has been demonstrated that green color can reduce secondary metabolite activity with other species as well. For example, the addition of green to a light spectrum decreases anthocyanin concentration in lettuce (Zhang and Folta 2012). If green light only reverses the biosynthesis of some secondary metabolites, then why put green light into a growth spectrum at all? Well, there are a couple of good reasons. One is that green penetrates leaf layers effectively. Conversely red and blue light is almost completely absorbed by the first leaf layer. Green travels through the first, second, and even third layers effectively (Figure 2). Lower leaf layers can utilize green light in photosynthesis and therefore produce yields as well. Even though a green light-specific photoreceptor has not yet been found, it is known that green light has effects independent from the cryptochrome but then again, also cryptochrome-dependent ones, just like blue light. It is known that green light in low light intensity conditions can enhance far red stimulating secondary metabolite production in microgreens and then again, counteracts the production of these compounds in high-intensity light conditions (Kim et al. 2004). In many cases, green light promoted physiological changes in plants that are opposite to the actions of blue light. In the study by Kim et al. blue light-induced anthocyanin accumulation was inhibited by green light. In another study it has been found that blue light promotes stomatal opening whereas green light promotes stomatal closure (Frechilla et al. 2000). Blue light inhibits the early stem elongation in the seedling stage whereas green light promotes it (Folta 2004). Also, blue light results in flowering induction, and green light inhibits it (Banerjee et al., 2007). As you can see, green light works very closely with blue light, and therefore not only the amount of these two wavelengths separately is important but also the ratio (Blue: Green) between these two in the designed spectrum. Furthermore, green light has been found to affect the elongation of petioles and upward leaf reorientation with the model plant Arabidopsis thaliana both of which are a sign of shade avoidance symptoms (Zhang et al. 2011) and also gene expression in the same plant (Dhingra et al. 2006). As mentioned before, green light produces shade avoidance symptoms which are quite intuitive if you consider the natural conditions where the plants grow. Not all the green light is reflected from the highest canopy leaves in nature but a lot of it (50-90%) has been estimated to penetrate the upper leaves at the plant level ((Terashima et al., 2009; Nishio, 2000). For the plant growing in the understory of the forest green light is a signal for the plant of being in the shade of a bigger plant. Then again, the plants growing under unobstructed sunlight can take advantage of the green photons that can more easily penetrate the upper leaves than the red and blue photons. From the photosynthetic pigments in higher plants, chlorophyll is crucial for plant growth. Dissolved chlorophyll and absorb maximally in the red (λ600–700 nm) and blue (λ400–500 nm) regions of the spectrum and not as easily in the green (λ500–600 nm) regions. Up to 80% of all green light is thought to be transmitted through the chloroplast (Terashima et al., 2009) and this allows more green photons to pass deeper into the leaf mesophyll layer than red and blue photons. When the green light is scattered in the vertical leaf profile its journey is lengthened and therefore photons have a higher chance of hitting and being absorbed by chloroplasts on their passage through the leaf to the lower leaves of the plant. Photons of PPFD (photosynthetic photon flux density) are captured by chlorophyll causing an excitation of an electron to enter a higher energy state in which the energy is immediately passed on to the neighboring chlorophyll molecule by resonance transfer or released to the electron transport chain (PSII and PSI). Despite the low extinction coefficient of chlorophyll in the green 500–600 nm region it needs to be noted that the absorbance can be significant if the pigment (chlorophyll) concentration in the leaf is high enough. The research available clearly shows that plants use green wavelengths to promote higher biomass and yield (photosynthetic activity), and that it is a crucial signal for long-term developmental and short-term dynamic acclimation (Blue:Green ratio) to the environment. It should not be dismissed but studied more because it brings more opportunities to control plant gene expression and physiology in plant production. REFERENCES Banerjee R., Schleicher E., Meier S. Viana R. M., Pokorny R., Ahmad M., Bittl R., Batschauer. 2007. The signaling state of Arabidopsis cryptochrome 2 contains flavin semiquinone. The Journal of Biological Chemistry 282, 14916–14922. Dhingra, A., Bies, D. H., Lehner, K. R., and Folta, K. M. 2006. Green light adjusts the plastic transcriptome during early photomorphogenic development. Plant Physiol. 142, 1256-1266. Folta, K. M. 2004. Green light stimulates early stem elongation, antagonizing light-mediated growth inhibition. Plant Physiol. 135, 1407-1416. Frechilla, S., Talbott, L. D., Bogomolmi, R. A., and Zeiger, E. 2000. Reversal of blue light -stimulated stomatal opening by green light. Plant Cell Physiol. 41, 171-176. Kim, H.H., Goins, G. D., Wheeler, R. M., and Sager, J. C. 2004.Green-light supplementation for enhanced lettuce growth under red- and blue-light emitting diodes. HortScience 39, 1617-1622. Nishio, J.N. 2000. Why are higher plants green? Evolution of the higher plant photosynthetic pigment complement. Plant Cell and Environment 23, 539–548. Terashima I., Fujita T., Inoue T., Chow W.S., Oguchi R. 2009. Green light drives leaf photosynthesis more efficiently than red light in strong white light: revisiting the enigmatic question of why leaves are green. Plant & Cell Physiology 50, 684–697. Zhang, T., Maruhnich, S. A., and Folta, K. M. 2011. Green light induces shade avoidance symptoms. Plant Physiol. 157, 1528-156. Wang, Y. & Folta, K. M. Contributions of green light to plant growth and development. Am. J. Bot. 100, 70–78 (2013). Zhang, T. & Folta, K. M. Green light signaling and adaptive response. Plant Signal. Behav. 7, 75–78 (2012). Johkan, M. et al. Blue light-emitting diode light irradiation of seedlings improves seedling quality and growth after transplanting in red leaf lettuce. HortScience 45, 1809–1814 (2010). Kasajima, S., et al. Effect of Light Quality on Developmental Rate of Wheat under Continuous Light at a Constant Temperature. Plant Prod. Sci. 10, 286–291 (2007). Banerjee, R. et al. The signaling state of Arabidopsis cryptochrome 2 contains flavin semiquinone. J. Biol. Chem. 282, 14916–14922 (2007). Goggin, D. E. & Steadman, K. J. Blue and green are frequently seen: responses of seeds to short- and mid-wavelength light. Seed Sci. Res. 22, 27–35 (2012). Mandák, B. & Pyšek, P. The effects of light quality, nitrate concentration and presence of bracteoles on germination of different fruit types in the heterocarpous Atriplex sagittata. J. Ecol. 89, 149–158 (2001). Darko, E. et al. Photosynthesis under artificial light: the shift in primary and secondary metabolism. Philos. Trans. R. Soc. B Biol. Sci. 369 (2014). Lu, N. et al. Effects of Supplemental Lighting with Light-Emitting Diodes (LEDs) on Tomato Yield and Quality of Single-Truss Tomato Plants Grown at High Planting Density. Environ. Control Biol. 50, 63–74 (2012).