I've raised light to 30" with a ppfd of 180. Still just watering every couple days. Know I need to increase temp. Sitting at around 20.5°C. Want that above 23/24°C right!? **Edit** 1. Bought a heater for tent. 3/11. 2. Light lowered to 24", increased to 40% = tent centre now at 400ppfd

Seeds were pre soaked for 20 hours, grow media was warming in dome overnite with heat pad.. i just planted the seeds at 12:00 pm today , so hopefully fast germination with the dome and heat pad. Ok update.. 1.5 days later 2 of the 3 bubba kush sprouted and the peanut butter breath sprouted.. still early only been 2 days.

Je commence la deuxième semaine de strech J'ai modifié la puissance de la led et la hauteur pour pouvoir changer le "dli" (dli week 2= 35) JAI ENFIN RECU LE CALMAG après 10 jours🙄 wtf. Cette semaine , j'ai fait une erreur , j'ai laissé mes plants 5 jours sans boire 😔😔 (je n'avais pas le choix). J'ai changé ma manière d'arroser. Les 6 premières semaines a chaque arrosage (additifs et/ou engrais) A partir de cette semaine , j'arrose 1 fois avec les additifs et les engrais , 1 x juste avec le calmag et 1 x juste à leau. Je suis à flo+13 , donc normalement la fin du stretch, mais je m'étonne de voir que les plantes sont petites. La plus grande fait maximum 70 cm.🤔🤔🤔. Demain normalement le stretch devrait être fini. Et puis on verra . Le reste la semaine prochaine...

Somewhat slacking with detailed photos from this week, been busy with the holidays/ family etc. hopefully should have a little more time to take some good ones for next week.. Not much to say, they are getting quite big! some more lower branches and leaves were removed and I've been watering every other day, about .5-.75 gal per plant until I see some run off and the top looks evenly moist. End of week 1 of flower and there are Lots of white pistils, a pleasant smell (controlled by my filter/vent) and some major stretching happening on the strongest branches. Already raised the light by a few inches twice now too keep the distance over 12 inches from these stretchy ones! 😏 Also found a large healthy looking seed in my grinder that I've saved (Mac 1 supposedly, its good smoke)

F66 Humboldt Sour Diesel SD3 only the tops buds swoll. the rest of the main colas didnt fatten up. Maybe it was me or the genetics or just the light distribution? She doesnt smell as vibrant as at F50-55. I dont know if she was ready back then SD2 buds fattened up and since she showed signs of flowering a week later than SD2, it seems she is ready for harvest now as the she smells more vibrant right now at F66 I harvested Humboldt Sour Diesel at F68. SD2:137g wet 25dry SD3: 251g wet 48dry

Good week. Issues found.

Here we are at week 8 of flower plants are getting cut down tomorrow at day 56! I would of liked to push them another week but I’m literally getting my neighbors knocking on the door telling me it’s the smell is too strong! But I’m hyped to smoke these strains the snowcandy is a keeper forsure I got a couple more phenos of each strain I’m going to run next round so that should be promising ! Definitely go grab some of robinhoodseeds strains they are always fire!

D57 F13 - The week is off to a good start. This lady continues to bush out AND stretch at the same time! I started doing some minimal HST - just to try to keep her going as much "out" as possible, as opposed to "up." D59 F15 - Feeding every other day was just not cutting it anymore, therefore, I started feeding daily this week. There are two other plants in the tent besides this Zkittles, one Sour Diesel and one 707 Headband. So, I'm currently mixing up 12 gal. of nutes in a batch, feeding 6 gal every day - 2 gal/day per plant. Check out the ladies getting fed in the video I included above ;-) Also, I took several pics today; some of those pretty buds getting of to a good start.

I'm happy :) I couldn't do it as it should have been, my ph meters broke and ruined everything :( well, but I'm very, very satisfied with the result :) a big thank you to my teacher :)@AsNoriu you are super :) without you it wouldn't have been possible :) I learned a lot of useful information from you :) the house is full of lemon aroma :)

6 week started in July, 8. In this week i incorporate some CO2.The plants look great.The tallest plant is a syrup buddha, its weird because she is one week younger.I know that i said that i will do another diarie for the younger plants but im lazy, and the other plants are faster than the Lemons, so they are kind of in the same week. I keep feeding them with 1/2 of the snoop's premium nutrients bloom and the other half with snoop's premium nutrients grow, following the recommendations of the product. Also i incorporate Genesis from Agrobeta (pictures in the 5 week).

Unsere Cinderella bleibt, trotz eines kurzen Zwischenschub, eher eine der zierlicheren Pflanzen. Aktuell baut sie weiter und kontinuierlich ihre Buds auf. Alles bestens bei unserer Prinzessin. Alles in allem eine eher ruhige und gute Growwoche. 😏

so far so good they look nice and healthy

Esta cosecha fue muy buena con excelentes resultados de flores muy compactas y demasiado resinosas , la genética en sí es muy resinosa con olor muy característico , con sabores terrosos muy marcados .

D57/F13 - 27/05/23 - Added sunset and sunrise (only red lights for 1,5 hours at the start and 1,5 at the end) D58/F14 - 28/05/23 - I set up my AFD (see picture). I find a way to feed her automaticly when I 'll be out, Every day I start the pump for 30 sec (about) to give her 2 liters of nutes with my AFS (Automatic Feeding System) D59/F15 - 29/05/23 - Automatic feeding D60/F16 - 30/05/23 - Automatic feeding D61/F17 - 31/05/23 - Automatic feeding D62/F18 - 01/06/23 - Automatic feeding D63/F19 - 02/06/23 - I'm back, Nora looks ok, automatic feeding works. A little bit of problem with timelaps framing, but it's ok, I've got all info I need. EC 0.9 and pH 6.5

Removed autoflower and put her in her own pot outside the tent. Foliars applied in strong blue 430nm with 4000Hz tone. 20-minute dose prior to application. In essence, you're seeing a combination of the infrared light reflected by the plant, which the camera perceives as red, and any residual visible blue light the plant reflects, which results in a purple hue. I was doing more stretching of the stems, adjusting weights, just a little too much, and it snapped almost clean. I got a little lucky in that it was still connected, wrapped her almost instantly while holding her in place with yoyo's. The core framework is now in place. If your soil has a high pH, it's not ideal; you want a pH of 6.4, 6.5, or 6.6, which is ideal. If you are over a pH of 7, you have no hydrogen on the clay colloid. If you want your pH down, add Carbon. If you keep the pH below 7, you will unlock hydrogen, a whole host of new microbes become active and begin working, the plant will now be able to make more sugar because she has microbes giving off carbon dioxide, and the carbon you added hangs onto water. Everything has electricity in it. When you get the microbes eating carbon, breathing oxygen, giving off CO2, those aerobic soil microbes will carry about 0.5V of electricity that makes up the EC. The microorganisms will take a metal-based mineral and a non-metal-based mineral with about 1000 different combinations, and they will create an organic salt! That doesn't kill them, that the plant loves, that the plant enjoys. This creates an environment that is conducive to growing its own food. Metal-based: Could include elements like iron, manganese, copper, or zinc, which are essential nutrients for plants but can exist in forms not readily accessible. Non-metal-based: Examples like calcium carbonate, phosphate, or sulfur are also important for plant growth and potentially serve as building blocks for the organic salt. Chelation in a plant medium is a chemical process where a chelating agent, a negatively charged organic compound, binds to positively charged metal ions, like iron, zinc, and manganese. This forms a stable, soluble complex that protects the micronutrient from becoming unavailable to the plant in the soil or solution. The chelate complex is then more easily absorbed by the plant's roots, preventing nutrient deficiency, improving nutrient uptake, and enhancing plant growth. Chelation is similar to how microorganisms create organic salts, as both involve using organic molecules to bind with metal ions, but chelation specifically forms ring-like structures, or chelates, while the "organic salts" of microorganisms primarily refer to metal-complexed low molecular weight organic acids like gluconic acid. Microorganisms use this process to solubilize soil phosphates by chelating cations such as iron (Fe) and calcium (Ca), increasing their availability. Added sugars stimulate soil microbial activity, but directly applying sugar, especially in viscous form, can be tricky to dilute. Adding to the soil is generally not a beneficial practice for the plant itself and is not a substitute for fertilizer. While beneficial microbes can be encouraged by the sugar, harmful ones may also be stimulated, and the added sugar is a poor source of essential plant nutrients. Sugar in soil acts as a food source for microbes, but its effects on plants vary significantly with the sugar's form and concentration: simple sugars like glucose can quickly boost microbial activity and nutrient release. But scavenge A LOT of oxygen in the process, precious oxygen. Overly high concentrations of any sugar can attract pests, cause root rot by disrupting osmotic balance, and lead to detrimental fungal growth. If you are one who likes warm tropical high rh, dead already. Beneficial, absolutely, but only to those who don't run out of oxygen. Blackstrap is mostly glucose, iirc regular molasses is mostly sucrose. Sugars, especially sucrose, act as signaling molecules that interact with plant hormones and regulate gene expression, which are critical for triggering the floral transition. When sucrose is added to the growth medium significantly influences its effect on floral transition. Probably wouldn't bother with blackstrap given its higher glucose content. Microbes in the soil consume the sugar and, in the process, draw nitrogen from the soil, which is the same nutrient the plant needs. Glucose is not an oxygen scavenger itself, but it acts as a substrate for the glucose oxidase (GOx) enzyme, effectively removing oxygen from a system. Regular molasses (powdered if you can), as soon as she flips to flower or a week before, the wrong form of sugar can delay flower, or worse. Wrong quantity, not great either. The timing of sucrose application is crucial. It was more complicated than I gave it credit for, that's for sure. When a medium's carbon-to-nitrogen (C:N) ratio reaches 24:1, it signifies an optimal balance for soil microbes to thrive, leading to efficient decomposition and nutrient cycling. At this ratio, soil microorganisms have enough nitrogen for their metabolic needs, allowing them to break down organic matter and release vital nutrients like phosphorus and zinc for plants. Exceeding this ratio results in slower decomposition and nitrogen immobilization, while a ratio below 24:1 leads to faster breakdown and excess nitrogen availability. Carbon and nitrogen are two elements in soils and are required by most biology for energy. Carbon and nitrogen occur in the soil as both organic and inorganic forms. The inorganic carbon in the soil has minimal effect on soil biochemical activity, whereas the organic forms of carbon are essential for biological activity. Inorganic carbon in the soil is primarily present as carbonates, whereas organic carbon is present in many forms, including live and dead plant materials and microorganisms; some are more labile and therefore can be easily decomposed, such as sugars, amino acids, and root exudates, while others are more recalcitrant, such as lignin, humin, and humic acids. Soil nitrogen is mostly present in organic forms (usually more than 95 % of the total soil nitrogen), but also in inorganic forms, such as nitrate and ammonium. Soil biology prefers a certain ratio of carbon to nitrogen (C:N). Amino acids make up proteins and are one of the nitrogen-containing compounds in the soil that are essential for biological energy. The C:N ratio of soil microbes is about 10:1, whereas the preferred C:N ratio of their food is 24:1 (USDA Natural Resource Conservation Service 2011). Soil bacteria (3-10:1 C:N ratio) generally have a lower C:N ratio than soil fungi (4-18:1 C:N ratio) (Hoorman & Islam 2010; Zhang and Elser 2017). It is also important to mention that the ratio of carbon to other nutrients, such as sulfur (S) and phosphorous (P) also are relevant to determine net mineralization/immobilization. For example, plant material with C:S ratio smaller than 200:1 will promote mineralization of sulfate, while C:S ratio higher than 400:1 will promote immobilization (Scherer 2001). In soil science and microbiology, the C:S ratio helps determine whether sulfur will be released (mineralized) or tied up (immobilized) by microorganisms. A carbon-to-sulfur (C:S) ratio smaller than 200:1 promotes the mineralization of sulfate, when the C:S ratio is low, it indicates that the organic matter decomposing in the soil is rich in sulfur relative to carbon. Microorganisms require both carbon and sulfur for their metabolic processes. With an excess of sulfur, microbes take what they need and release the surplus sulfur into the soil as plant-available sulfate A carbon-to-sulfur (C:S) ratio higher than 400:1 will promote the immobilization of sulfur from the soil. This occurs because when high-carbon, low-sulfur materials (like sawdust) are added to soil, microbes consume the carbon and pull sulfur from the soil to meet their nutritional needs, temporarily making it unavailable to plants. 200:1 C:S 400:1: In this range, both mineralization and immobilization can occur simultaneously, making the net availability of sulfur less predictable. This dynamic is similar to how the carbon-to-nitrogen (C:N) ratio regulates the availability of nitrogen in soil. Just as microbes need a certain amount of nitrogen to process carbon, they also require a balanced amount of sulfur. Both mineralization and immobilization are driven by the metabolic needs of the soil's microbial population. Sulfur is crucial for protein synthesis. A balanced ratio is particularly important in relation to nitrogen (N), as plants need adequate sulfur to efficiently use nitrogen. A severely imbalanced C:S ratio can hinder the efficient use of nitrogen, as seen in trials where adding nitrogen without balancing sulfur levels actually lowered crop yields. Maintaining a balanced carbon-to-sulfur (C:S) ratio is highly beneficial for plant growth, but this happens indirectly by regulating soil microbial activity. Unlike the C:N ratio, which is widely discussed for its direct effect on nutrient availability, the C:S ratio determines whether sulfur in the soil's organic matter is released (mineralized) or temporarily locked up (immobilized). Applied 3-day drought stress. Glucose will hinder oxygenation more than sucrose in a solution because glucose is consumed faster and has a higher oxygen demand, leading to a more rapid decrease in oxygen levels. When cells respire, they use oxygen to break down glucose, and this process requires more oxygen for glucose than for sucrose because sucrose must first be broken down into glucose and fructose before it can be metabolized. In a growth medium, glucose is a more immediate and universal signaling molecule for unicellular and multicellular organisms because it is directly used for energy and triggers a rapid gene expression response. In contrast, sucrose primarily acts as a signaling molecule in plants to regulate specific developmental processes by being transported or broken down, which can be a more complex and slower signaling process. Critical stuff. During wakefulness (DC electric current) life can not entangle electrons and protons. During the daytime, the light is sensed as multiple color frequencies in sunlight. Coherence requires monochromatic light. Therefore, at night, IR light dominates cell biology. This is another reason why the DC electric current disappears during the night. The coherence of water is maintained by using its density changes imparted by infrared light released from mitochondria in the absence of light. This density change can be examined by NMR analysis, and water is found to be in its icosahedral molecular form. This is the state that water should be in at night. This is when a light frequency is lowest and when the wave part of the photoelectric effect is in maximum use. 3600

Topping effectué pour arriver à 16 colas Palissage des tiges secondaire aux noeuds du bas afin de commencer à les former pour dans la tente de 90x60 pour qu’il puisse s’épanouir et ainsi pendre tous l’espace On va le garder au maximum à la hauteur qu’il est actuellement et essayer de faire en sorte que les tiges occupe entre 80x50 à 85x55 d’espace dans la box Pour ensuite les laisser monter 10/15cm en hauteur et lancer la floraison À la 3ème photo j’ai fait un dessin pain de la futur mise en formation En rouge ça sera les middle bud qui occuperont l’espace centrale Vert foncée ça sera les bud qui occuperont les espaces gauche /droite du centre de la longueur de la grande box Pour l’autre vert ça sera le comblement de la largeur Le dessin n’est pas la finalité du projet c’est juste la suite d’actuellement On avisera au moment venu du bouquet fin Pour la floraison il y aura la mise en place d’un 2ème panneaux SANlight dans la grande boxe afin de croiser les spectre et donner une meilleur pénétration lumineuse pour la floraison, j’espère atteindre un beau rendement au cm2

Week #18 GSC By Kannabia Week #18 Mar 8th-15th Week #7 Flower This week she's looking beautiful purple through out the plant the orange in the buds. Stay Growing!! Thanks for stopping by!!

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