Really sorry for anyone that was actually following and wanted to see updates but I had to take some time away and neglected this project. My friend/neighbour/weed mentor passed away and I just haven’t felt the same. Moving along, after cleaning up most of the big fan leaves I decided to just switch into flower… I have 3 seedlings of Tropicana poison F1 saved out of 40. This was the next project of my friend that has passed. My goal is to finish this grow and honor my late friend with a grow diary of his plants. I’m sure he’ll be smiling above. 36 hours of darkness before proceeding to switch lighting to 12/12 Added 3 feedings a day now, but reduced the amount fed. Food has been given extra liquid mycorrhiza and bacteria. Will be using PLAGRON: Green sensation 4-in-1 in addition to megacrop at week 4 of flowering and see if there’s any benefits

******************************************** Week 7 Transition to flower (flower week1) ******************************************** Light cycle=12/12 Light Power=218w 90% Extractor controller settings High temp= Day 24c, Night 20c Low temp= c Temp step=0c High Rh= Day 55%, Night 58% Low Rh= % Rh step=0% Speed max=9 Speed min=2 Smart controller settings (during lights on). Lights on=9.00am Top fan on=+23.5c Top fan off=-23.0c Dehumidifier on=+59% Dehumidifier off=-58% Smart controller settings (during lights off). Lights off=9.00pm VPD aim=0.6-1.4 DLI aim=25-35 EC aim=0.2-2.0 PH aim=6.0-6.5 NPK(15.4/7.2/25) 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 Method= Autofeed 6 drippers. Feed=Flower Nutes. Neutralise=0.1ml/L Bloom=4.0ml/L Roots=0.2ml/L Silicon=1.0ml/L Calmag=1.0ml/L Boost=1.0ml/L Volume=12L Easy Ph down= 0.125ml/L Ec=1.95 PH=6.4/6.4 Runs=17 Run times=4min (296ml each) Gap times=16min Total runtime=68mins (5.0L each) Total flowrate= 147ml/min (74ml/min each) Auto start time=10.00am Auto stop time=3.24pm 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 ******************************************** ******************************************** 📅30/6/24 Sunday (day 43, day 1 flower) 📋 H=48cm D=33cm Dli=29.7 Ppfd=688 12/12 Raised light and increased power to 218w 90% H=48cm D=43cm Dli=29.2 Ppfd=677 12/12 📅1/7/24 Monday (day 44 day 2 flower) 📋 💧 Method= automatic Feed=Nutes flower Volume=12L Ec=1.96 PH=6.4/6.4 Volume left=3L Volume used=9L (147ml/min) Volume each=4.5L (74ml/min) Runoff. Total runoff=0.4L Ec=2.5 PH=/6.4 💧 📅2/7/24 Tuesday (day 45, day 3 flower) 📋 Defoliate lower leaves about 8. H=53cm D=38cm Dli=33.2 Ppfd=768 12/12 📅3/7/24 Wednesday (day 46, day 4 flower) 📋 🚿Foliar feed (calmag 2ml/L/Boost 2ml/L) 1 hour before lights on. 📅4/7/24 Thursday (day 47, day 5 flower) 📋 H=57cm D=34cm Dli=38.8 Ppfd=897 12/12 HST 2 tallest colas. Drip system needs cleaning out again. 💧 Method= automatic Feed=Nutes flower Volume=12L Ec=1.95 PH=6.4/6.5 Volume left=3.5L Volume used=8.5L (147ml/min) Volume each=4.25L (74ml/min) Runoff. Total runoff=0L Ec= PH=/ Feed=manually 0.5L each Then 30 min break Feed=manually 0.5L each Runoff. Total runoff=0.6L Ec=3.4 PH=/6.2 💧 📅5/7/24 Friday (day 48, day 6 flower) 📋 Bent over tallest 2 colas and put a slight break in one of them. 📅6/7/24 Saturday (day 49, day 7 flower) 📋 She is starting to show pistils. H=62cm D=29cm Dli=42.0 Ppfd=972 12/12 Raised light. Not much room left above it. H=62cm D=37cm Dli=33.4 Ppfd=774 12/12 ******************************************** Weekly roundup. 📋 it's been another excellent week for this one, I managed to really hit her with some photons this week due to the weather cooling off and being able to get a better grip on the environment, because of this iv limited the 1st week of flower stretch to 14cm. I'm still going to run out of headroom and will need to lower the power later in the grow. Take it easy. Back soon. ********************************************

The ideal PPFD level for seedlings is between 100-300 micromoles per square meter per second (μmol/m²/s). This softer lighting mimics the diffused sunlight of early spring, providing enough energy for seedling-stage plants to develop their initial leaves without overwhelming them. at 48 inches from light sources, the seedlings receive around 150-180μmol/m²/s, as they grow they grow towards the higher levels of ppfd naturally. Urine is a liquid waste product as a result of our kidneys cleaning and filtering our blood. Typically, urine contains around 95% water and the rest are a mix of salts including sodium, potassium and chloride, urea, and uric acid. Due to the high water content in pee, the more you drink, the more you have to go. For a healthy person, human urine typically has a pH of around 6.2 with a range of 5.5-7.0. A person’s diet and alcohol consumption can also affect the pH of their urine. The main organic component of urine is urea, a combination of ammonia and carbon dioxide, which is the byproduct of our bodies breaking down proteins into usable amino acids. Urea is very high in nitrogen, a key ingredient to healthy leafy growth in plants. In addition to being very nitrogen-rich, urine also contains dissolved phosphorus that’s immediately available to plants, making urine a quick-acting fertilizer. Diesel exhaust fluid for motor engines is made up of 70% de-ionized water and 30% Urea. I didn't know that. Interesting stuff. If you own a dog, you may be familiar with yellow patches on your lawn where your pet has peed. Dogs and cats excrete fresh urine with a higher quantity of urea than humans do and that can more easily burn a plant upon contact. Human urine contains less urea and thus less ammonia. A novel electrochemically induced method for ammonia synthesis (eU2A) on demand from urea in alkaline media was demonstrated. A Nickel based electrode was employed as the active catalyst. The effective rate of ammonia generation of the eU2A process at 70◦C is ∼28 times higher than the thermal hydrolysis (THU) of urea. Despite Bear Grylls drinking urine in his popular survival shows, urine is not sterile. It picks up trace amounts of bacteria as the sterile version passes through the bladder, the urinary tract and comes in contact with the skin. Still, the health risks of using urine are very low because urine does not typically contain pathogens found in feces. Infectious diseases like cholera are spread through water sources contaminated by poop. In areas with poor sanitation, there is no way to separate solid and liquid waste which is why all untreated mixed sewage can pose significant public health risks. Only 10-15% of all nutrition you ingest is absorbed, all the rest is disposed of in the urea of urine, 95% Water, 5% Urea. Human urine consists primarily of water (91% to 96%), with organic solutes including urea, creatinine, uric acid, and trace amounts of enzymes, carbohydrates, hormones, fatty acids, pigments, and mucins, and inorganic ions such as sodium (Na+), potassium (K+), chloride (Cl-), magnesium (Mg2+), calcium (Ca2+), ammonium (NH4+), sulfates (SO42-), and phosphates (e.g., PO43-).1 A Representative Chemical Composition of Urine Water (H2O): 95% Urea (H2NCONH2): 9.3 g/l to 23.3 g/l Chloride (Cl-): 1.87 g/l to 8.4 g/l Sodium (Na+): 1.17 g/l to 4.39 g/l Potassium (K+): 0.750 g/l to 2.61 g/l Creatinine (C4H7N3O): 0.670 g/l to 2.15 g/l Inorganic sulfur (S): 0.163 to 1.80 g/l The pH of human urine ranges from 5.5 to 7, averaging around 6.2. The specific gravity ranges from 1.003 to 1.035. Significant deviations in pH3 Chemical Concentration in g/100 ml urine Water 95 Urea 2 Sodium 0.6 Chloride 0.6 Sulfate 0.18 Potassium 0.15 Phosphate 0.12 Creatinine 0.1 Ammonia 0.05 Uric acid 0.03 Calcium 0.015 Magnesium 0.01 The element abundance depends on diet, health, and hydration level, but human urine consists of approximately: Oxygen (O): 8.25 g/l Nitrogen (N): 8/12 g/l Carbon (C): 6.87 g/l Hydrogen (H): 1.51 g/l Morning piss is best, diluted to 6-10 parts water. Breaking Down Nitrogen Forms & Their Impact: Forms of Nitrogen: Nitrogen, comes in three primary forms: ammonium, nitrate, and urea. Ammonium (NH4+) carries a positive charge, nitrate (NH3–)carries a negative charge, while urea ((NH2)2CO) carries no charge. Natural Processes in Media: Once these nitrogen forms are introduced into the growing media, natural processes kick in. Bacteria play a vital role, converting urea to ammonium or ammonium to nitrate. This latter conversion releases hydrogen ions, increasing media acidity. Urea Conversion: Urea undergoes rapid conversion to ammonium in the soil, usually within two days. Both urea and ammonium are often grouped together and referred to as ammoniacal nitrogen. When plants absorb nitrogen, they typically release a molecule with the same charge to maintain internal pH. This process can also alter the pH of the media surrounding the roots. pH Effects of Nitrogen Uptake: Ammonium (NO4) Uptake and pH: When plants absorb ammonium, they release hydrogen ions (H+) into the media. This increases the acidity of the media over time, decreasing the pH. Nitrate (NO3) Uptake and pH: Plants take up nitrate by releasing hydroxide ions (OH–). These ions combine with hydrogen ions to form water. The reduction in hydrogen ions eventually reduces the media acidity increasing the pH. Nitrate (NO3) Absorption Variations: Sometimes, plants absorb nitrate differently, either by taking in hydrogen ions or releasing bicarbonate. Like hydroxide ions, bicarbonate reacts with hydrogen ions and indirectly raises the media pH. Understanding these processes helps in choosing the appropriate fertilizer to manage media pH. Depending on the nutrients present, the media’s acidity or alkalinity can be adjusted to optimize plant growth. Risks of Ammoniacal Nitrogen: Plants can only absorb a certain amount of nitrogen at a time. However, they have the ability to store excess nitrogen for later use if needed. Nitrate (NO3) vs. Ammonium (NH4): Plants can safely store nitrate, but too much ammonium can harm cells. Thankfully, bacteria in the media convert urea and ammonium to nitrate, reducing the risk of ammonium buildup. Factors Affecting Ammonium (NH4) Levels: Certain conditions like low temperatures, waterlogged media, and low pH can prevent bacteria from converting ammonium. This can lead to toxic levels of ammonium in the media, causing damage to plant cells. Symptoms of Ammonium (NH4) Toxicity: Upward or downward curling of lower leaves depending on plant species; and yellowing between the veins of older leaves which can progress to cell death. Preventing Ammonium (NH4) Toxicity: When it comes to nitrogen breakdown of a nutrient solution, it’s crucial not to exceed 30% of the total nitrogen as ammoniacal nitrogen. Higher levels can lead to toxicity, severe damage, and even plant death. Ideal Nitrogen Ratio for Cannabis: Best Nitrogen (NO3) Ratio: Research shows that medical cannabis plants respond best to nitrogen supplied in the form of nitrate (NO3). This helps them produce more flowers and maintain healthy levels of secondary compounds. Safe Ammonium (NH4) Levels: While high levels of ammonium (NH4) can be harmful to cannabis plants, moderate levels (around 10-30% of the total nitrogen) are are considered most suitable. This level helps prevent leaf burn and pH changes in the media. Nitrogen: nitrate (NO3-) and ammonium (NH4+) Nitrogen is mobile in the plant. When it is in the soil it is mobile as Nitrate NO3– and is immobile as Ammonium NH4+ All those nutrients should be in ionic form, either in the soil or in a nutrient solution. Ions are simply the atomic or molecule form having +ve or –ve charge. As we know, the positive attracts the negative, and the same charge elements will repel each other; this power of charge represents the strength of the element. The positive ions are known as Cation, while negative ions are Anions. The anions want to disperse themselves to even concentrations, so they move from higher concentrations to lower concentrations. As we look at the soil structure, it’s a composition of particles; those particles attract the positive ions (+Ve), repel the Negative ions (-ve), and float freely in the water. This attraction of Cation by the soil particles is called Cation Exchange Capacity (CEC), which measures the number of cations that can be retained by the soil particles. The higher the CEC, the more Cation Nutrients can be stored in the soil. As a result, the higher CEC soils can become more nutrient-rich; also, keep in mind the soil composition is diverse and varies among different soil types.

Day37 05/08/24 Monday Feed today using de-chlorinated tap water pH 6. She has bounced back from topping so now applying LST this week. Day 39 07/08/24 Wednesday De-chlorinated tap water pH 6 today with calmag. Day 41 10/08/24 Saturday Feed today using de-chlorinated tap water pH 6 only. Day 42 11/08/24 Sunday End of week de-chlorinated tap water pH 6 with calmag. She has recovered well from topping and lst. Presenting a beautiful structure so far 😁 Picture and video update ✌️💚

Day 92 Day 42 Flower 02/08/24 Friday De-chlorinated tap water pH 6 only today full 5L with small run off. Day 93 Day 43 Flower 03/08/24 Saturday De-chlorinated tap water pH 6 today with Plagron products pk13-14 and Bud candy. Full 5L with small run off. Day 94 Day 44 Flower 04/08/24 Sunday De-chlorinated tap water pH 6 only today full 5L small run off. Really swelling the density is insane, even with a light press/squeeze the buds don't move 😍 Smells insane , lemon candy with a gassy cookie background , can't quite put my finger on it except the citrus lemon. Day 95 Day 45 Flower 05/08/24 Monday De-chlorinated tap water pH 6 today again only. Still getting about 10% run off. Day 96 Day 46 Flower 06/08/24 Tuesday De-chlorinated tap water pH 6 today again with Plagron products and Bud candy. Day 98 Day 48 Flower 08/08/24 Thursday (end of week) De-chlorinated tap water pH 6 today only. Full 5L, a little run off. She was thirsty.

Summer is happening at full speed so a short entry here. Getting close anyways so wont be too much to cover. 7/15/2024 Day 55 Temp: 70.3 F RH: 64.3% VPD: 0.89 kPa Plant #1 Height: 37” inches Plant #2 Height: 31” inches Light distance 10” & 16” I’m going to water 2.5 gallons an hour before the lights come on tonight I’ve already prepared my water jug with a half a teaspoon of bio-phos, about five ML actually put a little more of the elixir in today and then the Q so I put all those things in the water and will give it to him before the lights come back on. 7/17/2024 Day 57 Temp: 81.8 F RH: 63.7% VPD: 1.31 kPa Plant #1 Height: 37” inches Plant #2 Height: 31” inches Did some work in the tent to try and alleviate some of the heat stress. Bent over the main cola to even out the canopy. Fed the regular feeding and some Oly Mtn Fish Compost.

Summer is happening at full speed so a short entry here. Getting close anyways so wont be too much to cover. 7/15/2024 Day 55 Temp: 70.3 F RH: 64.3% VPD: 0.89 kPa Plant #1 Height: 37” inches Plant #2 Height: 31” inches Light distance 10” & 16” I’m going to water 2.5 gallons an hour before the lights come on tonight I’ve already prepared my water jug with a half a teaspoon of bio-phos, about five ML actually put a little more of the elixir in today and then the Q so I put all those things in the water and will give it to him before the lights come back on. 7/17/2024 Day 57 Temp: 81.8 F RH: 63.7% VPD: 1.31 kPa Plant #1 Height: 37” inches Plant #2 Height: 31” inches Did some work in the tent to try and alleviate some of the heat stress. Bent over the main cola to even out the canopy. Fed the regular feeding and some Oly Mtn Fish Compost.

will be harvesting soon

will be harvesting soon

Northern light is looking good. She has gotten acclimated, and has started making progress in the grow. I am not a expert in soil grows by any means. Keeping the wet to dry cycle right has been my biggest challenge in soil. She is looking fine, and everything is looking great so far. Nothing else to report at the moment. Thank you Medic Grow, Pro-mix, and Divine Seeds. 🤜🏻🤛🏻🌱🌱🌱 Thank you grow diaries community for the 👇likes👇, follows, comments, and subscriptions on my YouTube channel👇. ❄️🌱🍻 Happy Growing 🌱🌱🌱 https://youtube.com/channel/UCAhN7yRzWLpcaRHhMIQ7X4g

The ideal PPFD level for seedlings is between 100-300 micromoles per square meter per second (μmol/m²/s). This softer lighting mimics the diffused sunlight of early spring, providing enough energy for seedling-stage plants to develop their initial leaves without overwhelming them. at 48 inches from light sources, the seedlings receive around 150-180μmol/m²/s, as they grow they grow towards the higher levels of ppfd naturally. Urine is a liquid waste product as a result of our kidneys cleaning and filtering our blood. Typically, urine contains around 95% water and the rest are a mix of salts including sodium, potassium and chloride, urea, and uric acid. Due to the high water content in pee, the more you drink, the more you have to go. For a healthy person, human urine typically has a pH of around 6.2 with a range of 5.5-7.0. A person’s diet and alcohol consumption can also affect the pH of their urine. The main organic component of urine is urea, a combination of ammonia and carbon dioxide, which is the byproduct of our bodies breaking down proteins into usable amino acids. Urea is very high in nitrogen, a key ingredient to healthy leafy growth in plants. In addition to being very nitrogen-rich, urine also contains dissolved phosphorus that’s immediately available to plants, making urine a quick-acting fertilizer. Diesel exhaust fluid for motor engines is made up of 70% de-ionized water and 30% Urea. I didn't know that. Interesting stuff. If you own a dog, you may be familiar with yellow patches on your lawn where your pet has peed. Dogs and cats excrete fresh urine with a higher quantity of urea than humans do and that can more easily burn a plant upon contact. Human urine contains less urea and thus less ammonia. A novel electrochemically induced method for ammonia synthesis (eU2A) on demand from urea in alkaline media was demonstrated. A Nickel based electrode was employed as the active catalyst. The effective rate of ammonia generation of the eU2A process at 70◦C is ∼28 times higher than the thermal hydrolysis (THU) of urea. Despite Bear Grylls drinking urine in his popular survival shows, urine is not sterile. It picks up trace amounts of bacteria as the sterile version passes through the bladder, the urinary tract and comes in contact with the skin. Still, the health risks of using urine are very low because urine does not typically contain pathogens found in feces. Infectious diseases like cholera are spread through water sources contaminated by poop. In areas with poor sanitation, there is no way to separate solid and liquid waste which is why all untreated mixed sewage can pose significant public health risks. Only 10-15% of all nutrition you ingest is absorbed, all the rest is disposed of in the urea of urine, 95% Water, 5% Urea. Human urine consists primarily of water (91% to 96%), with organic solutes including urea, creatinine, uric acid, and trace amounts of enzymes, carbohydrates, hormones, fatty acids, pigments, and mucins, and inorganic ions such as sodium (Na+), potassium (K+), chloride (Cl-), magnesium (Mg2+), calcium (Ca2+), ammonium (NH4+), sulfates (SO42-), and phosphates (e.g., PO43-).1 A Representative Chemical Composition of Urine Water (H2O): 95% Urea (H2NCONH2): 9.3 g/l to 23.3 g/l Chloride (Cl-): 1.87 g/l to 8.4 g/l Sodium (Na+): 1.17 g/l to 4.39 g/l Potassium (K+): 0.750 g/l to 2.61 g/l Creatinine (C4H7N3O): 0.670 g/l to 2.15 g/l Inorganic sulfur (S): 0.163 to 1.80 g/l The pH of human urine ranges from 5.5 to 7, averaging around 6.2. The specific gravity ranges from 1.003 to 1.035. Significant deviations in pH3 Chemical Concentration in g/100 ml urine Water 95 Urea 2 Sodium 0.6 Chloride 0.6 Sulfate 0.18 Potassium 0.15 Phosphate 0.12 Creatinine 0.1 Ammonia 0.05 Uric acid 0.03 Calcium 0.015 Magnesium 0.01 The element abundance depends on diet, health, and hydration level, but human urine consists of approximately: Oxygen (O): 8.25 g/l Nitrogen (N): 8/12 g/l Carbon (C): 6.87 g/l Hydrogen (H): 1.51 g/l Morning piss is best, diluted to 6-10 parts water. Breaking Down Nitrogen Forms & Their Impact: Forms of Nitrogen: Nitrogen, comes in three primary forms: ammonium, nitrate, and urea. Ammonium (NH4+) carries a positive charge, nitrate (NH3–)carries a negative charge, while urea ((NH2)2CO) carries no charge. Natural Processes in Media: Once these nitrogen forms are introduced into the growing media, natural processes kick in. Bacteria play a vital role, converting urea to ammonium or ammonium to nitrate. This latter conversion releases hydrogen ions, increasing media acidity. Urea Conversion: Urea undergoes rapid conversion to ammonium in the soil, usually within two days. Both urea and ammonium are often grouped together and referred to as ammoniacal nitrogen. When plants absorb nitrogen, they typically release a molecule with the same charge to maintain internal pH. This process can also alter the pH of the media surrounding the roots. pH Effects of Nitrogen Uptake: Ammonium (NO4) Uptake and pH: When plants absorb ammonium, they release hydrogen ions (H+) into the media. This increases the acidity of the media over time, decreasing the pH. Nitrate (NO3) Uptake and pH: Plants take up nitrate by releasing hydroxide ions (OH–). These ions combine with hydrogen ions to form water. The reduction in hydrogen ions eventually reduces the media acidity increasing the pH. Nitrate (NO3) Absorption Variations: Sometimes, plants absorb nitrate differently, either by taking in hydrogen ions or releasing bicarbonate. Like hydroxide ions, bicarbonate reacts with hydrogen ions and indirectly raises the media pH. Understanding these processes helps in choosing the appropriate fertilizer to manage media pH. Depending on the nutrients present, the media’s acidity or alkalinity can be adjusted to optimize plant growth. Risks of Ammoniacal Nitrogen: Plants can only absorb a certain amount of nitrogen at a time. However, they have the ability to store excess nitrogen for later use if needed. Nitrate (NO3) vs. Ammonium (NH4): Plants can safely store nitrate, but too much ammonium can harm cells. Thankfully, bacteria in the media convert urea and ammonium to nitrate, reducing the risk of ammonium buildup. Factors Affecting Ammonium (NH4) Levels: Certain conditions like low temperatures, waterlogged media, and low pH can prevent bacteria from converting ammonium. This can lead to toxic levels of ammonium in the media, causing damage to plant cells. Symptoms of Ammonium (NH4) Toxicity: Upward or downward curling of lower leaves depending on plant species; and yellowing between the veins of older leaves which can progress to cell death. Preventing Ammonium (NH4) Toxicity: When it comes to nitrogen breakdown of a nutrient solution, it’s crucial not to exceed 30% of the total nitrogen as ammoniacal nitrogen. Higher levels can lead to toxicity, severe damage, and even plant death. Ideal Nitrogen Ratio for Cannabis: Best Nitrogen (NO3) Ratio: Research shows that medical cannabis plants respond best to nitrogen supplied in the form of nitrate (NO3). This helps them produce more flowers and maintain healthy levels of secondary compounds. Safe Ammonium (NH4) Levels: While high levels of ammonium (NH4) can be harmful to cannabis plants, moderate levels (around 10-30% of the total nitrogen) are are considered most suitable. This level helps prevent leaf burn and pH changes in the media. Nitrogen: nitrate (NO3-) and ammonium (NH4+) Nitrogen is mobile in the plant. When it is in the soil it is mobile as Nitrate NO3– and is immobile as Ammonium NH4+ All those nutrients should be in ionic form, either in the soil or in a nutrient solution. Ions are simply the atomic or molecule form having +ve or –ve charge. As we know, the positive attracts the negative, and the same charge elements will repel each other; this power of charge represents the strength of the element. The positive ions are known as Cation, while negative ions are Anions. The anions want to disperse themselves to even concentrations, so they move from higher concentrations to lower concentrations. As we look at the soil structure, it’s a composition of particles; those particles attract the positive ions (+Ve), repel the Negative ions (-ve), and float freely in the water. This attraction of Cation by the soil particles is called Cation Exchange Capacity (CEC), which measures the number of cations that can be retained by the soil particles. The higher the CEC, the more Cation Nutrients can be stored in the soil. As a result, the higher CEC soils can become more nutrient-rich; also, keep in mind the soil composition is diverse and varies among different soil types.

Trying to tuck these huge fan leaves to expose the branches to get som growth the leaves were too big and blocking all the sites but man these plants are exploding on these self watering bases from ac infinity ️

Trying to tuck these huge fan leaves to expose the branches to get som growth the leaves were too big and blocking all the sites but man these plants are exploding on these self watering bases from ac infinity ️

Note: jegliches Equipment findet ihr in der Germinations Woche . Day 22: PPFD 410 * 20h = DLI 29.52 Day 23: Day 24: + Dünger + + 0.5 Flaschenwasser + + + Rhizotonic + + + Terra Vega + + 0.6 Leitungswasser + final PH 6.5 Day 25: Day 26: Day 27: + Flaschenwasser 2.5 L (PH 7.2 EC 0.26) + + CanaCym + Final PH 6.1 = Drain : EC 1.325 Sieht bissel danach aus als hab ich etwas zuviel Urgesteinsmehr in die Erde eingearbeitet :)) Muss ich halt bissel spaarsamer mit der Düngung umgehen . Day 28: Das Wetter und die liebe Luftfeuchtigkeit :(( Manchmal denk ich das ich Outdoor growe :)) Im Video sieht man schön wie der kleine Zwerk sich selber mit seinen riesen Blättern SCROG mäßig den Wuchs in die Breite erzwingt :)) Die Blütentriebe müssen halt den Weg zum Licht mit aller Anstrengung erreichen .

Note: jegliches Equipment findet ihr in der Germinations Woche . Day 22: PPFD 410 * 20h = DLI 29.52 Day 23: Day 24: + Dünger + + 0.5 Flaschenwasser + + + Rhizotonic + + + Terra Vega + + 0.6 Leitungswasser + final PH 6.5 Day 25: Day 26: Day 27: + Flaschenwasser 2.5 L (PH 7.2 EC 0.26) + + CanaCym + Final PH 6.1 = Drain : EC 1.325 Sieht bissel danach aus als hab ich etwas zuviel Urgesteinsmehr in die Erde eingearbeitet :)) Muss ich halt bissel spaarsamer mit der Düngung umgehen . Day 28: Das Wetter und die liebe Luftfeuchtigkeit :(( Manchmal denk ich das ich Outdoor growe :)) Im Video sieht man schön wie der kleine Zwerk sich selber mit seinen riesen Blättern SCROG mäßig den Wuchs in die Breite erzwingt :)) Die Blütentriebe müssen halt den Weg zum Licht mit aller Anstrengung erreichen .

Note: jegliches Equipment findet ihr in der Germinations Woche . Day 22: PPFD 410 * 20h = DLI 29.52 Day 23: Day 24: + Dünger + + 0.5 Flaschenwasser + + + Rhizotonic + + + Terra Vega + + 0.6 Leitungswasser + final PH 6.5 Day 25: Day 26: Day 27: + Flaschenwasser 2.5 L (PH 7.2 EC 0.26) + + CanaCym + Final PH 6.1 = Drain : EC 1.325 Sieht bissel danach aus als hab ich etwas zuviel Urgesteinsmehr in die Erde eingearbeitet :)) Muss ich halt bissel spaarsamer mit der Düngung umgehen . Day 28: Das Wetter und die liebe Luftfeuchtigkeit :(( Manchmal denk ich das ich Outdoor growe :)) Im Video sieht man schön wie der kleine Zwerk sich selber mit seinen riesen Blättern SCROG mäßig den Wuchs in die Breite erzwingt :)) Die Blütentriebe müssen halt den Weg zum Licht mit aller Anstrengung erreichen .

Dos-Si-Dos auto is growing good. Her roots are about ready to get into the solution in next day or 2. She is looking healthy, and off to a great start. She will be up for training likely by next update. Everything is looking great. Thank you Athena, Medic Grow, and Zamnesia seeds. 🤜🏻🤛🏻🌱🌱🌱 Thank you grow diaries community for the 👇likes👇, follows, comments, and subscriptions on my YouTube channel👇. ❄️🌱🍻 Happy Growing 🌱🌱🌱 https://youtube.com/channel/UCAhN7yRzWLpcaRHhMIQ7X4g

Week 21 and 3

Week 21 and 3

If you have been following my diary, you may know I appear to have an auto that started flowing during an 18 hour light schedule. Although the package came as a cookies gelato feminized seed (not an auto) but all indication sure appears to be an auto. Just an added bonus for a quick harvest, no complaints and love the looks of the genetics on the cookies gelato.