Week 6 Light cycle=18/6 Light Power=120w 50% Extractor controller settings High temp= 25c Low temp= c Temp step=0c High Rh= 56% Low Rh= % Rh step=0% Speed max=8 Speed min=2 Smart controller settings (during lights on). Lights on=06.00am Radiator on= below 21c Radiator off= above 22c Smart controller settings (during lights off). Lights off=00.00am Radiator on= below 18c Radiator off= above 19c VPD aim=0.6-1.4 DLI aim=35-40 EC aim=1.9 PH aim=6.2 Fri 26/1/24 #1 (Day 36) 📋 defoliate lower leaves that hardly get any light. Sat 27/1/24 #1 (Day 37) 📋 H=42cm D=39cm DLI=32.5 Raised light about 10cm Increased light power to 140w H=42cm D=49cm DLI=30.1 Sun 28/1/24 I have decided today is going to be the last day of veg before I flip to flower. Lights will have come on today at 6.00am and go off at 10.00pm, they will get 14hrs light today and tomorrow will be day 1 of 12/12. 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 Method= automatic Feed=Veg nutes. Neutralise=0.1ml/L Silicon=1.0ml/L Calmag=1.0ml/L Terra grow=4.0ml/L Roots=0.2ml/L Easy Ph down=0.125ml/L Ec= 2.05 PH=6.1/6.3 Time start=12.00pm Finish time=13.45pm (11×5 minute runs with 5 minute gaps) Total flow rate=181ml/min Flow rate per plant=45ml/min. Total volume made=12L Total volume left=2L Total volume used=10L Volume per plant=2.5L (Est) Runoff. Total runoff=1L Ec=2.7 PH=6.1/6.3 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 #1 (Day 38) 📋 With no information for flower time I'm going to have to guess she will be finished in 45-60 days. I removed quite a few lower nodes that probably won't break through the canopy, they where ideal candidates for clones. Light cycle=12/12 Light Power=140w 58% Extractor controller settings High temp= 25c Low temp= c Temp step=0c High Rh= 56% Low Rh= % Rh step=0% Speed max=8 Speed min=2 Smart controller settings (during lights on). Lights on=10.01-21.59 Radiator on= below 21.5c Radiator off= above 22.5c Smart controller settings (during lights off). Lights off=22.00-10.00 Radiator on= below 18c Radiator off= above 19c Mon 29/1/24 Lights on at 10.00am off at 22.00pm #1 (Day 39)(Day 1 flower) 📋 H=45cm D=46cm DLI=23.1 At 9.00pm increased light to 150w H=45cm D=46cm DLI=24.0 Tue 30/1/24 #1 (Day 40)(Day 2 flower) 📋 Wed 31/1/24 #1 (Day 41)(Day 3 flower) 📋 H=48cm D=43cm DLI=28.4 🚿 foliar sprayed (Sumo Boost 2ml/L). Thur 1/2/24 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 Method= automatic Feed=water Neutralise=0.1ml/L Roots=0.2ml/L Easy Ph down=0.ml/L Ec=0.2 PH=6.6/6.6 Time start=12.00pm Finish time=13.45pm (11×5 minute runs with 5 minute gaps) Total flow rate=181ml/min Flow rate per plant=45ml/min. Total volume made=14L Total volume left=4L Total volume used=10L Volume per plant=2.5L (Est) Runoff. Total runoff=1L Ec=2.0 PH=6.1/6.2 💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧💧 #1 (Day 42)(Day 4 flower)**** 📋 H=50cm D=41cm DLI=29.0 Lifted light and increasd power to 196w. H=50cm D=50cm DLI=29.5 She is doing great, has a nice height and shape to her. No problems still. She has been under 12/12 for majority of the week. Back soon. Take it easy.

Day 70 after switch. its going to end soon I think. 65 - 70 days recomended by breeder. Maybe I will just not water again and let her slowly die 😱 she looks good - beatutifull almost - although I inspected a problem at one of the buds... more in my question that I will create. bigger leafs are getting soaked out of nutritions and start to get yellow. probably the last time you see her alive. I try to recap a little bit of the veg. phase in the upcoming week to get the diary a more "complete" look 😎 Also I will update you as soon as I got this in the glasses. thanks for your participation on my way with ralph wigum from root riot seeds (almicanna)👌

Welcome to my pink rozay x strawberry banana auto diary from original sensible seeds. Veg Days 15-21 Doing well. Have been able to put my RH back up to 70% so expecting much better growth. Hopefully she'll stay in veg for another 2 weeks. But I've yet to have an auto go by 28 Days in veg. Maybe with growth been slow and been started in a big pot she'll grow nice and big. Let's see. She's healthy and I've moved her off onto a new enzyme from Terra Power and took her off the others. Sticking to feeds between 450-550ppm. PH 6.0-2. Base feeds twice a wk. With 1 Epsom salt feed with some cal powder to bring my 110ppm tap to 250-300 and then I also add an enzyme feed that acts also like a follow up water feed. Roughly 4 feeds every 7-9 days, depending breaking base feeds up every 3-4 days. "This will be a common feeding pattern so won't be bringing up much about this again unless adjusted" Have moved most of my plants under my new SP 3000 300w now. Great versatile light. That meets more than my expectations COUPON FOR MARSHYDRO Use code "ggs" at any official marshydro site for a discount.

Que pasa familia, vamos con la séptima y última semana de floración de estas Gorilla cookies Auto de FastBuds. Por el momento todo va bien tienen buen color, van madurando esas flores. Llevan solo agua toda la semana. Por supuesto el ph se mide en cada riego y se mantiene en 6.2 y riego en intervalos de 48h. La temperatura está entorno al 22/24 grados y la humedad anda sobre el 50%. La verdad para ser autos es que me han hasta sorprendido , buena estructura, resistentes , fáciles, huelen fuerte y están llenas de resina. Qué más puedo pedir? Mars hydro: Code discount: EL420 https://www.mars-hydro.com/ Agrobeta: https://www.agrobeta.com/agrobetatiendaonline/36-abonos-canamo Hasta aquí todo, Buenos humos 💨💨💨

31 days into flower, I have slowly upped the cf to 1.8 since my last post, I have added a bit of Cal/Mag and upped the pk and treacle. My lights will come on as I am writing this, so we will see soon if yesterdays biggest feed to date has had any adverse effects. Video is my run off left to stand in shopvac over night. As you can see it is 'Alive' and bubbling away. What is going on does not smell like yeast or Vinegar, it smells like 'Clean fresh Compost'. So I expect the runoff is producing CO2 and Methane. CO2 is good, roots can absorb it. With the Methane there is possibly some Ethylene being produced, which may have some very positive benefits as far as plant chemistry and suppression of masculine traits? The gases bubbling off the runoff 'Soup' would not be difficult to Identify with a couple of wash bottles and a few readily available reagents. I ain't got the time, or the kit. There are definitely a few different organisms at play here as you can see different structured plaques forming on the water surface, and different foams forming with the bubbles. Just took photo's, everything looks good except Blue Sherbalato, Developed a kink in top leaf, that could be a couple of things, I shall work it out. (highered light a bit, dropped c/f, pushed cola away from light centre, and I shall let this pot dry out a touch, it has been happy till now.) Every thing else is looking OK, all got a touch of tip burn. Canna Coco sometimes does not have enough N for grow, and almost always too much N in flower so I expect a bit of tip burn especially in high calyx to leaf hybrids. The plants are using around 2 litres of water + food per day with a slight + or - on c/f with first runoff. Ph going in at 5 to 5.5. First runoff is 6.8 I will keep watering till runoff hits 5.8 or lower so it usually takes between 3 and 4 litres of nutes. per day. Hate being this wasteful with nutes , not enough going on in the garden to use it all out there yet, so down the drain it goes. I have thought about re-circulation, if I was bigger and running clones maybe. The Blue Sherbalato has shown me I got to start treating these plants as individuals and tailor their treatment accordingly. The GTH have changed their smell, the Lemon is still there but fuel and floor polish is becoming more dominant in 3 of the plants. My plants are in 10 litres of Coco in 15 litre felt pots rolled down. Maltezerz, Orangesicle GTH 1, . plus the Scott's OG will run out of pot space so I will top them up to the 15 litre. Got to make decisions on the cuts of these plants soon. I hate culling plants before the parent has finished its cycle.

De nuevo familia, estoy de vuelta para actualizar la 5 semana y la verdad que mal, que no esperaba tantos errores en un cultivo , pero el trasplante no les sentó muy bien , empezaron amarillear por abajo por falta de nutrientes , ya aporte N nitrógeno para ponerlas verdes pero bueno eso ralentizó algo el crecimiento a ver si las recuperamos al 100% y las pasamos a floración, veremos cómo crecen estos días. Seguiré aportando algún riego Rico en N nitrógeno para estimular el crecimiento y que cojan buen color. Volví a colocar el humidificador, en principio lo quite pero también pienso que les falto humedad esos días y tampoco ayudo , hasta ahora esto es todo espero no cometer más errores aquí, Buenos humos 💨💨

hey growmies I decided to switch to flowering, I am using ADV nutes with the dosage recommended by them and they seem to me in great shape, tonight I will do a defoliation in order to breathe better and get as much light as possible. I'll keep you up-to-date. good growth and happy day 💚🌳

16cm vertical growth this week, but she's bushed out a lot.

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She has exploded since last week so i tied her down a bit more. I think that she has almost reached full growth potential if she hasn't already. The bud development is starting to ramp up. I also removed a few leaves I watered once with 2,5l of rain water and another time with 3l. There were some very hot days (32-38 °C) so she had to be in the shade. I don't know if the burnt tips are because of the sun or a nute burn/deficiency, i will keep on following the biobizz schedule.

The grow cycle went smoothly, I did not update this diary as much as before, because I realised that I enjoy more the whole growing process than the documentation part.

70 Days 10 Weeks Flower Time 2 out 5 for Density Support Needed

bit of light stress in the last weeks photos, everything has cleared up still watering with silica when pot is dry. might just do a plain watering we have started flowering at day 18 on one of the crinkles , the rest of the room has now followed

They getting bigger and bigger

Lacewings seemed to have mostly killed themselves by flying into hot light fixtures. I may have left the UV on which was smart of me :) Done very little to combat if anything but make a sea of carcasses, on the bright side its good nutrition for the soil. Made a concoction of ethanol 70%, equal parts water, and cayenne pepper with a couple of squirts of dish soap. Took around an hour of good scrubbing the entire canopy. Worked a lot more effectively and way cheaper. Scorched earth right now, but it seems to have wiped them out almost entirely very pleased. Attempted a "Fudge I Missed" for the topping. So just time to wait and see how it goes. Question? If I attached a plant to two separate pots but it was connected by rootzone, one has a pH of 7.5 ish the other has 4.5. Would the Intelligence of the plant able to dictate each pot separately to uptake the nutrients best suited to pH or would it still try to draw nitrogen from a pot with a pH where nitrogen struggles to uptake? Food for stoner thought experiments! Another was on my mind. What happens when a plant gets too much light? Well, it burns and curls up leaves. That's the heat radiation, let's remove excess heat, now what? I've always read it's just bad, or not good, but when I look for an explanation on a deeper level it's just bad and you shouldn't do it. So I did. How much can a cannabis plant absorb, 40 moles in a day, ok I'll give it 60 moles. 80 nothing bad ever happened. The answer, finally. Oh great........more questions........ Reactive oxygen species (ROS) are molecules capable of independent existence, containing at least one oxygen atom and one or more unpaired electrons. "Sunlight is the essential source of energy for most photosynthetic organisms, yet sunlight in excess of the organism’s photosynthetic capacity can generate reactive oxygen species (ROS) that lead to cellular damage. To avoid damage, plants respond to high light (HL) by activating photophysical pathways that safely convert excess energy to heat, which is known as nonphotochemical quenching (NPQ) (Rochaix, 2014). While NPQ allows for healthy growth, it also limits the overall photosynthetic efficiency under many conditions. If NPQ were optimized for biomass, yields would improve dramatically, potentially by up to 30% (Kromdijk et al., 2016; Zhu et al., 2010). However, critical information to guide optimization is still lacking, including the molecular origin of NPQ and the mechanism of regulation." What I found most interesting was research pointing out that pH is linked to this defense mechanism. The organism can better facilitate "quenching" when oversaturated with light in a low pH. Now I Know during photosynthesis plants naturally produce exudates (chemicals that are secreted through their roots). Do they have the ability to alter pH themselves using these excretions? Or is that done by the beneficial bacteria? If I can prevent reactive oxygen species from causing damage by "too much light". The extra water needed to keep this level of burn cooled though, I must learn to crawl before I can run. Reactive oxygen species (ROS) are key signaling molecules that enable cells to rapidly respond to different stimuli. In plants, ROS plays a crucial role in abiotic and biotic stress sensing, integration of different environmental signals, and activation of stress-response networks, thus contributing to the establishment of defense mechanisms and plant resilience. Recent advances in the study of ROS signaling in plants include the identification of ROS receptors and key regulatory hubs that connect ROS signaling with other important stress-response signal transduction pathways and hormones, as well as new roles for ROS in organelle-to-organelle and cell-to-cell signaling. Our understanding of how ROS are regulated in cells by balancing production, scavenging, and transport has also increased. In this Review, we discuss these promising developments and how they might be used to increase plant resilience to environmental stress. Temperature stress is one of the major abiotic stresses that adversely affect agricultural productivity worldwide. Temperatures beyond a plant's physiological optimum can trigger significant physiological and biochemical perturbations, reducing plant growth and tolerance to stress. Improving a plant's tolerance to these temperature fluctuations requires a deep understanding of its responses to environmental change. To adapt to temperature fluctuations, plants tailor their acclimatory signal transduction events, specifically, cellular redox state, that are governed by plant hormones, reactive oxygen species (ROS) regulatory systems, and other molecular components. The role of ROS in plants as important signaling molecules during stress acclimation has recently been established. Here, hormone-triggered ROS produced by NADPH oxidases, feedback regulation, and integrated signaling events during temperature stress activate stress-response pathways and induce acclimation or defense mechanisms. At the other extreme, excess ROS accumulation, following temperature-induced oxidative stress, can have negative consequences on plant growth and stress acclimation. The excessive ROS is regulated by the ROS scavenging system, which subsequently promotes plant tolerance. All these signaling events, including crosstalk between hormones and ROS, modify the plant's transcriptomic, metabolomic, and biochemical states and promote plant acclimation, tolerance, and survival. Here, we provide a comprehensive review of the ROS, hormones, and their joint role in shaping a plant's responses to high and low temperatures, and we conclude by outlining hormone/ROS-regulated plant-responsive strategies for developing stress-tolerant crops to combat temperature changes. Onward upward for now. Next! Adenosine triphosphate (ATP) is an energy-carrying molecule known as "the energy currency of life" or "the fuel of life," because it's the universal energy source for all living cells.1 Every living organism consists of cells that rely on ATP for their energy needs. ATP is made by converting the food we eat into energy. It's an essential building block for all life forms. Without ATP, cells wouldn't have the fuel or power to perform functions necessary to stay alive, and they would eventually die. All forms of life rely on ATP to do the things they must do to survive.2 ATP is made of a nitrogen base (adenine) and a sugar molecule (ribose), which create adenosine, plus three phosphate molecules. If adenosine only has one phosphate molecule, it’s called adenosine monophosphate (AMP). If it has two phosphates, it’s called adenosine diphosphate (ADP). Although adenosine is a fundamental part of ATP, when it comes to providing energy to a cell and fueling cellular processes, the phosphate molecules are what really matter. The most energy-loaded composition for adenosine is ATP, which has three phosphates.3 ATP was first discovered in the 1920s. In 1929, Karl Lohmann—a German chemist studying muscle contractions—isolated what we now call adenosine triphosphate in a laboratory. At the time, Lohmann called ATP by a different name. It wasn't until a decade later, in 1939, that Nobel Prize–-winner Fritz Lipmann established that ATP is the universal carrier of energy in all living cells and coined the term "energy-rich phosphate bonds."45 Lipmann focused on phosphate bonds as the key to ATP being the universal energy source for all living cells, because adenosine triphosphate releases energy when one of its three phosphate bonds breaks off to form ADP. ATP is a high-energy molecule with three phosphate bonds; ADP is low-energy with only two phosphate bonds. The Twos and Threes of ATP and ADP Adenosine triphosphate (ATP) becomes adenosine diphosphate (ADP) when one of its three phosphate molecules breaks free and releases energy (“tri” means “three,” while “di” means “two”). Conversely, ADP becomes ATP when a phosphate molecule is added. As part of an ongoing energy cycle, ADP is constantly recycled back into ATP.3 Much like a rechargeable battery with a fluctuating state of charge, ATP represents a fully charged battery, and ADP represents a "low-power mode." Every time a fully charged ATP molecule loses a phosphate bond, it becomes ADP; energy is released via the process of ATP becoming ADP. On the flip side, when a phosphate bond is added, ADP becomes ATP. When ADP becomes ATP, what was previously a low-charged energy adenosine molecule (ADP) becomes fully charged ATP. This energy-creation and energy-depletion cycle happens time and time again, much like your smartphone battery can be recharged countless times during its lifespan. The human body uses molecules held in the fats, proteins, and carbohydrates we eat or drink as sources of energy to make ATP. This happens through a process called hydrolysis . After food is digested, it's synthesized into glucose, which is a form of sugar. Glucose is the main source of fuel that our cells' mitochondria use to convert caloric energy from food into ATP, which is an energy form that can be used by cells. ATP is made via a process called cellular respiration that occurs in the mitochondria of a cell. Mitochondria are tiny subunits within a cell that specialize in extracting energy from the foods we eat and converting it into ATP. Mitochondria can convert glucose into ATP via two different types of cellular respiration: Aerobic (with oxygen) Anaerobic (without oxygen) Aerobic cellular respiration transforms glucose into ATP in a three-step process, as follows: Step 1: Glycolysis Step 2: The Krebs cycle (also called the citric acid cycle) Step 3: Electron transport chain During glycolysis, glucose (i.e., sugar) from food sources is broken down into pyruvate molecules. This is followed by the Krebs cycle, which is an aerobic process that uses oxygen to finish breaking down sugar and harnesses energy into electron carriers that fuel the synthesis of ATP. Lastly, the electron transport chain (ETC) pumps positively charged protons that drive ATP production throughout the mitochondria’s inner membrane.2 ATP can also be produced without oxygen (i.e., anaerobic), which is something plants, algae, and some bacteria do by converting the energy held in sunlight into energy that can be used by a cell via photosynthesis. Anaerobic exercise means that your body is working out "without oxygen." Anaerobic glycolysis occurs in human cells when there isn't enough oxygen available during an anaerobic workout. If no oxygen is present during cellular respiration, pyruvate can't enter the Krebs cycle and is oxidized into lactic acid. In the absence of oxygen, lactic acid fermentation makes ATP anaerobically. The burning sensation you feel in your muscles when you're huffing and puffing during anaerobic high-intensity interval training (HIIT) that maxes out your aerobic capacity or during a strenuous weight-lifting workout is lactic acid, which is used to make ATP via anaerobic glycolysis. During aerobic exercise, mitochondria have enough oxygen to make ATP aerobically. However, when you're out of breath and your cells don’t have enough oxygen to perform cellular respiration aerobically, the process can still happen anaerobically, but it creates a temporary burning sensation in your skeletal muscles. Why ATP Is So Important? ATP is essential for life and makes it possible for us to do the things we do. Without ATP, cells wouldn't be able to use the energy held in food to fuel cellular processes, and an organism couldn't stay alive. As a real-world example, when a car runs out of gas and is parked on the side of the road, the only thing that will make the car drivable again is putting some gasoline back in the tank. For all living cells, ATP is like the gas in a car's fuel tank. Without ATP, cells wouldn't have a source of usable energy, and the organism would die. Eating a well-balanced diet and staying hydrated should give your body all the resources it needs to produce plenty of ATP. Although some athletes may slightly improve their performance by taking supplements or ergonomic aids designed to increase ATP production, it's debatable that oral adenosine triphosphate supplementation actually increases energy. An average cell in the human body uses about 10 million ATP molecules per second and can recycle all of its ATP in less than a minute. Over 24 hours, the human body turns over its weight in ATP. You can last weeks without food. You can last days without water. You can last minutes without oxygen. You can last 16 seconds at most without ATP. Food amounts to one-third of ATP production within the human body.

Out of the two plants, I only harvested one of them. I dried and cured the gassy Fino. It is curing right now. I’ll do a report a little later as far as the girl in the back right she she just sucked. Extremely large fee and just didn’t grow good, so I’m going to turn her into bubble hash chopped her down in frozen. The gassy Fino on the other hand did yield very well. I got 7 ounces off of her of all solid buds and there was probably about 2 ounces of large fat, I just threw in the trim bin

Cette plante poursuit sa vie calmement. Les têtes se durcissent et se développe encore légèrement. Remarque : nutriments à 50 % de la dose recommandée en partie finale Terra aquatica.