She's doing well. Another week started in low humidity. The meter is on wet soil hence the high number which is inaccurate. Mostly 45-50%. Topped her on day 10 which turned out to be a FIM.

Today, august 4, i flush the lemons because i see some ambar trichomes but now i think that it wasn't enough because the others doesn't look cloudy, so i keep feeding them. The pictures are from the lemons and was taken with a wifi digital microscope that i bought in Amazon. August 8, second time with potasic soap (i know that i have to clean/wash the buds, if you have any suggestion, do it please 😊) August 9 flushing all the plants, except the tallest one (one of the syrups). How you can see on the video, the TGL 60 is over she. August 10 little defoliation.

I loved the first grow of this strain. let's try again.

Friday, 2021-06-25 Definitely the last Week of Flower for her, soon Harvest will come And she stands now under the VIPARSPECTRA XS-2000 Light is on 75 Percent, to get used to... because the Lights are very Powerful and I dont want to burn// stress her in her last Days Leaves are discoloring, all Pistils are Orange/ brown Trichomes are all Milky and afew Amber ones Tomorrow she gets agood drink with " Clean Fruits" to help her devour the Nutrient-Remainings Shopping Link for the LIghts: Amazon US: XS1000 10% off: it10mlarimar http://yx-8.cn/0y-6 XS1500 5% off: it15mlarimar http://yx-8.cn/0yA XS2000 5% off: it20mlarimar http://yx-8.cn/0y2Y XS4000 5% off: it40mlarimar http://yx-8.cn/0y5k Amazon Canada XS1000 10% off: it10mlarimar https://amzn.to/38udUVe XS1500 5% off: it15mlarimar https://amzn.to/3esVUyr XS2000 5% off: it20mlarimar https://amzn.to/3l5zAfg XS4000 5% off: it40mlarimar https://amzn.to/3l7k5Uj

Sono molto felice della mia pianta e dei suoi frutti spero in un buon raccolto da secca 😉 io direi di farmi fare altre 3 settimane di fioritura e poi raccogliere. Saluti 🙏🙏

Week 9 flowering Water 🚿 only

Radical Juice – Week 4 of Flowering The Radical Juice is looking amazing! 🌿 The buds are starting to form beautifully, and the scent is becoming more noticeable with every day! 🌸 The plants are doing great and are getting more and more frosty as time goes on. The first trichomes are appearing, and I’m already excited about the upcoming harvest! ✨ The stretch seems to be slowing down now, and the plant is focusing more on bud development. Everything is progressing as expected. I’m still only using water, and I’m letting the soil and the microorganisms do the work. 🌱 As for the clone trial, the clone that received my homemade fertilizer with every watering is noticeably bigger and healthier than the other clones that didn’t get it. It’s really interesting to see the results! 📈 Stay tuned for more updates, and don’t forget to follow so you won’t miss anything! 😎 --- Radical Juice – Woche 4 der Blüte Die Radical Juice sieht einfach großartig aus! 🌿 Die Buds beginnen sich wunderschön zu entwickeln, und der Duft wird mit jedem Tag intensiver! 🌸 Die Pflanzen machen sich bestens und werden von Tag zu Tag frostiger. Die ersten Trichome sind bereits sichtbar, und ich freue mich schon sehr auf die Ernte! ✨ Der Stretch scheint jetzt langsamer zu werden, und die Pflanze konzentriert sich mehr auf die Budentwicklung. Alles läuft wie erwartet. Ich gieße immer noch nur mit Wasser und lasse den Boden und die Mikroorganismen die Arbeit erledigen. 🌱 Was die Klon-Versuchsreihe angeht, ist der Klon, der bei jedem Gießen meinen selbstgemachten Dünger erhalten hat, deutlich größer und gesünder als die anderen Klone, die ihn nicht bekommen haben. Es ist wirklich spannend, die Ergebnisse zu sehen! 📈 Bleibt dran für weitere Updates und vergesst nicht zu folgen, damit ihr nichts verpasst! 😎

15/08/18 - all looking good got loads of roots piercing out the sides of the smart pot , I’m thinking of adding cannazyme soon to break up all the dead roots etc, I’m feeding them the usual tonight and 2 litres each 💧and I’m done with LST now im just gonna let them start to stretch🙏🏻🙌🏻 17/08/18 - saw some weird marks on a leaf or two this morning and then later on it look like the pic above, it’s only happening on older leaves it’s not affecting any new growth, I’m out of grow questions so any help would be grear ✌️🏻 20/08/18 - just watered them with the above ☝️🏻 All looking good think I’m half way through the stretch so I’ve started to add some canna boost to the solution , probably gonna do some LST later on this week.

2024-07-06 we are in the FInals ( the indoor Plant) and shes very hungry and Thristy. i give her moderate amounts of feedings and around 2l of water every Day, and shes still a bit limegreen. But in the end, we are halfway through the Flowering she showsa super structure, and the Flowers are building shape- i lowered the Humidity to 50 percent. The Outdoor Girls looks nearly like nothing happened. outddor temperatures are cold and it tends to be rainy- so shes very well conservated, and di not get too big, for taking her indoor later. i still have not decided we will see. BREEDER INFO Tangerine Snow F1 Fast Feminised is a 75% sativa, four-way cross of (Boost x Tangelo) with (Lavender x Power Plant). This Fast F1 hybrid is bred from Cali genetics and boasts great citrus terps, high resin production for extracts, high levels of THC, very good yields and excellent mould resistance. Tangerine Snow F1 Fast can be grown indoors as well as outdoors. Indoor flowering times are between 8 - 10 weeks while harvest time in northern latitudes is during September while in the southern hemisphere growers will be harvesting during March. Recommended climate regions are hot, dry, humid and warm. These are tall, semi-branched plants that grow in excess of 200cm and display a high degree of vigour with very good uniformity. In common with many other heavily sativa-dominant strains, Tangerine Snow F1 Fast offers excellent resistance to mould as well as to plant pests and diseases. The combination of citrus terps and plenty of resin makes thi a very good extract strain with the 'washing' method delivering very good yields of hash. The citrus terpene profile is reminiscent of mandarins and tangerines and also has sweet candy notes. THC production has been lab-verified at a strong 24% while CBD is low. The effect is uplifting and energising, perfect for use during the day and early evening.

Day 28 - Found some early nute burn on the lower leaves of Gelato, I think i'm fertigating too little and the salts in the coco is rising. From now I'm going to give 2L of water two times per day in order to re-clean the medium with much more run off.

This girl has been growing out of control in my tent I don't see her flowering very much not sure if she's a auto or a photo Plant i will continue to have an eye on he for now I had to tie her to a corner of the tent in order for her not to take over the entire space and is a plant that grows vigorously strong and it has a lovely smell White Widow skunk . Thank you for reading I will continue to update have a happy grow.

Just came back after vacation

Harvested 5 out of 7 pics and videos soon..... loading.....

No food just Water. Flower 12/12 on 9-12-24 = (48 days)

nada que resaltar. Una más entre el montón. igual 70gr. en seco no más como comenté antes, las auto no siempre gustan pasados unos meses curando y cansado de tenerlo por ahí me decidí por hacer hash con hielo. 9,1gr de 100 gr. áprox de cogollitos

19/01/21. segundo dia de sesunda semana de floracion, hoy le pode algunas hojas grandes para que le pegue mejor la luz en las partes bajas le aplique un poco de insecticida organico para araña roja encontre algunas hojas con la plaga 22/01/21. hoy se aplico riego con nutrientes organico de Rootz.mx se aplico magnaflor y forzasilicia MagnaFlor. Estimula la floración. 100% orgánico. Contiene biocatalizadores que serán rápidamente absorbidos por las raíces de tus plantas. El comienzo de la floración será explosivo. 24/01/21. le puse un poco de insectisida organico por que le e notado muchos acaros araña roja, cierre de semana

Yellow butterfly came to see me the other day; that was nice. Starting to show signs of stress on the odd leaf, localized isolated blips, blemishes, who said growing up was going to be easy! Smaller leaves have less surface area for stomata to occupy, so the stomata are packed more densely to maintain adequate gas exchange. Smaller leaves might have higher stomatal density to compensate for their smaller size, potentially maximizing carbon uptake and minimizing water loss. Environmental conditions like light intensity and water availability can influence stomatal density, and these factors can affect leaf size as well. Leaf development involves cell division and expansion, and stomatal differentiation is sensitive to these processes. In essence, the smaller leaf size can lead to a higher stomatal density due to the constraints of available space and the need to optimize gas exchange for photosynthesis and transpiration. In the long term, UV-B radiation can lead to more complex changes in stomatal morphology, including effects on both stomatal density and size, potentially impacting carbon sequestration and water use. In essence, UV-B can be a double-edged sword for stomata: It can induce stomatal closure and potentially reduce stomatal size, but it may also trigger an increase in stomatal density as a compensatory mechanism. It is generally more efficient for gas exchange to have smaller leaves with a higher stomatal density, rather than large leaves with lower stomatal density. This is because smaller stomata can facilitate faster gas exchange due to shorter diffusion pathways, even though they may have the same total pore area as fewer, larger stomata. Leaf size tends to decrease in colder climates to reduce heat loss, while larger leaves are more common in warmer, humid environments. Plants in arid regions often develop smaller leaves with a thicker cuticle and/or hairs to minimize water loss through transpiration. Conversely, plants in wet environments may have larger leaves and drip tips to facilitate water runoff. Leaf size and shape can vary based on light availability. For example, leaves in shaded areas may be larger and thinner to maximize light absorption. Leaf mass per area (LMA) can be higher in stressful environments with limited nutrients, indicating a greater investment in structural components for protection and critical resource conservation. Wind speed, humidity, and soil conditions can also influence leaf morphology, leading to variations in leaf shape, size, and surface characteristics. Small leaves: Reduce water loss in arid or cold climates. Environmental conditions significantly affect gene expression in plants. Plants are sessile organisms, meaning they cannot move to escape unfavorable conditions, so they rely on gene expression to adapt to their surroundings. Environmental factors like light, temperature, water, and nutrient availability can trigger changes in gene expression, allowing plants to respond to and survive in diverse environments. Depending on the environment a young seedling encounters, the developmental program following seed germination could be skotomorphogenesis in the dark or photomorphogenesis in the light. Light signals are interpreted by a repertoire of photoreceptors followed by sophisticated gene expression networks, eventually resulting in developmental changes. The expression and functions of photoreceptors and key signaling molecules are highly coordinated and regulated at multiple levels of the central dogma in molecular biology. Light activates gene expression through the actions of positive transcriptional regulators and the relaxation of chromatin by histone acetylation. Small regulatory RNAs help attenuate the expression of light-responsive genes. Alternative splicing, protein phosphorylation/dephosphorylation, the formation of diverse transcriptional complexes, and selective protein degradation all contribute to proteome diversity and change the functions of individual proteins. Photomorphogenesis, the light-driven developmental changes in plants, significantly impacts gene expression. It involves a cascade of events where light signals, perceived by photoreceptors, trigger changes in gene expression patterns, ultimately leading to the development of a plant in response to its light environment. Genes are expressed, not dictated! While having the potential to encode proteins, genes are not automatically and constantly active. Instead, their expression (the process of turning them into proteins) is carefully regulated by the cell, responding to internal and external signals. This means that genes can be "turned on" or "turned off," and the level of expression can be adjusted, depending on the cell's needs and the surrounding environment. In plants, genes are not simply "on" or "off" but rather their expression is carefully regulated based on various factors, including the cell type, developmental stage, and environmental conditions. This means that while all cells in a plant contain the same genetic information (the same genes), different cells will express different subsets of those genes at different times. This regulation is crucial for the proper functioning and development of the plant. When a green plant is exposed to red light, much of the red light is absorbed, but some is also reflected back. The reflected red light, along with any blue light reflected from other parts of the plant, can be perceived by our eyes as purple. Carotenoids absorb light in blue-green region of the visible spectrum, complementing chlorophyll's absorption in the red region. They safeguard the photosynthetic machinery from excessive light by activating singlet oxygen, an oxidant formed during photosynthesis. Carotenoids also quench triplet chlorophyll, which can negatively affect photosynthesis, and scavenge reactive oxygen species (ROS) that can damage cellular proteins. Additionally, carotenoid derivatives signal plant development and responses to environmental cues. They serve as precursors for the biosynthesis of phytohormones such as abscisic acid () and strigolactones (SLs). These pigments are responsible for the orange, red, and yellow hues of fruits and vegetables, while acting as free scavengers to protect plants during photosynthesis. Singlet oxygen (¹O₂) is an electronically excited state of molecular oxygen (O₂). Singlet oxygen is produced as a byproduct during photosynthesis, primarily within the photosystem II (PSII) reaction center and light-harvesting antenna complex. This occurs when excess energy from excited chlorophyll molecules is transferred to molecular oxygen. While singlet oxygen can cause oxidative damage, plants have mechanisms to manage its production and mitigate its harmful effects. Singlet oxygen (¹O₂) is considered a reactive oxygen species (ROS). It's a form of oxygen with higher energy and reactivity compared to the more common triplet oxygen found in its ground state. Singlet oxygen is generated both in biological systems, such as during photosynthesis in plants, and in cellular processes, and through chemical and photochemical reactions. While singlet oxygen is a ROS, it's important to note that it differs from other ROS like superoxide (O₂⁻), hydrogen peroxide (H₂O₂), and hydroxyl radicals (OH) in its formation, reactivity, and specific biological roles. Non-photochemical quenching (NPQ) protects plants from damage caused by reactive oxygen species (ROS) by dissipating excess light energy as heat. This process reduces the overexcitation of photosynthetic pigments, which can lead to the production of ROS, thus mitigating the potential for photodamage. Zeaxanthin, a carotenoid pigment, plays a crucial role in photoprotection in plants by both enhancing non-photochemical quenching (NPQ) and scavenging reactive oxygen species (ROS). In high-light conditions, zeaxanthin is synthesized from violaxanthin through the xanthophyll cycle, and this zeaxanthin then facilitates heat dissipation of excess light energy (NPQ) and quenches harmful ROS. The Issue of Singlet Oxygen!! ROS Formation: Blue light, with its higher energy photons, can promote the formation of reactive oxygen species (ROS), including singlet oxygen, within the plant. Potential Damage: High levels of ROS can damage cellular components, including proteins, lipids, and DNA, potentially impacting plant health and productivity. Balancing Act: A balanced spectrum of light, including both blue and red light, is crucial for mitigating the harmful effects of excessive blue light and promoting optimal plant growth and stress tolerance. The Importance of Red Light: Red light (especially far-red) can help to mitigate the negative effects of excessive blue light by: Balancing the Photoreceptor Response: Red light can influence the activity of photoreceptors like phytochrome, which are involved in regulating plant responses to different light wavelengths. Enhancing Antioxidant Production: Red and blue light can stimulate the production of antioxidants, which help to neutralize ROS and protect the plant from oxidative damage. Optimizing Photosynthesis: Red light is efficiently used in photosynthesis, and its combination with blue light can lead to increased photosynthetic efficiency and biomass production. In controlled environments like greenhouses and vertical farms, optimizing the ratio of blue and red light is a key strategy for promoting healthy plant growth and yield. Understanding the interplay between blue light signaling, ROS production, and antioxidant defense mechanisms can inform breeding programs and biotechnological interventions aimed at improving plant stress resistance. In summary, while blue light is essential for plant development and photosynthesis, it's crucial to balance it with other light wavelengths, particularly red light, to prevent excessive ROS formation and promote overall plant health. Oxidative damage in plants occurs when there's an imbalance between the production of reactive oxygen species (ROS) and the plant's ability to neutralize them, leading to cellular damage. This imbalance, known as oxidative stress, can result from various environmental stressors, affecting plant growth, development, and overall productivity. Causes of Oxidative Damage: Abiotic stresses: These include extreme temperatures (heat and cold), drought, salinity, heavy metal toxicity, and excessive light. Biotic stresses: Pathogen attacks and insect infestations can also trigger oxidative stress. Metabolic processes: Normal cellular activities, particularly in chloroplasts, mitochondria, and peroxisomes, can generate ROS as byproducts. Certain chlorophyll biosynthesis intermediates can produce singlet oxygen (1O2), a potent ROS, leading to oxidative damage. ROS can damage lipids (lipid peroxidation), proteins, carbohydrates, and nucleic acids (DNA). Oxidative stress can compromise the integrity of cell membranes, affecting their function and permeability. Oxidative damage can interfere with essential cellular functions, including photosynthesis, respiration, and signal transduction. In severe cases, oxidative stress can trigger programmed cell death (apoptosis). Oxidative damage can lead to stunted growth, reduced biomass, and lower crop yields. Plants have evolved intricate antioxidant defense systems to counteract oxidative stress. These include: Enzymes like superoxide dismutase (SOD), catalase (CAT), and various peroxidases scavenge ROS and neutralize their damaging effects. Antioxidant molecules like glutathione, ascorbic acid (vitamin C), C60 fullerene, and carotenoids directly neutralize ROS. Developing plant varieties with gene expression focused on enhanced antioxidant capacity and stress tolerance is crucial. Optimizing irrigation, fertilization, and other management practices can help minimize stress and oxidative damage. Applying antioxidant compounds or elicitors can help plants cope with oxidative stress. Introducing genes for enhanced antioxidant enzymes or stress-related proteins over generations. Phytohormones, also known as plant hormones, are a group of naturally occurring organic compounds that regulate plant growth, development, and various physiological processes. The five major classes of phytohormones are: auxins, gibberellins, cytokinins, ethylene, and abscisic acid. In addition to these, other phytohormones like brassinosteroids, jasmonates, and salicylates also play significant roles. Here's a breakdown of the key phytohormones: Auxins: Primarily involved in cell elongation, root initiation, and apical dominance. Gibberellins: Promote stem elongation, seed germination, and flowering. Cytokinins: Stimulate cell division and differentiation, and delay leaf senescence. Ethylene: Regulates fruit ripening, leaf abscission, and senescence. Abscisic acid (ABA): Plays a role in seed dormancy, stomatal closure, and stress responses. Brassinosteroids: Involved in cell elongation, division, and stress responses. Jasmonates: Regulate plant defense against pathogens and herbivores, as well as other processes. Salicylic acid: Plays a role in plant defense against pathogens. 1. Red and Far-Red Light (Phytochromes): Red light: Primarily activates the phytochrome system, converting it to its active form (Pfr), which promotes processes like stem elongation and flowering. Far-red light: Inhibits the phytochrome system by converting the active Pfr form back to the inactive Pr form. This can trigger shade avoidance responses and inhibit germination. Phytohormones: Red and far-red light regulate phytohormones like auxin and gibberellins, which are involved in stem elongation and other growth processes. 2. Blue Light (Cryptochromes and Phototropins): Blue light: Activates cryptochromes and phototropins, which are involved in various processes like stomatal opening, seedling de-etiolation, and phototropism (growth towards light). Phytohormones: Blue light affects auxin levels, influencing stem growth, and also impacts other phytohormones involved in these processes. Example: Blue light can promote vegetative growth and can interact with red light to promote flowering. 3. UV-B Light (UV-B Receptors): UV-B light: Perceived by UVR8 receptors, it can affect plant growth and development and has roles in stress responses, like UV protection. Phytohormones: UV-B light can influence phytohormones involved in stress responses, potentially affecting growth and development. 4. Other Colors: Green light: Plants are generally less sensitive to green light, as chlorophyll reflects it. Other wavelengths: While less studied, other wavelengths can also influence plant growth and development through interactions with different photoreceptors and phytohormones. Key Points: Cross-Signaling: Plants often experience a mix of light wavelengths, leading to complex interactions between different photoreceptors and phytohormones. Species Variability: The precise effects of light color on phytohormones can vary between different plant species. Hormonal Interactions: Phytohormones don't act in isolation; their interactions and interplay with other phytohormones and environmental signals are critical for plant responses. The spectral ratio of light (the composition of different colors of light) significantly influences a plant's hormonal balance. Different wavelengths of light are perceived by specific photoreceptors in plants, which in turn regulate the production and activity of various plant hormones (phytohormones). These hormones then control a wide range of developmental processes.