Day 72 from seed Just feed water ph to 6 Around 600-700 par Both veg and bloom mode on the light.

WEEK#9 DAY#56 :She could use some water . Easy going grow , slow vertical climb multi-lateral branching . I could selectively prune to encourage vertical growth but at this time I think the grow is going fine . I anticipated the plant being larger at this time athough I’ve never grown this strain before to know what to expect I think another 4-6 weeks of VEG will do her nothing but JUSTICE . Still watering to make those dry amendments available . After these 28-31 days we’ll transplant her into her final 6gallon pot . Or atleast I think that will be her final pot I see the benefit of stepping up pot size gradually and honesty think the growth is healthier when done that way I’m just being lazy and don’t feel like up-potting 3 or more times . I just wanna make small adjustments and move on ya know ? Week#9Day#56Update: 2/3 older girls showing signs of flushing, there’s heavy yellowing top of the plant & purple hues beginning to show. The two of them should have 3-4 weeks left & the buds have not even began to swell yet so I’m worried I missed my feeding time after I gave them nute burn beginning of flower so my fear is that my bud won’t swell & I’ve just jacked up my harvest the last half of flower. I’m going to try & get small amounts of nutes in there to help the bud develop without giving too much to mess up the end of flower flush . The final older girl isn’t showing any signs of flush it is the smallest of the 3 & therefore perhaps did not consume as much food as the other 2 girls is all I can think considering all three ladies soil came from the same batch of premixed “soil” they weren’t individually mixed It’s almost time to get these older girls out & get some note-worthy shots of “Cellie” growing All ALONE into this 5x5. Heavy heavy heavy defoliation. Will pony-tail when the fan leaves grow back out Week#9 Day#63 Update: started pony tailing her tops that are large enough to pin back without decapitating/severing the top . The top dress feeding I gave her still hasn’t become plant available yet. She’s still yellowing . I’ll be glad to see her park back up & continuing growing on. I purchased some worm castings I’ll top dress with a few tablespoons before watering her in & see if that perks her up until the Gaia Green is broken down. Shes almost tall enough to come down off that 1gall bucket even before transplant into a 6gal planter like the older girls finishing up .

Day 25 Did a single topping on one of the Pineapple Express Phenos. Just feed water ph to 6.00 area. Light is around 450-550 par

I’m unloading two weeks today was just busy last week and forgot to add

Massive colas! Massive yield from KTMD8 finicky on nutrients. Not for a novice. Not incredibly hard either though very very sticky! Petroleum, gas and sweet. Grape maybe.

Borax laundry detergent. Also known by its scientific name, sodium tetraborate. The atomic structure of sodium tetraborate, also known as borax, is made up of two tetrahedral boron atoms and two trigonal boron atoms in a fused bicyclic structure: Two fused distorted hexagonal (boroxole) rings and one distorted octagonal ring Anion Tetraborate anion (tetramer) with the formula B4O2−7 Sodium tetraborate, Na2B4O7 Sodium tetraborate is a naturally occurring, powdery, white mineral that is used in laundry detergent and cleaning supplies. It is an ionic compound that dissolves easily in warm water and reforms into large crystals when given a surface to attach to. Sodium = Salt Tetra = Greek "4" Borate = Boron After my 2 month coma stone we are back at it. New digs too. Experiments have shown that treating soil with magnetized water and/or low-frequency current (0.5 or 5 A) activates soil potassium and phosphorus, thereby increasing their bioavailability. 23. Chemical Abstracts 96: 49235b; ibid., 96: 67828b 24. Appl. Electr. Phenom. 6: 454-458 (Nov.-Dec. 1967) Aloe vera is ideal as a rooting powder alternative because it contains glucomannans, amino acids, sterols, and vitamins. Studies show that these help many types of species develop more and stronger roots when growing cuttings or propagating via air layering. Turmeric is an excellent natural rooting hormone Cinnamon as a rooting agent is as useful. Small mixture of all 3. The ancient tradition of Sacred Geometry is still alive and well in the person of Frank Chester. He has discovered a new geometric form that unites the five Platonic solids and provides some startling indications about the form and function of the human heart. This new form, called the Chestahedron, was discovered in 2000, and is a seven-sided polyhedron with surfaces of equal area. Frank has been exploring the form and its significance for over a decade, His work has potential implications across a number of areas, from physiology to architecture, sculpture, geology, and beyond. Organic cotton stands out with a frequency of 100, mirroring the human body's frequency. *burp* It's all about the salt https://www.seafriends.org.nz/oceano/seawater.htm Water will be moved counterclockwise around quartzite oxygenated. Plants need elements for normal growth. Three of them--carbon, hydrogen, and oxygen--are found in air and water. The rest are found in the soil. Six soil elements are called macronutrients because they are used in relatively large amounts by plants. They are nitrogen, potassium, magnesium, calcium, phosphorus, and sulfur. Eight other soil elements are used in much smaller amounts and are called micronutrients or trace elements. They are iron, zinc, molybdenum, manganese, boron, copper, cobalt, and chlorine. They make up less than 1% of the total but are nonetheless vital. Most of the nutrients a plant needs are dissolved in water and then absorbed by its roots. In fact, 98 percent are absorbed from the soil-water solution, and only about 2 percent are actually extracted from soil particles. on that note, some points of interest regarding Boron. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6073895/ Boron (B) is an essential trace element required for the physiological functioning of higher plants. B deficiency is considered as a nutritional disorder that adversely affects the metabolism and growth of plants. B is involved in the structural and functional integrity of the cell wall and membranes, ion fluxes (H+, K+, PO43−, Rb+, Ca2+) across the membranes, cell division and elongation, nitrogen and carbohydrate metabolism, sugar transport, cytoskeletal proteins, and plasmalemma-bound enzymes, nucleic acid, indoleacetic acid, polyamines, ascorbic acid, and phenol metabolism and transport. This review critically examines the functions of B in plants, deficiency symptoms, and the mechanism of B uptake and transport under limited B conditions. B deficiency can be mitigated by inorganic fertilizer supplementation, but the deleterious impact of frequent fertilizer application disrupts soil fertility and creates environmental pollution. Considering this, we have summarized the available information regarding alternative approaches, such as root structural modification, grafting, application of biostimulators (mycorrhizal fungi (MF) and rhizobacteria), and nanotechnology, that can be effectively utilized for B acquisition, leading to resource conservation. Additionally, we have discussed several new aspects, such as the combination of grafting or MF with nanotechnology, combined inoculation of arbuscular MF and rhizobacteria, melatonin application, and the use of natural and synthetic chelators, that possibly play a role in B uptake and translocation under B stress conditions. Apart from the data obtained from agricultural reports that prove the involvement of B in plant growth and development, B often results in deficiency or toxicity because it is a unique micronutrient for which the threshold levels of deficiency and toxicity are very narrow [12]. B deficiency and excess are both widespread agricultural problems for higher plants in arid and semi-arid conditions. B deficiency was primarily observed in apples growing in Australia in the 1930s and subsequently reported in more than 132 field crops grown in sandy soils with low pH and organic matter from 80 different countries [28]. Depending on the age and species, plants manifest a wide range of deficiency symptoms, including stunted root growth, restricted apical meristem growth, brittle leaves, reduced chlorophyll content and photosynthetic activity, disruption in ion transport, increased phenolic and lignin contents, and reduced crop yield [1,8,20]. The prevalence of symptoms depends on the severity of the B-deficiency condition because plants show uniform deficiency symptoms on entire leaves but sometimes in the form of isolated patches. Given the immobile nature of B, it usually accumulates in mature leaves, whereas young leaves do not receive sufficient B for proper growth. Thus, the deficiency symptoms first appear on young leaves, including thick, curled, and brittle leaves with reduced leaf expansion; corky veins; interveinal chlorosis; yellow water-soaked spots on lamina; and a short internodal distance, resulting in a bushy plant appearance [14,29,30]. In severe cases, leaf apex necrosis and leaf dieback occur [12]. The expansion of stems and petioles leads to hollow stem disorder in broccoli and stem crack symptoms in celery [1]. However, in tomato, cauliflower, apple, and citrus, scaly surface development with internal and external corking of fruits is a typical feature associated with B deficiency [13,28]. Amino acids improve plant nutrition by affecting soil microbial activity through the production of a beneficial microbial community and nutrient mineralization in the soil solution, thus enhancing micronutrient mobility [84]. Seaweed extract contains several ions, growth regulators, carbohydrates, proteins, vitamins, and polyuronides, including alginates and fucoidans. These polyuronides can form highly cross-linked polymers and condition the soil, thereby improving the water retention and ion uptake capacity within the soil [89]. Kahydrin, a commercial seaweed component, acidifies the rhizosphere by altering the plasma membrane proton pump and secretes H+ ions that change the soil redox condition and make the metal ions available to plants, leading to improved crop production [90]. Turan and Kose [91] applied three seaweed extracts, including Maxicrop, Algipower, and Proton, on grapevine (Vitis vinifera L. cv. Karaerik) to check the ion uptake efficacy under optimal and deficient ion availability. Maximum micronutrient uptake under optimal conditions were observed with no significant difference among the three kinds of extracts. The alteration in uptake of one ion influences the availability of another ion [85], supporting the idea of B uptake through biostimulator application, but this requires further investigation. The application of biofertilizers opens new routes of ion acquisition by increasing nutrient use efficiency in plants. In this regard, mycorrhizal and non-mycorrhizal fungi, endosymbiotic bacteria, and plant-growth-promoting rhizobacteria are important because of their dual function as microbial biostimulants and biocontrol agents. We explain the functions of these biostimulators and their possible relationship with ion acquisition in plants. Indeed, grafting and AMF inoculation improve plant physiological and nutritional aspects and a number of studies have proved their pivotal role in B uptake [74,75,79,105]. Additionally, nanotechnology is an emerging technique to solve plant-nutrition-related problems. The combination of these techniques may improve B uptake. For instance, a combination of grafting and Cu NPs improved growth and development of watermelon by increasing ion uptake [129]. Melatonin application improves plant performance by inducing resistance against stress conditions. According to a report, melatonin application reversed the toxic effect of B by moderating B accumulation in leaf and fruit, increasing photosynthetic activity, and improving dry weight that ultimately enhanced plant growth of Capsicum annuum [138]. Similarly, in watermelon, melatonin application enhanced the N concentration in roots by improving root elongation, root diameter, and root surface area under limited N availability [61]. However, no evidence for B uptake under deficient conditions has been found yet, and that requires further investigation. https://pubmed.ncbi.nlm.nih.gov/8508192/ https://pubmed.ncbi.nlm.nih.gov/34988929/

Borax laundry detergent. Also known by its scientific name, sodium tetraborate. The atomic structure of sodium tetraborate, also known as borax, is made up of two tetrahedral boron atoms and two trigonal boron atoms in a fused bicyclic structure: Two fused distorted hexagonal (boroxole) rings and one distorted octagonal ring Anion Tetraborate anion (tetramer) with the formula B4O2−7 Sodium tetraborate, Na2B4O7 Sodium tetraborate is a naturally occurring, powdery, white mineral that is used in laundry detergent and cleaning supplies. It is an ionic compound that dissolves easily in warm water and reforms into large crystals when given a surface to attach to. Sodium = Salt Tetra = Greek "4" Borate = Boron After my 2 month coma stone we are back at it. New digs too. Experiments have shown that treating soil with magnetized water and/or low-frequency current (0.5 or 5 A) activates soil potassium and phosphorus, thereby increasing their bioavailability. 23. Chemical Abstracts 96: 49235b; ibid., 96: 67828b 24. Appl. Electr. Phenom. 6: 454-458 (Nov.-Dec. 1967) Aloe vera is ideal as a rooting powder alternative because it contains glucomannans, amino acids, sterols, and vitamins. Studies show that these help many types of species develop more and stronger roots when growing cuttings or propagating via air layering. The ancient tradition of Sacred Geometry is still alive and well in the person of Frank Chester. He has discovered a new geometric form that unites the five Platonic solids and provides some startling indications about the form and function of the human heart. This new form, called the Chestahedron, was discovered in 2000, and is a seven-sided polyhedron with surfaces of equal area. Frank has been exploring the form and its significance for over a decade, His work has potential implications across a number of areas, from physiology to architecture, sculpture, geology, and beyond. Organic cotton stands out with a frequency of 100, mirroring the human body's frequency. *burp* It's all about the salt https://www.seafriends.org.nz/oceano/seawater.htm Water will be moved counterclockwise around quartzite oxygenated. Plants need elements for normal growth. Three of them--carbon, hydrogen, and oxygen--are found in air and water. The rest are found in the soil. Six soil elements are called macronutrients because they are used in relatively large amounts by plants. They are nitrogen, potassium, magnesium, calcium, phosphorus, and sulfur. Eight other soil elements are used in much smaller amounts and are called micronutrients or trace elements. They are iron, zinc, molybdenum, manganese, boron, copper, cobalt, and chlorine. They make up less than 1% of the total but are nonetheless vital. Most of the nutrients a plant needs are dissolved in water and then absorbed by its roots. In fact, 98 percent are absorbed from the soil-water solution, and only about 2 percent are actually extracted from soil particles. on that note, some points of interest regarding Boron. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6073895/ Boron (B) is an essential trace element required for the physiological functioning of higher plants. B deficiency is considered as a nutritional disorder that adversely affects the metabolism and growth of plants. B is involved in the structural and functional integrity of the cell wall and membranes, ion fluxes (H+, K+, PO43−, Rb+, Ca2+) across the membranes, cell division and elongation, nitrogen and carbohydrate metabolism, sugar transport, cytoskeletal proteins, and plasmalemma-bound enzymes, nucleic acid, indoleacetic acid, polyamines, ascorbic acid, and phenol metabolism and transport. This review critically examines the functions of B in plants, deficiency symptoms, and the mechanism of B uptake and transport under limited B conditions. B deficiency can be mitigated by inorganic fertilizer supplementation, but the deleterious impact of frequent fertilizer application disrupts soil fertility and creates environmental pollution. Considering this, we have summarized the available information regarding alternative approaches, such as root structural modification, grafting, application of biostimulators (mycorrhizal fungi (MF) and rhizobacteria), and nanotechnology, that can be effectively utilized for B acquisition, leading to resource conservation. Additionally, we have discussed several new aspects, such as the combination of grafting or MF with nanotechnology, combined inoculation of arbuscular MF and rhizobacteria, melatonin application, and the use of natural and synthetic chelators, that possibly play a role in B uptake and translocation under B stress conditions. Apart from the data obtained from agricultural reports that prove the involvement of B in plant growth and development, B often results in deficiency or toxicity because it is a unique micronutrient for which the threshold levels of deficiency and toxicity are very narrow [12]. B deficiency and excess are both widespread agricultural problems for higher plants in arid and semi-arid conditions. B deficiency was primarily observed in apples growing in Australia in the 1930s and subsequently reported in more than 132 field crops grown in sandy soils with low pH and organic matter from 80 different countries [28]. Depending on the age and species, plants manifest a wide range of deficiency symptoms, including stunted root growth, restricted apical meristem growth, brittle leaves, reduced chlorophyll content and photosynthetic activity, disruption in ion transport, increased phenolic and lignin contents, and reduced crop yield [1,8,20]. The prevalence of symptoms depends on the severity of the B-deficiency condition because plants show uniform deficiency symptoms on entire leaves but sometimes in the form of isolated patches. Given the immobile nature of B, it usually accumulates in mature leaves, whereas young leaves do not receive sufficient B for proper growth. Thus, the deficiency symptoms first appear on young leaves, including thick, curled, and brittle leaves with reduced leaf expansion; corky veins; interveinal chlorosis; yellow water-soaked spots on lamina; and a short internodal distance, resulting in a bushy plant appearance [14,29,30]. In severe cases, leaf apex necrosis and leaf dieback occur [12]. The expansion of stems and petioles leads to hollow stem disorder in broccoli and stem crack symptoms in celery [1]. However, in tomato, cauliflower, apple, and citrus, scaly surface development with internal and external corking of fruits is a typical feature associated with B deficiency [13,28]. Amino acids improve plant nutrition by affecting soil microbial activity through the production of a beneficial microbial community and nutrient mineralization in the soil solution, thus enhancing micronutrient mobility [84]. Seaweed extract contains several ions, growth regulators, carbohydrates, proteins, vitamins, and polyuronides, including alginates and fucoidans. These polyuronides can form highly cross-linked polymers and condition the soil, thereby improving the water retention and ion uptake capacity within the soil [89]. Kahydrin, a commercial seaweed component, acidifies the rhizosphere by altering the plasma membrane proton pump and secretes H+ ions that change the soil redox condition and make the metal ions available to plants, leading to improved crop production [90]. Turan and Kose [91] applied three seaweed extracts, including Maxicrop, Algipower, and Proton, on grapevine (Vitis vinifera L. cv. Karaerik) to check the ion uptake efficacy under optimal and deficient ion availability. Maximum micronutrient uptake under optimal conditions were observed with no significant difference among the three kinds of extracts. The alteration in uptake of one ion influences the availability of another ion [85], supporting the idea of B uptake through biostimulator application, but this requires further investigation. The application of biofertilizers opens new routes of ion acquisition by increasing nutrient use efficiency in plants. In this regard, mycorrhizal and non-mycorrhizal fungi, endosymbiotic bacteria, and plant-growth-promoting rhizobacteria are important because of their dual function as microbial biostimulants and biocontrol agents. We explain the functions of these biostimulators and their possible relationship with ion acquisition in plants. Indeed, grafting and AMF inoculation improve plant physiological and nutritional aspects and a number of studies have proved their pivotal role in B uptake [74,75,79,105]. Additionally, nanotechnology is an emerging technique to solve plant-nutrition-related problems. The combination of these techniques may improve B uptake. For instance, a combination of grafting and Cu NPs improved growth and development of watermelon by increasing ion uptake [129]. Melatonin application improves plant performance by inducing resistance against stress conditions. According to a report, melatonin application reversed the toxic effect of B by moderating B accumulation in leaf and fruit, increasing photosynthetic activity, and improving dry weight that ultimately enhanced plant growth of Capsicum annuum [138]. Similarly, in watermelon, melatonin application enhanced the N concentration in roots by improving root elongation, root diameter, and root surface area under limited N availability [61]. However, no evidence for B uptake under deficient conditions has been found yet, and that requires further investigation. https://pubmed.ncbi.nlm.nih.gov/8508192/ https://pubmed.ncbi.nlm.nih.gov/34988929/

What a gorgeous strain. Full of purple hue and terps for days with the petroleum, gas, sweet grape. We will see how it changes after a long cure. Chopped her on the 11th week of flower at about 15% amber. Has a pretty heady Stoney high, euphoria, body buzz. Not a couchlock but definitely sedated but functional.

12-28 Scc got plain ph water. 3x got none. Just a day to show off their moves. 😂🤘 Scc is happy. I suspect she may not like plain water though. 12-29 3x plain ph water. 12-30 Scc half tsp build a bloom ( I put ml last week, think it was stuck in my head 😂), 1/2 tsp recharge, 1/8th tsp kelp and 1 ml drops. Upped the dose of build bloom from 1/4 to half tsp. Was only 310 ppm after stiring and desolving for several hours. Felt low, but taking it slow. 3x gets all the goodies on her next! . 12-31 Started a 2 gallon tea. 1/4 cup poo, 1 1/2 tsp build a bloom, 2 ml drops, 1/8 tsp kelp, 1/2 tsp recharge, 1 tbs molasses. Bubble bubble. Ppm is 612 brewing. 24 hrs Bring in the new year with some goodies! 💪🤘 Happy New Year! 1-1 Gabe them both the tea. Ppm was 623 ph 6.2. Mmm

12-28 Scc got plain ph water. 3x got none. Just a day to show off their moves. 😂🤘 Scc is happy. I suspect she may not like plain water though. 12-29 3x plain ph water. 12-30 Scc half tsp build a bloom ( I put ml last week, think it was stuck in my head 😂), 1/2 tsp recharge, 1/8th tsp kelp and 1 ml drops. Upped the dose of build bloom from 1/4 to half tsp. Was only 310 ppm after stiring and desolving for several hours. Felt low, but taking it slow. 3x gets all the goodies on her next! . 12-31 Started a 2 gallon tea. 1/4 cup poo, 1 1/2 tsp build a bloom, 2 ml drops, 1/8 tsp kelp, 1/2 tsp recharge, 1 tbs molasses. Bubble bubble. Ppm is 612 brewing. 24 hrs Bring in the new year with some goodies! 💪🤘 Happy New Year! 1-1 Gabe them both the tea. Ppm was 623 ph 6.2. Mmm

See

Week III

Just feed water ph to 6.00 area.

Just feed water ph to 6.00 area.

Just feed water ph to 6.00 area.

Just feed water ph to 6.00 area.

Just feed water ph to 6.00 area.

Mildew was detected in the beginning if the week, the plant sprayed with solution of hydro peroxide to kill spores and then solution of apple vinegar to stop prevent new mold. It worked. I thenk the next eeek will be the last. I decreased 5he concentration of the watering solution, especially in Nitrogen part.

Flower !

Now its drying... I Will update soon