Had to defoliate heavy because of mildew but she’s trooping along

More Big changes this week! The flowers seem to be growing and getting bigger every day - I anxiously look in my tent each morning to see the new developments and there seems to be new changes each time - very cool to smoke a bowl in the morning and go check your garden! I was able to get some pretty cool photos with my macro lens - I found the ONLY flower site and first signs of red colors on one of the lower flowers of Cherry Gorilla #3 - I was able to get some pretty sweet pics of that. If you have a smart phone or tablet, definitely check out some of the macro shots and pinch/zoom in! I did add a fan on the bottom blowing underneath the canopy, in efforts of opening up the stomata of the ladies. We are finally having our first relatively hot week up here and it has absolutely tested my environment management skills - AC, Dehumidifier, Fans, Window open and close - this silly temp VPD and humidity control dance all day will not be too much longer, very much looking forward to the lower temperatures of the fall and winter months! When opening up the tent - you are blasted with a unfamiliar smell that can be explained as a sweet dank. I have touched some of the lower buds on each of the plants and WOW! - They are SWEET and Cherry flavor like crazy - The GMO is just as I expected - Garlic Gas Sweetness when touching her leaves - You are left with a very sticky goo on your finger that absolutely smells of its particular strain. Again - I could not be happier with the garden, and especially this being my first grow ever. Looking forward to more changes and absolutely some input from the Grow Diaries Community!

hi growmies, this one is really bulking hard. taking over most of the box. she doesn't smell like a typical afghan anymore, very creamy. still amazing what you can do to these plants and they still recover from it. The buds on this one seemed very fluffy at the beginning, however this has starting to change know and they start swelling very nicely.

There is definitely some deficiencies present. I had planned on doing a flip to flower however this will put me off for another week or two while I correct any nutritional problem. Other than that they look good, very bushy. What do you guys think? Am I going to have a good 1212?

Привет садовники !!!😐

Alles gut, macht sein ding ! 😜

Hallo zusammen 🤙. Sie wächst sehr schön und macht keine Probleme.

Magic castle on day 78 getting close to harvest. Started the carboflush last week and will continue till harvest!

MATARO BLUE by KANNABIA Week #21 Overall Week #7 Flower This week been a good week for this lady she's doing good no issues to report buds are looking good so far. Stay Growing!! Kannabia.com MATARO BLUE

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.

113 days from seed in tiny pot 1 lt, the best smelling in my tent floral and diesel ⛽

Day 23th Flowering Stage, all plants looking healthy except for Gelato Sorbet. All plants 2L water + nutrients, Gelato Sorbet got 1L water + nutrients and 1L 6.3 pH filtered water.

FBT2309 is doing great. She has grow a lot in a week. In a few days more space will open in grow room and that will help as well. Everything is looking good under the Medic Grow Mini Sun-2, in the Gen1:11 nutrition. Thank you again Gen1:11, Medic Grow, and Fast Buds. 🤜🏻🤛🏻🌱🌱🌱 Thank you grow diaries community for the 👇likes👇, follows, comments, and subscriptions on my YouTube channel👇. ❄️🌱🍻 Happy Growing 🌱🌱🌱 https://youtube.com/channel/UCAhN7yRzWLpcaRHhMIQ7X4g If anyone needs to purchase fastbuds here is a link for my affiliate program https://myfastbuds.com/?a_aid=60910eaff2419

Note : Jegliches Equipment aufgelistet welches ich nutze findet Ihr in der Germinations Woche !!! 200PPFD 20/4 Day 14: + Düngen + + 0.5L Flaschenwasser (EC 0.36) + + Canna Terrar Vega 2.9ml + + Canna Rhizotonic 2ml + + PH 6.0

Literally she’s beautiful. I can’t even tell you how happy I am with how she turned out. The Rosin is crystal clear amber goodness. She tastes so creamy and sweet. The profile is just pure bliss. One of my all time favorite plants. Yields great. Dense as ever nugs. Tastes fabulous. Sweet seeds keep it up 💪🏻💪🏻💪🏻💪🏻

So I heard that matterhorn is an unstable plant but I never thought it was so unstable. One fenotype are doing well but plants from another mother are struggling. I checked the condition every day and every day the EC dropped and the pH rose. Which meant eating, but still showing problems on the leaves. During this period I made a mistake with the water temperature, namely when the water temperature is above 20 ° C the oxygen in the water drops drastically and these were the beginnings of my root problems. I didn't know it then, but later root rot appeared.

to be updated soon

Third one in the video, candy kush express, beautiful compact plant, she is growing fast and has a beautiful structure. She won't need long to finish her flower cycle ⚡