Week 3 (April 12-18th) At this point I was using water and a small amount of coffee grounds. Spent a lot of time talking and singing to the plant. The leaves got bigger and formed quickly this week. If you look at the different days you can clearly see how big the plant was getting.

Week 1 of flower is finally here. Tons of growth! One more foliar application of Chitosal this Saturday. These plants need a thorough cleaning underneath at the two week point to allow flower initiation without stress. I will be watching closely for deficiencies in laughing Buddha and blueberry. With the size of the plants a heavy feed schedule might not satisfy requirements. I see a noticeable increase in the quality of plant growing directly under the Hortilux in comparison to the mars hydro supplemental lighting. I am debating adding flora nectar to my nutrient regiment to help in the flavour profiles. I have recently added terpinator from Rhizoflora to increase resin glands on bud structure. I can’t wait to see flowers develop, am hoping for a heavy yield from laughing Buddha and blueberry

Still growing like a beast. I did raise the light a little. I feel like the taller one that got fed BLOOM at the beginning of the week is a bit darker green than the other one. It also showed a slight amount of possible N burn/deficiency on a couple of leaves. Everything else is looking great. I did try to adjust some of the tie downs a little to open her up a bit more

Little bit of heat stress, turned led back to 80%

I'm back and since the gorilla glues have been harvested this girl is taking her time and what a yield she's gonna give grandmommy purple

Week 12 13 December 2023 Heya👍🤙👍🌱 Thanks for reading!!!🤙👍🤙🌱

Harvest time!

Welcome back in the 8th week of flowering with Dutch Passion’s Brooklyn Sunrise. The one in the front is ripening good, buds are rock solid and covered in trichomes, such a beauty. The smell is surprising, in the first weeks flowering she had more of a diesel kind of smell but it turned its self totally around, the smell reminds me of sour candy, an extremely sweet smell which I didn’t expect but its even better than I expected. Last Sunday I gave the one in the front her the last bits of nutrients, so this week is flushing till Sunday, Sunday will be harvest day!! I noticed that since last weeks some leaves and buds are turning purple, I didn’t even know these have purple in them as well of all the journals that I checked out to see what was up with this strain and what to expect, not a single one had purple in them so I guess I have had a different pheno. Such a beauty to see with all the colors. Cant wait to have a taste! After the one in the front is cut down ill let the other 2 stay in there with the other 2 Cookies for at least 1 week maybe 2 but im not sure. My next grow will take place first or second week of December, in the meantime I will chooce a new strain to grow and prepare the next grow. This time I will perfom my first real ScrOG and combine it with the airdome underneath my pot (they say you can improves your yield by 20-30%). So it got my attention and im very curious about the results. That’s it for now see you all back on Sunday harvest day!!

As altas temperaturas arruinaram a colheita, as plantas estão sem cheiro a WW#1 foi a mais resistente ao calor, ainda exala um aroma muito bom, porem as outras plantas sofreram mais, a C99xBB#1 perdeu totalmente o cheiro, e nasceram novos pistilos diminuindo a densidade das flores.

It is a vigorous plant with very uniform branching, high resinous and high yield, if you grow from seed there are a few different phenos that I got, equally as good

Day 66, she continues the very healthy flowering 🙌 size 80 cm👏🏻👏🏻 temperature 24º C ☀️, humidity 60% 💧 watering 750 ml alternating one day with nutrients and another without nutrients with osmotized water 💦💦 Session 45 min. of binaural sounds for growth and healing 🎼 and music 😉👍

Put a lot of love into this grow. She grew for 4 months from seeds to harvest. About 5 weeks and 56 days of flower. Overall great strain to grow and great site @growdiaries for giving the platform and help from other growers. I’ve learned so much about growing and especially about this strain.

Week 7 of flower,room a bit cold but they are close to havest.

Almost finished, flushing 10% discount on Zamnesia seeds with code GROWITGD

1st day of week 4 Mixed the Soil mix that will be feeding these girls throughout the rest of their lives. Will let it rest for 1-2 weeks before selecting the final top 4 to go into the 10 gallon pots. Water fed 2 cups of plain water to all today Rolled lighting schedule back to 16-8. Getting my girls 8 hours of sleep a night Increased light intensity to 550 W Day 23 Water fed 2 cups of water with silica added Foliar fed with fish fertilizer and silica Day 24 Water fed with water + mychoriza + beneficial bacteria Day 25 Pruned lower leaves and nodes as needed for better air flow and light penetrative. Gotta get these girls to put all their focus in cranking out new nodes now for the next few weeks to fill up the tent space for flowering. Looking for the top 4 with the most impressive smell, vigor and structure Also water fed 2 cups each again today. They are needing fed every day almost now cause they are out growing the 1 gal pots. Transplanting will need to happen within the next fee days. Day 26 Eliminated 1 Kosher Kush and 1 Double Stuffed Sorbet transplanted last half gallon pot (Blueberry 6) water fed 1 cup of water to all foliar fed with fish fert + cal mag Last day of week 4: I fed 1 cup of water and then super cropped most. Some got LST stakes. Kind of had a little regret after super cropping most. Next run I will do zero lst or hst training. Just grow them to 24 inches (6 weeks) then move to final pots and put in trellis net 12" over top of pot thereby allowinh the the trellis net to gently fold over the top 8-12" of the plants, creating the same training effect but with no stalling of growth. Train them into the net for final 2 weeks of veg and for the 1st week or 2 of flowering.

De nuevo traigo otra semana de estas green poison segunda de floración. Sweetseeds hizo un gran trabajo en su día trabajando esta variedad. Resistente, vigorosa, y veréis que flores que tiran, están tan bien ramificadas que los laterales están a la altura de la puntas. . La humedad esta al 45% la temperatura está entre 21/24 grados , y como siempre el ph , ya que es de lo más importante,está en 5,8/6,0. . AgroBeta: 0,5 ml x L Flowering black line , vía radicular. 0,2 ml x L Beta shark, vía radicular. 0,3 ml x L Tucán , vía radicular. 0,8 ml x L Génesis, vía radicular. 0,1 ml x L Betazyme, vía radicular. 0,2 ml x L Flash Root , vía radicular. 0,05 ml x L Gold Joker, vía radicular. 0,2 ml x L Silver, vía radicular. . Hasta aquí todo gente, espero que os guste lo que veía, un saludo y buenos humos fumetillas💨💨💨.

The drying took 2 weeks, but well worth the wait.

So the Cal-mag issue in AK was held back for a while, but now in week 4, its pretty clear that is the problem with her. Watered her with a full 5ml dose mixed in a 1 liter bottle, pHed to 6.8 on monday. Now im just watching the progression. Not sure i logged it, but i watered her with a quarter strength dose of the same stuff two weeks ago. No Urb this week, or Big Bloom. All other plants are doing just dandy. There's been a progression in fungus gnat appearances in both my closet space, and tent. Im planning on drying out the soil in all of my plants in both grow spaces, down to about 1 12 inch from topsoil, so i can apply some Diatomaceous Earth. Other than all that, all of my candidate plants are doing awesome! Ak began to produce a noticeable stench around saturday last weekend. Kind of reminds me of grape skittles. Sour Ripper isnt producing much of a scent yet, but she's definitely in the bud-building mode. Buds are developing at an equal rate to AK48. I can tell she's going to burst in growth in about a week or so. I've ceased ALL training as of last week on thursday. Did minor lollipopping and defoliation on all of my candidate plants needing it. The plants are pretty damn short. But thats fine as im planning to do a perpetual cycle soon - plus, ive got taller girls vegging out in my tent. Also got a Candy Cream (Seedsman) mother in there too. Stay tuned for that journal in the near future. ;) Heres to being halfway there everybody! Cheers

Seedling managing 93F 30%RH, around 20 DLI. Vpd is in the 3's. No I don't recommend. Signum Magnum. "A great sign appeared in the sky a woman clothed with the sun with the moon under her feet and on her head a crown of twelve stars. Sing ye to the Lord a new canticle: because He has done wonderful things. Glory to the Father, and to the Son, and to the Holy Spirit As it was in the beginning, and now, and ever shall be, world without end." The plant nutrient nitrogen exists in forms with both positive and negative charges. Ammonium (NH4+)(immobile in soil)(Cation) has a positive charge, while nitrate (NO3-) (highly mobile in soil)(Anion)has a negative charge. Nitrogen is unique among plant nutrients in that it can exist in both positively charged (ammonium, NH₄⁺) and negatively charged (nitrate, NO₃⁻) forms in the soil. This makes it a special nutrient. In that it is responsible for providing balance for reactionary trade offs when it comes to ph. Because ph itself in the medium will always slowly drift towards acidicity, such is nature. 80% of nitrogen should be nitrate and no more than 20% ammoniacal nitrogen. Ca, mg, and K are the big 3 cations related to soil composition, pH & base saturation. When nitrogen is in the form of ammonium, it can compete with calcium, magnesium, and potassium for absorption sites in the plant root. This competition can lead to a reduction in the uptake of these other essential nutrients. Nitrogen, particularly in its nitrate form (NO3-), can increase soil acidity, which can also affect the availability of calcium, magnesium, and potassium. The form of nitrogen applied (ammonium vs. nitrate) can influence its interactions with other nutrients. Ammonium nitrogen can have a more pronounced negative effect on the uptake of calcium, magnesium, and potassium compared to nitrate nitrogen. Common forms of ammonium nitrogen include ammonium ion (NH4+), urea, and ammonium compounds like ammonium nitrate, ammonium sulfate, and ammonium phosphate. Common forms of nitrate nitrogen include potassium nitrate (KNO3), sodium nitrate (NaNO3), calcium nitrate (Ca(NO3)2), and ammonium nitrate (NH4NO3). Phosphorus is an essential plant nutrient, and its availability in the soil is strongly linked to the presence of oxygen. Plants primarily absorb phosphorus as phosphate (PO4), and oxygen is a key component of this molecule. Furthermore, the availability of phosphorus in the soil can be impacted by factors like soil aeration and temperature, which in turn affect the oxygen supply to the roots. Phosphorus uptake in plants is most critical during the early stages of growth, particularly within the first few weeks of plant development. Young plants actively growing tissues have a high demand for phosphorus. They may absorb up to 75% of their total phosphorus requirements within the first few weeks of vegetative growth, with up to 51% of uptake happening overnight, primarily in the first few hours or early nightfall. ⑨Anaerobic root respiration, or respiration without oxygen, is detrimental to plants because it's less efficient and produces toxic byproducts, leading to reduced energy production, nutrient uptake issues, and ultimately, root damage and plant stress. ⑨Anaerobic respiration, unlike aerobic respiration, doesn't utilize oxygen as the final electron acceptor in the electron transport chain. This results in a significant drop in the amount of energy (ATP) produced, which is necessary for various plant functions, including growth, nutrient uptake, and maintenance of cellular processes. ⑨In the absence of oxygen, plants produce byproducts like ethanol and lactic acid during anaerobic fermentation. These byproducts can be toxic to the roots and inhibit their function, ⑨When oxygen is depleted in a medium, the pH tends to decrease (become more acidic) due to the production of metabolic byproducts. This is particularly relevant in biological systems where aerobic respiration relies on oxygen as the final electron acceptor. ⑨When oxygen is scarce, plants may switch to anaerobic respiration. This process produces carbon dioxide (CO2) as a byproduct. ⑨CO2 dissolves in water to form carbonic acid (H2CO3). This acid lowers the pH of the medium, making it more acidic. ⑨Anaerobic conditions can impair a plant's ability to regulate its internal pH, leading to a drop in cytoplasmic pH and potentially cellular acidosis. ⑨The change in pH can also affect the availability of certain nutrients to the plant, as pH influences the solubility of micronutrients like iron, manganese, zinc, copper, and boron. ⑨The lack of oxygen in the plant medium leads to a decrease in pH due to the production of carbon dioxide during anaerobic respiration and impaired pH regulation within the plant. In plant cells, cellular acidosis, a drop in the internal pH of the cytosol, is a significant stress response, particularly during conditions like flooding or hypoxia. This acidification can be triggered by a decrease in oxygen levels, leading to the production of metabolic byproducts like lactic acid and CO2. The plant's ability to tolerate and recover from these conditions depends on its cellular mechanisms to regulate pH and mitigate the effects of acidosis. When plants are subjected to low oxygen environments, such as those experienced during flooding, anaerobic metabolism, which produces lactic acid and ethanol, becomes the primary source of energy. This can lead to a build-up of these acidic metabolites in the cytosol, causing a drop in pH. OXYGEN Atomic oxygen (single oxygen atom, O) is the lightest form of oxygen, as it has the lowest mass of the oxygen molecules. Oxygen also exists as a diatomic molecule (O2) and an allotrope called ozone (O3), which have higher masses due to the number of oxygen atoms combined. Atomic Oxygen (O): This refers to a single oxygen atom, which is the most fundamental form of oxygen. Molecular Oxygen (O2): This is the common form of oxygen we breathe, consisting of two oxygen atoms bonded together. Ozone (O3): This is an allotrope of oxygen, meaning it's a different form of the same element, consisting of three oxygen atoms bonded together. Since atomic oxygen has the fewest oxygen atoms, it naturally has the lowest mass compared to O2 or O3. Ozone (O3) Lifespan: Ozone has a relatively long lifespan in the stratosphere, particularly at lower altitudes. For example, at 32 km in the middle latitudes during spring, ozone has a lifetime of about 2 months. Oxygen (O) Lifespan: Atomic oxygen, on the other hand, has a much shorter lifespan. At the same altitude, its lifetime is about 4/100ths of a second. Ozone-Oxygen Cycle: The ozone-oxygen cycle involves the rapid exchange between atomic oxygen (O) and ozone (O3). UV radiation can split molecular oxygen (O2) into atomic oxygen (O), which then reacts with O2 to form ozone (O3). Ozone can also be photolyzed by UV radiation, creating atomic oxygen again, which can then react with O3 to reform O2. Dominant Form: The partitioning of odd oxygen (Ox) between ozone and atomic oxygen favors ozone in the lower stratosphere. This means that a much larger proportion of odd oxygen exists as ozone than as atomic oxygen, especially in the lower stratosphere. Recombination: Atomic oxygen has a high energy and reactivity. When it encounters another oxygen atom, they can combine to form O2. This process releases energy, contributing to the heating of the atmosphere. Ozone Formation: Atomic oxygen can also react with molecular oxygen (O2) to form ozone (O3). Ozone plays a significant role in absorbing harmful UV radiation. Other Reactions: Atomic oxygen can react with various other molecules in the atmosphere, like nitrogen (N2), water (H2O), and carbon dioxide (CO2), forming different compounds. UV light below 240nm (peak 185nm) creates ozone (O₃) through a process called photolysis, where UV light breaks down dioxygen molecules (O₂) into single atomic oxygen atoms (O). These single oxygen atoms then react with other oxygen molecules to form ozone (O₃). Specifically, UV-C light with wavelengths shorter than 240 nm can cause this photolysis. UV light with wavelengths between 240-280 nm, (peak 254 nm) breaks down ozone (O₃) into dioxygen molecules (O₂) and atomic oxygen atoms (O). 280nm does not have the energy potential to break apart the stable bond of (O₂) into enough (O) to make (O₃) At ground level, atomic oxygen (single oxygen atoms) has a very short lifespan. This is because it's highly reactive and quickly combines with other molecules to form stable diatomic oxygen (O2) or other compounds. While the exact timeframe varies depending on the specific circumstances, its lifespan is typically measured in nanoseconds or picoseconds.