whatever it is, it's a pity, but you can't fight with Nature :) as far as I can see from the drone flight, the girls are simply gone :D:D they are under water,.... it's a pity.... it rained a lot during the week, there is a river 300m away which flooded, here is the result: D I see this for the first time in 9 years .... well, nothing new automatic seeds, already thrown into the ground :) so I will wait for new girls :).

They took a while but they all popped out!

All details will be added every day/week if u have any questions feel free to ask. December 4th:starting in the winter, veg and bloom will happen under 400watt hps to keep the grow room warm. the seeds have been germinating for 2 days with the wet paper towel technique, they got root and are now in soil and the rockwool cube. for now im just waiting for the seeds to show root coming out of the rockwool, then i transplant to the netpot with clay pellets straight in the dwc, untill then they get fluorescent light (max 7 days) these are autoflowers so they get 18 or 20 hours light. nutrients General hydroponics three part :micro gro bloom and calmag water: rainwater (25ppm) i hope the room wont cool of too much when the lights go out. Day 1 (December 5) seeds start to come above the rockwool and the soil Day 2 (december 6) stems start to stretch i give them both pure rain water with 100ppm calmag when they feel dry. Day 4 (december 8) still no root visible out of the rockwool Day 5 (december 9) root visible outside of rockwool cube and transplant to the 55Liter rdwc air pumps 10l/minute Day 7 (december 11) root comes trough netpot, i lowered the water by removing 3Liters

15.04.22 Полив 1 литр раствора Рипена 4 мл/л 17.04.22 Полив 1 литр раствора Рипена 4 мл/л 19.04.22 Полив расвором рипена: 2 литра талой воды + 8 мл Ripen Следующий полив водой, вымываем вкус удобрений( в итоге не стал этого делать, а закончил рипеном). Далее - темнота и харв =) 13 неделя завершена.

So i flushed all old nutrients out and switched over directly to ripen, now they finish up in the coming 14 days

So meine kleine Kofferprinzessin befindet sich nun in der zweiten Blütewoche (im Video sage ich Growwoche, das ist natürlich quatsch) und ich glaub alles ist soweit gut. Ich habe die kleine ein bisschen mit Draht von der Lampe weggebogen und hoffe das hilft irgendwie. PS Ich benutz nie wieder so n whackn Growkoffer :/

Start of week 9. Buds are filling out nicely, but trichomes are still mostly clear. Breeder says 8-10 weeks so im hoping they are ready in the next week. Both are starting to show a little bit of the leaves fading, not sure if its normal or the start of some sort of deficiency. Super strong smell on both phenos. I was expecting alot more in terms of weight but the quality dies look great. Cant wait! 💨💨

Well once again I’m blown away with the genetics from Fastbuds. I only wish I had more room for them to really grow. I’m growing Fastbuds Smoothie outside and hoping that’s going to thrive in lots of space. Anyway the Cali Snow is smelling divine and really stacking up nicely. The grapefruit continues to fatten up and smells just like over ripe grapefruit. Very acidic almost gassy. The grapefruit is a lot small so yield might be down but quality over quantity win some for me. 👊✌️🏻💚

Привет садоводы процес вегитации идет полным ходом и цветку понадобится много времени , что-бы вырасти до хороших размеров поэтому будем наблюдать, как пойдут дела

Overall this grow went very smooth and the purple punch bud is top 3 of the best home grown indoor I have ever smoked very impressed with the insane terps and heavy effects she brings to my table ,I am 100% going to be growing much more purple punch autos in the future

Amazing week for this monster ladies! I do some LST on them and they bounce back so quickly no any issues with them and I will may be keep them two or three more weeks in grow for greater yield! Stay tuned 😁✌️💚🌿😜

Flip day for the Persian, she's looking good, just hope I can keep her short enough for my tent🤞🏻

D29/V25 - 29/04/23 - Benting D30/V26 - 30/04/23 - EC 0.9 pH 6.5 D31/V27 - 01/05/23 - LST and Benting D32/V28 - 02/05/23 - Some other LST D33/V29 - 03/05/23 - Added water and nutes - EC=0,9 pH=6,5 D34/V30 - 04/05/23 - LST D35/V31 - 05/05/23 - Nothing

summer has arrived in germany. the little one likes it very much. she is reaching out for the sun's rays to grow. she is doing well so far and i am confident that she will really step on the gas in the next few weeks.

All getting super frosty and stacking up

Hey everyone 😊. Both phenotypes do very well and both look beautiful 😍. Again two super genetics from Sweet Seeds 👍. Let's start with the weekly overview: Flowering day 15 Today both were carefully checked for health and sprayed with Canna Cure. Flowering day 16 Today both were poured with 1 l each. The tent was cleaned and fresh osmosis water was filled into the tank. Flowering day 17 Both were sprayed with canna cure and checked for health. Flowering day 18 Today both were once again poured with 1 liter because they are very thirsty 😃. and like every day they were checked for their health. Flowering day 19 Today there was nothing to be done except to fill the humidifier :-). Flowering day 20 Today both were lifted out of their pots and the roots on the root ball checked, everything was great ☺️👍. For this purpose, the plants were sprayed with Canna Cure. Flowering day 21 to the At the end of the week, another 0.8 l was poured per plant :-). Both checked for health, and the humidifier refilled. I wish you all the best until the next update, stay healthy and let it grow 🙏🏻👌. You can buy this Strain at : https://sweetseeds.es/de/cream-caramel/ Type: Cream Caramel ☝️🏼 Genetics: Blue Black x Maple Leaf Indica x White Rhino 👍 Vega lamp: 2 x Todogrow Led Quantum Board 100 W 💡 Bloom Lamp : 2 x Todogrow Led Cxb 3590 COB 3500 K 205W 💡💡☝️🏼 Soil : Canna Coco Professional + ☝️🏼 Fertilizer: Green House Powder Feeding ☝️🏼🌱 Water: Osmosis water mixed with normal water (24 hours stale that the chlorine evaporates) to 0.2 EC. Add Cal / Mag to 0.4 Ec Ph with Organic Ph - to 5.5 - 5.8 .

Knocked out lot's of friends ;) my favorite strain...easy to grow!!! She took high EC levels...heavy smell :PPP very very heavy :P

What's in the soil? What's not in the soil would be an easier question to answer. 16-18 DLI @ the minute. +++ as she grows. Probably not recommended, but to get to where it needs to be, I need to start now. Vegetative @1400ppm 0.8–1.2 kPa 80–86°F (26.7–30°C) 65–75%, LST Day 10, Fim'd Day 11 CEC (Cation Exchange Capacity): This is a measure of a soil's ability to hold and exchange positively charged nutrients, like calcium, magnesium, and potassium. Soils with high CEC (more clay and organic matter) have more negative charges that attract and hold these essential nutrients, preventing them from leaching away. Biochar is highly efficient at increasing cation exchange capacity (CEC) compared to many other amendments. Biochar's high CEC potential stems from its negatively charged functional groups, and studies show it can increase CEC by over 90%. Amendments like compost also increase CEC but are often more prone to rapid biodegradation, which can make biochar's effect more long-lasting. biochar acts as a long-lasting Cation Exchange Capacity (CEC) enhancer because its porous, carbon-rich structure provides sites for nutrients to bind to, effectively improving nutrient retention in soil without relying on the short-term benefits of fresh organic matter like compost or manure. Biochar's stability means these benefits last much longer than those from traditional organic amendments, making it a sustainable way to improve soil fertility, water retention, and structure over time. Needs to be charged first, similar to Coco, or it will immobilize cations, but at a much higher ratio. a high cation exchange capacity (CEC) results in a high buffer protection, meaning the soil can better resist changes in pH and nutrient availability. This is because a high CEC soil has more negatively charged sites to hold onto essential positively charged nutrients, like calcium and magnesium, and to buffer against acid ions, such as hydrogen. EC (Electrical Conductivity): This measures the amount of soluble salts in the soil. High EC levels indicate a high concentration of dissolved salts and can be a sign of potential salinity issues that can harm plants. The stored cations associated with a medium's cation exchange capacity (CEC) do not directly contribute to a real-time electrical conductivity (EC) reading. A real-time EC measurement reflects only the concentration of free, dissolved salt ions in the water solution within the medium. 98% of a plants nutrients comes directly from the water solution. 2% come directly from soil particles. CEC is a mediums storage capacity for cations. These stored cations do not contribute to a mediums EC directly. Electrical Conductivity (EC) does not measure salt ions adsorbed (stored) onto a Cation Exchange Capacity (CEC) site, as EC measures the conductivity of ions in solution within a soil or water sample, not those held on soil particles. A medium releases stored cations to water by ion exchange, where a new, more desirable ion from the water solution temporarily displaces the stored cation from the medium's surface, a process also seen in plants absorbing nutrients via mass flow. For example, in water softeners, sodium ions are released from resin beads to bond with the medium's surface, displacing calcium and magnesium ions which then enter the water. This same principle applies when plants take up nutrients from the soil solution: the cations are released from the soil particles into the water in response to a concentration equilibrium, and then moved to the root surface via mass flow. An example of ion exchange within the context of Cation Exchange Capacity (CEC) is a soil particle with a negative charge attracting and holding positively charged nutrient ions, like potassium (K+) or calcium (Ca2+), and then exchanging them for other positive ions present in the soil solution. For instance, a negatively charged clay particle in soil can hold a K+ ion and later release it to a plant's roots when a different cation, such as calcium (Ca2+), is abundant and replaces the potassium. This process of holding and swapping positively charged ions is fundamental to soil fertility, as it provides plants with essential nutrients. Negative charges on soil particles: Soil particles, particularly clay and organic matter, have negatively charged surfaces due to their chemical structure. Attraction of cations: These negative charges attract and hold positively charged ions, or cations, such as: Potassium (K+) Calcium (Ca2+) Magnesium (Mg2+) Sodium (Na+) Ammonium (NH4+) Plant roots excrete hydrogen ions (H+) through the action of proton pumps embedded in the root cell membranes, which use ATP (energy) to actively transport H+ ions from inside the root cell into the surrounding soil. This process lowers the pH of the soil, which helps to make certain mineral nutrients, such as iron, more available for uptake by the plant. Mechanism of H+ Excretion Proton Pumps: Root cells contain specialized proteins called proton pumps (H+-ATPases) in their cell membranes. Active Transport: These proton pumps use energy from ATP to actively move H+ ions from the cytoplasm of the root cell into the soil, against their concentration gradient. Role in pH Regulation: This active excretion of H+ is a major way plants regulate their internal cytoplasmic pH. Nutrient Availability: The resulting decrease in soil pH makes certain essential mineral nutrients, like iron, more soluble and available for the root cells to absorb. Ion Exchange: The H+ ions also displace positively charged mineral cations from the soil particles, making them available for uptake. Iron Uptake: In response to iron deficiency stress, plants enhance H+ excretion and reductant release to lower the pH and convert Fe3+ to the more available form Fe2+. The altered pH can influence the activity and composition of beneficial microbes in the soil. The H+ gradient created by the proton pumps can also be used for other vital cell functions, such as ATP synthesis and the transport of other solutes. The hydrogen ions (H+) excreted during photosynthesis come from the splitting of water molecules. This splitting, called photolysis, occurs in Photosystem II to replace the electrons used in the light-dependent reactions. The released hydrogen ions are then pumped into the thylakoid lumen, creating a proton gradient that drives ATP synthesis. Plants release hydrogen ions (H+) from their roots into the soil, a process that occurs in conjunction with nutrient uptake and photosynthesis. These H+ ions compete with mineral cations for the negatively charged sites on soil particles, a phenomenon known as cation exchange. By displacing beneficial mineral cations, the excreted H+ ions make these nutrients available for the plant to absorb, which can also lower the soil pH and indirectly affect its Cation Exchange Capacity (CEC) by altering the pool of exchangeable cations in the soil solution. Plants use proton (H+) exudation, driven by the H+-ATPase enzyme, to release H+ ions into the soil, creating a more acidic rhizosphere, which enhances nutrient availability and influences nutrient cycling processes. This acidification mobilizes insoluble nutrients like iron (Fe) by breaking them down, while also facilitating the activity of beneficial microbes involved in the nutrient cycle. Therefore, H+ exudation is a critical plant strategy for nutrient acquisition and management, allowing plants to improve their access to essential elements from the soil. A lack of water splitting during photosynthesis can affect iron uptake because the resulting energy imbalance disrupts the plant's ability to produce ATP and NADPH, which are crucial for overall photosynthetic energy conversion and can trigger a deficiency in iron homeostasis pathways. While photosynthesis uses hydrogen ions produced from water splitting for the Calvin cycle, not to create a hydrogen gas deficiency, the overall process is sensitive to nutrient availability, and iron is essential for chloroplast function. In photosynthesis, water is split to provide electrons to replace those lost in Photosystem II, which is triggered by light absorption. These electrons then travel along a transport chain to generate ATP (energy currency) and NADPH (reducing power). Carbon Fixation: The generated ATP and NADPH are then used to convert carbon dioxide into carbohydrates in the Calvin cycle. Impaired water splitting (via water in or out) breaks the chain reaction of photosynthesis. This leads to an imbalance in ATP and NADPH levels, which disrupts the Calvin cycle and overall energy production in the plant. Plants require a sufficient supply of essential mineral elements like iron for photosynthesis. Iron is vital for chlorophyll formation and plays a crucial role in electron transport within the chloroplasts. The complex relationship between nutrient status and photosynthesis is evident when iron deficiency can be reverted by depleting other micronutrients like manganese. This highlights how nutrient homeostasis influences photosynthetic function. A lack of adequate energy and reducing power from photosynthesis, which is directly linked to water splitting, can trigger complex adaptive responses in the plant's iron uptake and distribution systems. Plants possess receptors called transceptors that can directly detect specific nutrient concentrations in the soil or within the plant's tissues. These receptors trigger signaling pathways, sometimes involving calcium influx or changes in protein complex activity, that then influence nutrient uptake by the roots. Plants use this information to make long-term adjustments, such as Increasing root biomass to explore more soil for nutrients. Modifying metabolic pathways to make better use of available resources. Adjusting the rate of nutrient transport into the roots. That's why I keep a high EC. Abundance resonates Abundance.