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Nach einer Woche Nährstoff Lockout durch zu viel Wasser haben sich die Ladys wieder erholt und trotzdem ca 5 cm zugelegt. Ich habe jetzt 6 Tage nicht gegossen und morgen gibt es nur 1,5 Liter und am Montag nochmal 1 Liter. Dann dürfen sie wieder 4 Tage davon zehren. Danach sollten die Wurzeln stark genug und angewachsen sein, um mit den geplanten 2,5 Liter Wasser weiter zu gießen. Dann ca alle 3 Tage bis Woche 5 und dann gießen nach Plan auf biologischer Erde - ca 1/3 des Topfvolumens pro Gießgang. Man kann an manchen Stellen den Mg/Ca Lockout gut erkennen. Bin gespannt wie es weiter geht. 🤞 Stofftöpfe ist eine neue Erfahrung für mich 🌱🌿💚 Keep on growing 💚
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Some of the buds/ leafs were starting to turn brown. It seems like it was a bit past it's prime, I harvested on day 60 of flower. The strain was 56-63 days Jack Herer by pHenos Nursery. The trichoms looked ready, I did have some issues that I've noted in previous weeks but it smells amazing and I can't wait for it to finish drying and curing!
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@Targona
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The girl is still growing tall and has started to bloom. He still has a lot of time ahead of him and it is a strong and healthy plant. 😊
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The Moab girls on going on the last week run before chop. The double UNiT FARM UFL3000 lights has performing amazing! An really got the buds going. Very nice growth rate an bud density. Beside the mishaps that happen on my end of everything performed great.
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@FrankFarm
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Kia Ora Hello / สวัสดีคับ ทุดคน every body here are our farm First legal season Germination rate alright for sure if i took them out from the chamber earlier they all would make it my bad Watering only ph to around 6.2 🙏
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@LIPANJA
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So guys, amber trichomes have started to appear, so today was the last feeding with nutrients. In two days I’ll start the flush (which will last 5 days), and next weekend I'll do the harvest. A lot of the upper leaves are brittle, the smell is sweet and pleasant, with moderate potency — maybe because I didn’t reach lower temperatures during flowering, and also due to excess nutrients at some stages. Besides the delay caused by keeping it on 12/12 for a few weeks because of other plants, and the fact that it will need to spend the final 3 weeks in my secondary tent, which I normally use for drying, with older lights instead of my new and more powerful one. Despite all the setbacks, it will definitely yield over 100g dry and will have a very pleasant aromatic profile. Então galera, começaram a aparecer tricomas âmbares, então hoje foi a ultima rega com nutrientes, em 2 dias começarei o flush (que durará 5 dias), e no proximo fim de semana faço a colheita. Bastante folhas superiores quebradiças, cheiro doce, agradável, moderado em potência, talvez porque não atingi temperaturas baixas durante a floração, e também por excesso de nutrientes em algumas fases, tirando o atraso que precisou ficar 12/12 por algumas semanas por conta de outras plantas, e tirando também o fato de que vai precisar ficar as 3 semanas finais na minha estufa secundária que uso pra secagem com luzes antigas ao invés da minha nova e potente. Apesar de todos os transtornos ela com certeza vai render acima de 100g seco e terá um perfil aromático bem agradável.
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@NastyNug
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4x8, 1000w HPS (@50%- 500 w) on a Light Rail mover. Transition week. 1g to 3g pot. Azamax 2 wk PM. Scrogged, down to 12-16 inches. Not sure if I over vegged. Took clones to start Veg 3. Distance to Canopy is 36”.
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@Ageddd
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Whats up GD !!! ------------- GROWTH------------- She is getting weight and finishing, leaves turned purple, red, and all the amazing colours you see in photos, she is almost ready and it is so frosty, Smells like red licorice, and fruits. Flushing last 7 days. ------------- IRRIGATION------------- 1,5l, watering each 3 days . 1 of 2 irrigations with nutes, and the other with water. ------------- NUTRIENTS------------- Top Bloom (3ml/l) Top Candy (2ml/l) --------------------------------------- Good vibes !! _29/06/2018_
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Day 1 – Germination (Water Glass Method) Today I started germinating my Gelato K seeds using the water glass method. The seeds are soaking in room temperature water for 12-24 hours, giving them a good start. Waiting for them to crack open and show the first signs of life! I'll keep you posted on the progress. 🌱💧 Day 2 – Into the Soil (No Germination Yet) Even though the seeds haven't germinated yet in the water, I decided to go ahead and plant them directly into the soil. I’ve placed the seeds about 1 cm deep and added a sprinkle of mycorrhizal fungi to help encourage root development once they sprout. Now, I’m making sure the soil stays moist and hoping the seeds will break through soon. Let's see what happens over the next few days! 🌱🌍 Day 4 – First Leaves Unfolding Exciting progress! 🌱 Yesterday, on Day 3, the seedling finally broke through the soil and made its appearance. Today, on Day 4, the first tiny leaves (cotyledons) have fully formed. It’s a great sign that the plant is establishing itself and is ready to begin photosynthesis. The soil is staying moist, and I’m keeping the light at a good distance to encourage steady growth. Looking forward to seeing those first true leaves pop up in the coming days!
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@Stonyways
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lights up to 66w, 28 inches from the top of the plants, fox farm nutrients for this grow..... already anticipating my next grow... start to the the Peet Pods I used were/are garbage, first and last time I will use them
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@MrFriday
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Ill hang em to dry and see the real harvest soon.
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8. Woche Läuft soweit gut, Z-Up ist aktiv am Bloom produzieren 😊
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@GoodBudz
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Pineapple Express was an exciting plant to grow. It grew fast and stretched nicely. Purple Kush was just a runt. It did not like the hot climates from the previous week but grew it out anyway. By weeks end was feeding Remo's full flower lineup. Pineapple - 8ml per 3800ml Ph between 6 - 6.1 Purple - 5ml per 2000ml Ph between 6 - 6.1 No change in light scheduled as with Auto's they do not require the 12 hour darkness period to flower. **Spider Farmer lights generate a lot of heat.
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@HisHope
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12/28 Week 9 Maddie is on a water only diet not making her cranky yet Tammy is still stuffing her face at the buffet table happy as she can be 12/29 Picture day!
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Remember that, however you are played, or by whom, your soul is in your keeping alone. Even though those who presume to play you be kings or men of power, when you stand before God, you cannot say, 'But I was told by others to do thus,' or that virtue was not convenient at the time. This will not suffice. Remember that. Day:18 84°F and 65% RH (VPD) for the vegetative stage. Approximately 1.15kPa(assuming leaf temperature is about 2°F cooler than the air), which falls right into the ideal vegetative sweet spot (0.8kPa to 1.2kPa). At 1.15kPa, plants can draw water and nutrients efficiently without risking stress or wilting. It keeps the leaf pores (stomata) open, allowing for ideal carbon dioxide intake and maximizing vegetative growth. VPD is determined by the leaf's temperature, not just the ambient air. Because leaves usually run 1° to 3°F cooler than room air under bright grow lights, my actual VPD will be slightly lower, closer to the 1.0kPa mark. As she transitions from vegetative growth to flowering, one can gradually lower the humidity (to around 45–60%) and drop temperatures slightly to prevent disease from settling inside dense buds when they appear. Night:6 At 70°F and 60% relative humidity, Vapor Pressure Deficit (VPD) is 0.86 kPa. This is right on the cusp of whats optimal for the vegetative stage. During the nighttime, plants generally close their stomata and undergo cellular respiration rather than photosynthesis. Transpiration slows to a near stop, making VPD less critical at night than during the day. However, maintaining a nighttime VPD between 0.8 and 1.0 kPa is highly beneficial in that it ensures the air is dry enough to prevent powdery mildew or bud rot, but moist enough to keep the plant from undergoing unnecessary stress. This range keeps the environment comfortable for cellular processes and prevents large atmospheric swings. Keeping it all flowing. (Not pushing them yet, these are photoperiods) The optimal soil (root zone) temperature for cellular root respiration and nutrient uptake in cannabis is between 68F & 72F This narrow range balances biological energy production (cellular respiration) with the dissolved oxygen levels in the soil, maximizing plant growth and health. Warmer soils hold significantly less dissolved oxygen. When soil temperature exceeds 74F oxygen depletion occurs, inhibiting cellular respiration almost entirely, At 68-72F root cells generate optimal adenosine triphosphate (ATP) via respiration to power root-tip elongation and the active transport of water and nutrients. Too Hot (Above 78F) Root respiration increases, demanding more oxygen, while the water's oxygen-carrying capacity drops. This creates a prime environment for anaerobic pathogens and Pythium (root rot). Too Cold (Below 60F) Root metabolism and cellular respiration slow to a crawl. This severely impairs nutrient and water absorption, leading to yellowing, wilting, and phosphorus deficiencies. A lot depends on whether it's automatic or photoperiod; with photoperiod, there is not as much of a need to push "hard" as the real countdown only begins once the flower is initiated. Automatics, on the other hand, the chronological "clock" begins ticking the moment the seed germinates. It is of critical importance that the seedling growth gets off to the races, understanding that early growth is like compound interest, which will pay off come harvest. This reality is why getting autoflowers "off to the races" early on yields such exponential benefits. The "compound interest" is directly related to the surface area of the leaves. Larger, faster-growing seedlings process more light and build bigger root networks early on, which translates into an explosion of vertical and lateral growth during their short vegetative window. The margins for error are so thin with autoflowers; this early-stage momentum depends on several critical practices. Seedlings exposed to increased atmospheric CO2 levels early in life will develop at an increased rate. To effectively "extend" or optimize the capacity of Photosystem II (PSII) for increased photosynthetic efficiency. In standard oxygenic photosynthesis, Photosystem II (PSII) is naturally limited to the red-light spectrum, peaking at 680nm. Extending its light-harvesting capacity past 700nm into the far-red region requires bypassing the natural limits of standard chlorophyll a. Adding 730 nm (far-red) LEDs alongside standard red/blue lights has been shown to increase canopy photosynthesis by 20–30% in several crops by acting synergistically with shorter wavelengths. However, the limitation is that excessive, pure IR/Far-red light (without accompanying red light) can trigger the "shade avoidance response," causing plants to grow tall, weak, and spindly rather than robust. Utilizing infrared light (specifically the 700-750 nm far-red range) is a viable method to boost photosynthetic efficiency. It acts as a bridge to allow PSII to utilize a broader spectrum of light, breaking the traditional 700 nm barrier. UVR8-mediated signaling (often in conjunction with CRY proteins) triggers protective mechanisms that maintain the stability of the photosynthetic apparatus (including LHCII and reaction center proteins), thus ensuring that the efficiency of Photosystem II remains higher in UV-B-exposed plants compared to plants lacking this receptor. ΦPSII indictates the rate of electron transfer from water to plastoquinone, which drives the production of ATP and NADPH. There is a close link between ΦPSII and the true rate of CO2 fixation (Φ*co2). ETR stands for Electron Transport Rate. It measures the speed at which electrons are moved through the thylakoid membranes in a plant's chloroplasts during the light-dependent reactions of photosynthesis. Infrared light (particularly Near-Infrared or NIR) improves cellular energy by interacting directly with the electron transport chain (ETC) in mitochondria. This process boosts adenosine triphosphate production, which acts as a metabolic coefficient multiplier by accelerating enzyme activity dramatically. Extend then multiply. Far-Red photons interact with plant photoreceptors to accelerate the plant’s biological "clock" or trigger a shade-avoidance response. Autoflowers don't use the plant's biological clock, although the IR will initiate a shade avoidance and make them stretchy. You can just add equal measures of 660nm-680nm to negate the shade avoidance effect. Replacing nights' "darkness" with a combination of IR+ and 660nm. Because autoflowers don't require a dark period to flower, many growers just blast them with light. 18/6 24/0. However, this ignores the plant's metabolic rhythms, where daytime photosynthesis (light reactions) must be perfectly balanced with nighttime carbon fixation and assimilation (Calvin cycle) to avoid bottlenecking plant development. Cellular respiration is a 24/7 process, but it can only function while the plant has the free oxidative capacity to do so. A 100% photosynthetically active leaf cannot perform cellular respiration. The viral trend of defoliation of every leaf that isn't "getting enough light" is of great detriment overall, putting 100% of the cellular respiratory "workload" and responsibility on the 0/4/6 hours of darkness in sub-optimal conditions for enzymatic activity. Photosynthesis captures nearly 100% of the initial energy as carbon, while cellular respiration is the process that unlocks 90% of that captured energy into usable ATP so the plant can use it. Respiration is considered roughly 30% to 40% efficient. It captures enough of the potential energy in glucose to synthesize around 30 to 38 ATP molecules per glucose molecule. The remaining 60% to 70% of the energy in the sugar is not captured in ATP; instead, it naturally escapes into the environment as heat, which helps regulate plant temperature. In plants, the primary enzymes of the Electron Transport Chain (ETC) and the ATP synthase complexes are typically adapted to function optimally in warmer temperatures (roughly 25°C to 35°C depending on the specific plant strain). As temperatures rise within this physiological range, molecular collisions increase, speeding up respiration and ATP production. The cannabis plant has a branched respiratory pathway. During heat or cold stress, plants activate Alternative Oxidase (AOX). AOX burns sugars to dissipate energy as heat rather than coupling it to ATP production. This pathway actually functions optimally at elevated temperatures to help protect the cell from the damaging build-up of Reactive Oxygen Species (ROS) during heat stress. Enzyme activity generally scales with heat; there is a strict biological limit. If canopy temperatures in a grow room exceed 40°C, the enzymes and their supporting lipid membranes lose stability. Not saying you need to go crazy, just optimize nights the same as we optimize days. Phosphorus is the driving force behind early seedling development. It acts as the "energy hub" of the plant, directly driving cell division, robust root growth, and the creation of DNA. Without an adequate, easily accessible supply early on, the plant's overall growth potential and final yield can suffer permanently. E=MC2 looks like a simple multiplication problem; it describes a fundamental physical truth: mass and energy are the same thing. The equation doesn't just calculate a value; it reveals that mass is effectively "congealed" energy. Energy is just numbers. Energy isn't a physical "substance" you can hold or touch. It is essentially an abstract, calculated number that we assign to a system to predict how it will change, interact, or move. A numerical label we attach to matter to track how it behaves. Because the universe runs on laws of symmetry (specifically, that the laws of physics don't change over time), a single global number must be conserved. We call that number "energy". We don't grow; we facilitate energy conversion. How well a seedling grows is essentially down to how much knowledge one can acquire to increase the level of conversion to occur. Applying knowledge effectively requires intuition, which comes from hands-on experience. A seasoned stoner learns to read subtle signs—like a slight change in leaf turgor (stiffness), subtle color shifts, or the specific texture of the soil—before a textbook diagnosis can be made. Ultimately, growing is the application of botanical science blended with active observation. Knowledge dictates your potential, but adaptability and attentiveness to the plant's immediate environment determine your results. 1.618 nature mathematically optimizes quantum energy transfer and light absorption efficiency within the photosynthetic machinery, as it naturally dictates energy scaling hierarchies and resonance dynamics. External vibration or electromagnetic wave that perfectly matches a plant's natural frequency directly influences plant growth. Low-frequency sound waves and targeted electromagnetic fields stimulate cellular processes and boost photosynthetic efficiency Does it produce better yields? How long is a piece of string? As long as you cut it. But isssss the juice worth the squeeze? The quantum framework of the IVM seems to think so. Good enough for the quantum firmware, good enough for the DNA software. Genetics are not dictated; they are expressed; the rate of that expression is dictated by the environment in which growth occurs. Quantum Coherence in Photosynthesis occurs When a photon of sunlight strikes a leaf, the energy it carries must travel to a reaction center to be converted into chemical energy. This process operates at nearly 100% efficiency. If the energy moved in a traditional "bunching" or random hopping manner, a large portion of it would be lost as heat. Instead, plants utilize quantum superposition. The energy particle (exciton) doesn't just take one path; it exists in a wave state and explores multiple pathways simultaneously. It essentially "chooses" the most efficient route to the reaction center simultaneously. Research shows that molecular vibrations and the specific network arrangements of chlorophyll molecules (like the naturally evolved Chlorophyll A & B ratios) actively protect against energy overflow, optimizing light capture across different light intensities. Enzymes are the biological catalysts that speed up chemical reactions within a plant's cells, allowing them to grow, metabolize, and repair. Rather than relying solely on the classical kinetic energy of molecules colliding, plants use quantum tunneling. Subatomic particles like electrons and protons (hydrogen ions) can literally "teleport" through energy barriers that they normally wouldn’t have the energy to climb over. This makes vital metabolic reactions happen far faster than classical physics could ever explain. Chloryphyll b has peak absorption at 460nm (Blue) and at 647nm(Red). If we take the blue peak wavelength 460nm and a UV-B, UVR8 peak absorption wavelength 285nm, Tryptophan-285 (W285) Sensing protein. 460/285=1.618 Φ If we take chlorypyhll b's Red absorption peak 647nm and a UV-A of 400nm, we get 647/400=1.618 Φ. "Structure of light". The cryptochrome photoreceptor (CRY) is a UV-A/blue light receptor that shares this dual sensitivity with several other biological structures and functions, including significant sequence similarity and a common evolutionary ancestor with DNA photolyase enzymes. These are light-activated enzymes that use blue/UV-A light to repair DNA damage caused by UV-B radiation in plants. Synergistic. But Shhh, it's a secret. Effective quantum efficiency of photosystem II, often denoted as ΦPSII, represents the proportion of light absorbed by Photosystem II (ΦPSII) that is actually used in photosynthetic electron transport. It is a key indicator of how efficiently a plant is using light for photosynthesis, as opposed to losing it as heat or fluorescence. ΦPSII (effective quantum yield of photosystem II) functions primarily as a "multiplier" (a coefficient of efficiency) rather than an additive factor when estimating the overall photosynthetic electron transport rate (ETR). Multipliers are considered far more beneficial than additions because they generate exponential growth, leverage existing resources to their full potential, and create sustainable, self-multiplying capacity, rather than just incremental, linear increases. This fascinating observation is rooted in the intersection of subatomic geometry, fractal scaling, and quantum dynamics. In specific molecular arrangements—such as in conjugated polymer networks or biomolecular architectures—the Golden Ratio (PHI) naturally dictates energy scaling hierarchies and resonance dynamics. Mathematically tied to the fine-structure constant, which defines the strength of the electromagnetic interaction. The Golden Ratio can be mapped geometrically as the Golden Angle (137.5 degrees) in atomic structures, linking the charge of the electron to fundamental quantum constants like Planck's constant. Electromagnetic. The Golden Angle (137.5): This angle is derived from the Golden Ratio (1.618). It is the smaller of two angles created when a circle is divided such that the ratio of the arcs equals the Golden Ratio.
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@Zuppler
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Grow Report by Zuppler - Week 3 Veg Phase Ayy, what it do fam? Zuppler back on the check-in with that week 3 veg report, live from the capital. Yo, these girls ain’t playin’ no more – they really startin’ to stack up, lookin' thick in the canopy like they preppin' for somethin’ big. We still runnin’ that Advanced Nutrients like clockwork, straight through that RO water, keepin’ it pure as a Miami night breeze. The nodes are gettin’ tight, leaves spreadin’ out nice and wide, takin’ all that light. I hit ‘em with a little scrog, just a lil’ bend here and there, makin’ sure that light hit every corner of the canopy. You already know I’m tryin’ to maximize that potential. Stems got that thick structure, and no signs of nute burn or nothin’. We’re talkin’ flawless execution, fam. At this point, it’s just watchin’ ‘em fill out, keepin’ the environment dialed in and lettin’ ‘em do their thing. We’re settin’ the stage for a strong finish when we flip ‘em to flower. Zuppler out, stay blessed.