2
4
Share
Waiting till she's big enuf to clone a whole tribe from her next big run only freak show
7
46
Share
This plant was an absolute dream to. Grow, no issues at all with health of plant, just struggled to tame her as she was a a thick strong climber 💪💪. I'm so impressed with how this turned out, I could have flushed for another 3 days to make it 12days but I needed the space. After The 2 days of dark I was recommended I can definitely say it has vastly boosted her trichomes and the smell when I opened the tent blew my head away 😍😋 Aiming for a 10-14 day hang dry, The 10-12 weeks curing in jars with humidity packs. I will update with a dry bud weight and smoke test 👌 Bud wet weight is just 500g+ Final bud dry weight is 298g. Of juicy resinous purple and orange buds 😍 smells like sherbert and hang dry smoke test revealed a candy sherbert, no banana yet but hoping like the grow it matures with cure process now. Hits eyes straight away, sandy bottom kids, giggles, munchies, fun time with Mrs, bed. Full cycle with this one very happy over here 😉😁💚 FAT BANANA AUTO FROM ROYAL QUEEN SEEDS, big thank you to the team, and the breaders. What a pheno I received. I appreciate you all
2
7
Share
@Adam22
Follow
I am waiting to start some more seeds I already have them but another tent is needed and a couple of leds, good ones. It will take a few weeks to sort and as usual I have some inspections on the house I need to try and time carefully around 🤔 I did have 2 during this grow the first was in veg luckily they grew in a closet the second was week 3 flower (don't ask) The smell didn't stink out the room like the wedding cake did so I will try and cure this as long as possible to last this as close to next harvest as possible 😅 my cats didn't eat my plants this time so thats another bonus. Need to look into getting a proper air circulation for the new tent I used a fan the whole time my tent was wide open I want to have it sealed next time so I can fully zip it closed ffs lol defo would recommend this strain but I don't think they stock these anymore 😕 I got a coupe seeds from the first plant I was right the pic of the top bud a few weeks ago you can see the seed just about forming after the branch got broken off we will live and learn 😉
5
2
Share
1
3
Share
I am loving this plant!! Her buds are deep deep purple and super dense and covered in trichs!!! The smell is awesome....sweet and fruity with gasseyness, pretty sure that's not a word. This is going to be a great grow!! Thank you @
3
4
Share
It was a 8 day dry and cured for bout a month I was left with 1 oz dry wait. the aroma of the buds were a strong musty jet-fule and fermented fruit 🍉. Braking it down by hand left my fingers sticky and covered in triphones❄️ so I switched to the grinder . When smoking the inhale you get a sweet jet-fule taste with a hit of pineapple on the exhale 😮‍💨 it taste like a dank watermelon pineapple smoothie. I role my self a gram maybe a lil more but the first couple hits really hit the chest and left me with a energetic head high but half way through the joint It was a relaxing full body high that left me feeling like I was floating through time. Is this girl and really want to grow her again.
Likes
45
Share
280nm = More than just a metric for a color of light, it is the frequency of the wave oscillation, 280nm is 0.00000028 meters, 2.8 x 10-7. For everything created by God is good, and nothing is to be rejected if it is received with thanksgiving, for it is made holy by the word of God and prayer (1 Timothy 4:4–5). Once a truck at work full of earth mixed with metal set off our radiation detector, after 4 positive tests for high radiation levels, the entire 18 wheeler had to be emptied and checked to find the source. No one could find anything, the nuclear technicians had to be called. they found that the rainwater had seeped out all the fertilizer from the soil, it was pottasium build-up to my disbelief. Unbeknown to us the earth was dug up from farmland. This was the backstory that set me off on a quest for this knowledge im about to share, I thought it was frickin awesome sauce. *puff puff pass* THORIUM Thorium, at atomic number 90, is one of the rarest elements. Named after Thor the God of thunder. 232Th is a primordial nuclide, having existed in its current form for over ten billion years; it was formed during the r-process, which probably occurs in supernovae and neutron star mergers. These violent events scattered it across the galaxy. The letter "r" stands for "rapid neutron capture", and occurs in core-collapse supernovae, where heavy seed nuclei such as 56Fe rapidly capture neutrons, running up against the neutron drip line, as neutrons are captured much faster than the resulting nuclides can beta decay back toward stability. Neutron capture is the only way for stars to synthesize elements beyond iron because of the increased Coulomb barriers that make interactions between charged particles difficult at high atomic numbers and the fact that fusion beyond 56Fe is endothermic. Because of the abrupt loss of stability past 209Bi, the r-process is the only process of stellar nucleosynthesis that can create thorium and uranium; all other processes are too slow and the intermediate nuclei alpha decay before they capture enough neutrons to reach these elements. Thorium is a naturally-occurring chemical element with atomic number 90, which means there are 90 protons and 90 electrons in the atomic structure. The chemical symbol for thorium is Th. Thorium was discovered in 1828 by Norwegian mineralogist Morten Thrane Esmark. Joens Jakob Berzelius, the Swedish chemist, named it after Thor, the Norse god of thunder. Thorium is a naturally-occurring element estimated to be about three times more abundant than uranium. Thorium is commonly found in monazite sands (rare earth metals containing phosphate minerals). Thorium has 6 naturally occurring isotopes. All of these isotopes are unstable (radioactive), but only 232Th is relatively stable with a half-life of 14 billion years, which is comparable to the age of the Earth (~4.5×109 years). Isotope 232Th belongs to primordial nuclides, and natural thorium consists primarily of isotope 232Th. Other isotopes (230Th, 229Th, 228Th, 234Th, and 227Th) occur in nature as trace radioisotopes, which originate from the decay of 232Th, 235U, and 238U. Histogram of estimated abundances of the 83 primordial elements in the Solar system Estimated abundances of the 83 primordial elements in the Solar system, plotted on a logarithmic scale. Thorium, at atomic number 90, is one of the rarest elements. In the universe, thorium is among the rarest of the primordial elements, because it is one of the two elements that can be produced only in the r-process (the other being uranium). POTASSIUM Potassium 40 is a radioisotope that can be found in trace amounts in natural potassium, is at the origin of more than half of the human body activity: undergoing between 4 and 5,000 decays every second for an 80kg man. Along with uranium and thorium, potassium contributes to the natural radioactivity of rocks and hence to the H"Earth". This isotope makes up one ten-thousandth of the potassium found naturally. In terms of atomic weight, it is located between two more stable and far more abundant isotopes (potassium 39 and potassium 41) that make up 93.25% and 6.73% of the Earth total potassium supply respectively. With a half-life of 1,251 billion years, potassium 40 existed in the remnants of dead stars whose agglomeration has led to the Solar System with its planets. Potassium 40 has the unusual property of decaying into two different nuclei: in 89% of cases beta-negative decay will lead to calcium 40, while 11% of the time argon 40 will be formed by electron capture followed by gamma emission at an energy of 1.46 MeV. This 1.46 MeV gamma ray is important, as it allows us to identify when potassium 40 decays. The beta electrons leading to calcium, however, are not accompanied by gamma rays, have no characteristic energies and rarely make it out of the rocks or bodies that contain potassium 40. Beta-minus decay indicates a nucleus with too many neutrons, electron capture a nucleus with too many protons. How can potassium 40 simultaneously have too many of both? The answer reveals one of the peculiarities of the nuclear forces. Everyone alive has roughly 140g of potassium = *0.016 grams of Potassium Isotope 40* The charge radius is a fundamental property of the atomic nucleus. Although it globally scales with the nuclear mass as A1/3, the nuclear charge radius also exhibits appreciable isotopic variations that are the result of complex interactions between protons and neutrons. Indeed, charge radii reflect various nuclear structure phenomena such as halo structures6, shape staggering7, shape coexistence8, pairing correlations9,10, neutron skins11, and the occurrence of nuclear magic numbers5,12,13. The term ‘magic number’ refers to the number of protons or neutrons corresponding to completely filled shells. In charge radii, a shell closure is observed as a sudden increase in the charge radius of the isotope just beyond magic shell closure, as seen, for example, at the well-known magic numbers N = 28, 50, 82 and 126 (refs. 5,12–14). In the nuclear mass region near potassium, the isotopes with proton number Z ≈ 20 and neutron number N = 32 are proposed to be magic on the basis of an observed sudden decrease in their binding energy beyond N = 32 (refs. 2,3) and the high excitation energy of the first excited state in 52Ca (ref. 1). Therefore, the experimentally observed a strong increase in the charge radii of calcium4 and potassium5 isotopes between N = 28 and N = 32, and in particular the large radius of 51K and 52Ca (both having 32 neutrons), have attracted substantial attention. https://www.nature.com/articles/s41567-020-01136-5.pdf “A cat has 9 lives” “On cloud 9” “Dressed to the nines” To go “the whole nine yards” “A stitch in time saves nine” “Nine-ness” seems to be synonymous with the maximum, with the furthest extent of what’s possible. With fullness, completion, and when every effort has been exhausted. In the ancient world (which is, let’s face it, is where numbers and their spiritual power were understood SO much more than they are today) the number 9 resonated with sacred structure, and the furthest limitations of this world, before human experience meets the Divine. Perhaps more than any other, the number nine had an extra special significance, which spread far and wide. It features across pretty much all cultures, worldwide, rippling through culture, mythology, history, law and time. Nine is the central number in the ancient Celtic tradition. Nine expresses through the triple Goddess (see Number 3) and in myths of the nine Celtic maidens, or sorceresses. In fact, stories of nine mystical women presiding over nature spread from England, Ireland and Wales, to Scandinavia, Iceland and even as far as Kenya. Even today, it’s tradition for nine groups of nine men to dance around Beltane fires. The limit of winter (which is what Beltane Almost all of the mythological tales from around the world have patterns of the number 9 weaving throughout. The Northern European sagas tell of Odin, who rules over the nine Norse worlds. His trial, to win the secrets of wisdom for mankind, was to hang on the Yggdrasil tree for nine days. Demeter, the Greek Goddess of the Earth searched for nine days for her daughter Persephone (who was in the underworld with Hades). Demeter is often depicted holding nine pieces of corn. Once recovered, Persephone was obliged to spend three months per year below the ground, and nine months above. Native American, Mayan and Aztec myths tell of a total of nine cosmic levels (and many of the temples comprise 9 stories). And in ancient China, nine was the most auspicious number of divine power: the Chinese had nine sacred rites, nine social laws, nine classes of officials in the government and built nine-story pagodas. In astrology, the planet Mars vibrates to the frequency of the nine. The ninth sign of the Zodiac is Sagittarius (where the Sun sails from November 22nd – December 21st) In Tarot, card number nine is the Hermit. In Hinduism, nine is the number of Brahma. In the Greek Sagas, the city of Troy was under siege for nine years. Azomite has 180ppm Thorium iirc.
Likes
45
Share
280nm = More than just a metric for a color of light, it is the frequency of the wave oscillation, 280nm is 0.00000028 meters, 2.8 x 10-7. For everything created by God is good, and nothing is to be rejected if it is received with thanksgiving, for it is made holy by the word of God and prayer (1 Timothy 4:4–5). Once a truck at work full of earth mixed with metal set off our radiation detector, after 4 positive tests for high radiation levels, the entire 18 wheeler had to be emptied and checked to find the source. No one could find anything, the nuclear technicians had to be called. they found that the rainwater had seeped out all the fertilizer from the soil, it was pottasium build-up to my disbelief. Unbeknown to us the earth was dug up from farmland. This was the backstory that set me off on a quest for this knowledge im about to share, I thought it was frickin awesome sauce. *puff puff pass* THORIUM Thorium, at atomic number 90, is one of the rarest elements. Named after Thor the God of thunder. 232Th is a primordial nuclide, having existed in its current form for over ten billion years; it was formed during the r-process, which probably occurs in supernovae and neutron star mergers. These violent events scattered it across the galaxy. The letter "r" stands for "rapid neutron capture", and occurs in core-collapse supernovae, where heavy seed nuclei such as 56Fe rapidly capture neutrons, running up against the neutron drip line, as neutrons are captured much faster than the resulting nuclides can beta decay back toward stability. Neutron capture is the only way for stars to synthesize elements beyond iron because of the increased Coulomb barriers that make interactions between charged particles difficult at high atomic numbers and the fact that fusion beyond 56Fe is endothermic. Because of the abrupt loss of stability past 209Bi, the r-process is the only process of stellar nucleosynthesis that can create thorium and uranium; all other processes are too slow and the intermediate nuclei alpha decay before they capture enough neutrons to reach these elements. Thorium is a naturally-occurring chemical element with atomic number 90, which means there are 90 protons and 90 electrons in the atomic structure. The chemical symbol for thorium is Th. Thorium was discovered in 1828 by Norwegian mineralogist Morten Thrane Esmark. Joens Jakob Berzelius, the Swedish chemist, named it after Thor, the Norse god of thunder. Thorium is a naturally-occurring element estimated to be about three times more abundant than uranium. Thorium is commonly found in monazite sands (rare earth metals containing phosphate minerals). Thorium has 6 naturally occurring isotopes. All of these isotopes are unstable (radioactive), but only 232Th is relatively stable with a half-life of 14 billion years, which is comparable to the age of the Earth (~4.5×109 years). Isotope 232Th belongs to primordial nuclides, and natural thorium consists primarily of isotope 232Th. Other isotopes (230Th, 229Th, 228Th, 234Th, and 227Th) occur in nature as trace radioisotopes, which originate from the decay of 232Th, 235U, and 238U. Histogram of estimated abundances of the 83 primordial elements in the Solar system Estimated abundances of the 83 primordial elements in the Solar system, plotted on a logarithmic scale. Thorium, at atomic number 90, is one of the rarest elements. In the universe, thorium is among the rarest of the primordial elements, because it is one of the two elements that can be produced only in the r-process (the other being uranium). POTASSIUM Potassium 40 is a radioisotope that can be found in trace amounts in natural potassium, is at the origin of more than half of the human body activity: undergoing between 4 and 5,000 decays every second for an 80kg man. Along with uranium and thorium, potassium contributes to the natural radioactivity of rocks and hence to the H"Earth". This isotope makes up one ten-thousandth of the potassium found naturally. In terms of atomic weight, it is located between two more stable and far more abundant isotopes (potassium 39 and potassium 41) that make up 93.25% and 6.73% of the Earth total potassium supply respectively. With a half-life of 1,251 billion years, potassium 40 existed in the remnants of dead stars whose agglomeration has led to the Solar System with its planets. Potassium 40 has the unusual property of decaying into two different nuclei: in 89% of cases beta-negative decay will lead to calcium 40, while 11% of the time argon 40 will be formed by electron capture followed by gamma emission at an energy of 1.46 MeV. This 1.46 MeV gamma ray is important, as it allows us to identify when potassium 40 decays. The beta electrons leading to calcium, however, are not accompanied by gamma rays, have no characteristic energies and rarely make it out of the rocks or bodies that contain potassium 40. Beta-minus decay indicates a nucleus with too many neutrons, electron capture a nucleus with too many protons. How can potassium 40 simultaneously have too many of both? The answer reveals one of the peculiarities of the nuclear forces. Everyone alive has roughly 140g of potassium = *0.016 grams of Potassium Isotope 40* The charge radius is a fundamental property of the atomic nucleus. Although it globally scales with the nuclear mass as A1/3, the nuclear charge radius also exhibits appreciable isotopic variations that are the result of complex interactions between protons and neutrons. Indeed, charge radii reflect various nuclear structure phenomena such as halo structures6, shape staggering7, shape coexistence8, pairing correlations9,10, neutron skins11, and the occurrence of nuclear magic numbers5,12,13. The term ‘magic number’ refers to the number of protons or neutrons corresponding to completely filled shells. In charge radii, a shell closure is observed as a sudden increase in the charge radius of the isotope just beyond magic shell closure, as seen, for example, at the well-known magic numbers N = 28, 50, 82 and 126 (refs. 5,12–14). In the nuclear mass region near potassium, the isotopes with proton number Z ≈ 20 and neutron number N = 32 are proposed to be magic on the basis of an observed sudden decrease in their binding energy beyond N = 32 (refs. 2,3) and the high excitation energy of the first excited state in 52Ca (ref. 1). Therefore, the experimentally observed a strong increase in the charge radii of calcium4 and potassium5 isotopes between N = 28 and N = 32, and in particular the large radius of 51K and 52Ca (both having 32 neutrons), have attracted substantial attention. https://www.nature.com/articles/s41567-020-01136-5.pdf “A cat has 9 lives” “On cloud 9” “Dressed to the nines” To go “the whole nine yards” “A stitch in time saves nine” “Nine-ness” seems to be synonymous with the maximum, with the furthest extent of what’s possible. With fullness, completion, and when every effort has been exhausted. In the ancient world (which is, let’s face it, is where numbers and their spiritual power were understood SO much more than they are today) the number 9 resonated with sacred structure, and the furthest limitations of this world, before human experience meets the Divine. Perhaps more than any other, the number nine had an extra special significance, which spread far and wide. It features across pretty much all cultures, worldwide, rippling through culture, mythology, history, law and time. Nine is the central number in the ancient Celtic tradition. Nine expresses through the triple Goddess (see Number 3) and in myths of the nine Celtic maidens, or sorceresses. In fact, stories of nine mystical women presiding over nature spread from England, Ireland and Wales, to Scandinavia, Iceland and even as far as Kenya. Even today, it’s tradition for nine groups of nine men to dance around Beltane fires. The limit of winter (which is what Beltane Almost all of the mythological tales from around the world have patterns of the number 9 weaving throughout. The Northern European sagas tell of Odin, who rules over the nine Norse worlds. His trial, to win the secrets of wisdom for mankind, was to hang on the Yggdrasil tree for nine days. Demeter, the Greek Goddess of the Earth searched for nine days for her daughter Persephone (who was in the underworld with Hades). Demeter is often depicted holding nine pieces of corn. Once recovered, Persephone was obliged to spend three months per year below the ground, and nine months above. Native American, Mayan and Aztec myths tell of a total of nine cosmic levels (and many of the temples comprise 9 stories). And in ancient China, nine was the most auspicious number of divine power: the Chinese had nine sacred rites, nine social laws, nine classes of officials in the government and built nine-story pagodas. In astrology, the planet Mars vibrates to the frequency of the nine. The ninth sign of the Zodiac is Sagittarius (where the Sun sails from November 22nd – December 21st) In Tarot, card number nine is the Hermit. In Hinduism, nine is the number of Brahma. In the Greek Sagas, the city of Troy was under siege for nine years. Azomite has 180ppm Thorium iirc.
Likes
45
Share
280nm = More than just a metric for a color of light, it is the frequency of the wave oscillation, 280nm is 0.00000028 meters, 2.8 x 10-7. For everything created by God is good, and nothing is to be rejected if it is received with thanksgiving, for it is made holy by the word of God and prayer (1 Timothy 4:4–5). Once a truck at work full of earth mixed with metal set off our radiation detector, after 4 positive tests for high radiation levels, the entire 18 wheeler had to be emptied and checked to find the source. No one could find anything, the nuclear technicians had to be called. they found that the rainwater had seeped out all the fertilizer from the soil, it was pottasium build-up to my disbelief. Unbeknown to us the earth was dug up from farmland. This was the backstory that set me off on a quest for this knowledge im about to share, I thought it was frickin awesome sauce. *puff puff pass* THORIUM Thorium, at atomic number 90, is one of the rarest elements. Named after Thor the God of thunder. 232Th is a primordial nuclide, having existed in its current form for over ten billion years; it was formed during the r-process, which probably occurs in supernovae and neutron star mergers. These violent events scattered it across the galaxy. The letter "r" stands for "rapid neutron capture", and occurs in core-collapse supernovae, where heavy seed nuclei such as 56Fe rapidly capture neutrons, running up against the neutron drip line, as neutrons are captured much faster than the resulting nuclides can beta decay back toward stability. Neutron capture is the only way for stars to synthesize elements beyond iron because of the increased Coulomb barriers that make interactions between charged particles difficult at high atomic numbers and the fact that fusion beyond 56Fe is endothermic. Because of the abrupt loss of stability past 209Bi, the r-process is the only process of stellar nucleosynthesis that can create thorium and uranium; all other processes are too slow and the intermediate nuclei alpha decay before they capture enough neutrons to reach these elements. Thorium is a naturally-occurring chemical element with atomic number 90, which means there are 90 protons and 90 electrons in the atomic structure. The chemical symbol for thorium is Th. Thorium was discovered in 1828 by Norwegian mineralogist Morten Thrane Esmark. Joens Jakob Berzelius, the Swedish chemist, named it after Thor, the Norse god of thunder. Thorium is a naturally-occurring element estimated to be about three times more abundant than uranium. Thorium is commonly found in monazite sands (rare earth metals containing phosphate minerals). Thorium has 6 naturally occurring isotopes. All of these isotopes are unstable (radioactive), but only 232Th is relatively stable with a half-life of 14 billion years, which is comparable to the age of the Earth (~4.5×109 years). Isotope 232Th belongs to primordial nuclides, and natural thorium consists primarily of isotope 232Th. Other isotopes (230Th, 229Th, 228Th, 234Th, and 227Th) occur in nature as trace radioisotopes, which originate from the decay of 232Th, 235U, and 238U. Histogram of estimated abundances of the 83 primordial elements in the Solar system Estimated abundances of the 83 primordial elements in the Solar system, plotted on a logarithmic scale. Thorium, at atomic number 90, is one of the rarest elements. In the universe, thorium is among the rarest of the primordial elements, because it is one of the two elements that can be produced only in the r-process (the other being uranium). POTASSIUM Potassium 40 is a radioisotope that can be found in trace amounts in natural potassium, is at the origin of more than half of the human body activity: undergoing between 4 and 5,000 decays every second for an 80kg man. Along with uranium and thorium, potassium contributes to the natural radioactivity of rocks and hence to the H"Earth". This isotope makes up one ten-thousandth of the potassium found naturally. In terms of atomic weight, it is located between two more stable and far more abundant isotopes (potassium 39 and potassium 41) that make up 93.25% and 6.73% of the Earth total potassium supply respectively. With a half-life of 1,251 billion years, potassium 40 existed in the remnants of dead stars whose agglomeration has led to the Solar System with its planets. Potassium 40 has the unusual property of decaying into two different nuclei: in 89% of cases beta-negative decay will lead to calcium 40, while 11% of the time argon 40 will be formed by electron capture followed by gamma emission at an energy of 1.46 MeV. This 1.46 MeV gamma ray is important, as it allows us to identify when potassium 40 decays. The beta electrons leading to calcium, however, are not accompanied by gamma rays, have no characteristic energies and rarely make it out of the rocks or bodies that contain potassium 40. Beta-minus decay indicates a nucleus with too many neutrons, electron capture a nucleus with too many protons. How can potassium 40 simultaneously have too many of both? The answer reveals one of the peculiarities of the nuclear forces. Everyone alive has roughly 140g of potassium = *0.016 grams of Potassium Isotope 40* The charge radius is a fundamental property of the atomic nucleus. Although it globally scales with the nuclear mass as A1/3, the nuclear charge radius also exhibits appreciable isotopic variations that are the result of complex interactions between protons and neutrons. Indeed, charge radii reflect various nuclear structure phenomena such as halo structures6, shape staggering7, shape coexistence8, pairing correlations9,10, neutron skins11, and the occurrence of nuclear magic numbers5,12,13. The term ‘magic number’ refers to the number of protons or neutrons corresponding to completely filled shells. In charge radii, a shell closure is observed as a sudden increase in the charge radius of the isotope just beyond magic shell closure, as seen, for example, at the well-known magic numbers N = 28, 50, 82 and 126 (refs. 5,12–14). In the nuclear mass region near potassium, the isotopes with proton number Z ≈ 20 and neutron number N = 32 are proposed to be magic on the basis of an observed sudden decrease in their binding energy beyond N = 32 (refs. 2,3) and the high excitation energy of the first excited state in 52Ca (ref. 1). Therefore, the experimentally observed a strong increase in the charge radii of calcium4 and potassium5 isotopes between N = 28 and N = 32, and in particular the large radius of 51K and 52Ca (both having 32 neutrons), have attracted substantial attention. https://www.nature.com/articles/s41567-020-01136-5.pdf “A cat has 9 lives” “On cloud 9” “Dressed to the nines” To go “the whole nine yards” “A stitch in time saves nine” “Nine-ness” seems to be synonymous with the maximum, with the furthest extent of what’s possible. With fullness, completion, and when every effort has been exhausted. In the ancient world (which is, let’s face it, is where numbers and their spiritual power were understood SO much more than they are today) the number 9 resonated with sacred structure, and the furthest limitations of this world, before human experience meets the Divine. Perhaps more than any other, the number nine had an extra special significance, which spread far and wide. It features across pretty much all cultures, worldwide, rippling through culture, mythology, history, law and time. Nine is the central number in the ancient Celtic tradition. Nine expresses through the triple Goddess (see Number 3) and in myths of the nine Celtic maidens, or sorceresses. In fact, stories of nine mystical women presiding over nature spread from England, Ireland and Wales, to Scandinavia, Iceland and even as far as Kenya. Even today, it’s tradition for nine groups of nine men to dance around Beltane fires. The limit of winter (which is what Beltane Almost all of the mythological tales from around the world have patterns of the number 9 weaving throughout. The Northern European sagas tell of Odin, who rules over the nine Norse worlds. His trial, to win the secrets of wisdom for mankind, was to hang on the Yggdrasil tree for nine days. Demeter, the Greek Goddess of the Earth searched for nine days for her daughter Persephone (who was in the underworld with Hades). Demeter is often depicted holding nine pieces of corn. Once recovered, Persephone was obliged to spend three months per year below the ground, and nine months above. Native American, Mayan and Aztec myths tell of a total of nine cosmic levels (and many of the temples comprise 9 stories). And in ancient China, nine was the most auspicious number of divine power: the Chinese had nine sacred rites, nine social laws, nine classes of officials in the government and built nine-story pagodas. In astrology, the planet Mars vibrates to the frequency of the nine. The ninth sign of the Zodiac is Sagittarius (where the Sun sails from November 22nd – December 21st) In Tarot, card number nine is the Hermit. In Hinduism, nine is the number of Brahma. In the Greek Sagas, the city of Troy was under siege for nine years. Azomite has 180ppm Thorium iirc.
Likes
45
Share
280nm = More than just a metric for a color of light, it is the frequency of the wave oscillation, 280nm is 0.00000028 meters, 2.8 x 10-7. For everything created by God is good, and nothing is to be rejected if it is received with thanksgiving, for it is made holy by the word of God and prayer (1 Timothy 4:4–5). Once a truck at work full of earth mixed with metal set off our radiation detector, after 4 positive tests for high radiation levels, the entire 18 wheeler had to be emptied and checked to find the source. No one could find anything, the nuclear technicians had to be called. they found that the rainwater had seeped out all the fertilizer from the soil, it was pottasium build-up to my disbelief. Unbeknown to us the earth was dug up from farmland. This was the backstory that set me off on a quest for this knowledge im about to share, I thought it was frickin awesome sauce. *puff puff pass* THORIUM Thorium, at atomic number 90, is one of the rarest elements. Named after Thor the God of thunder. 232Th is a primordial nuclide, having existed in its current form for over ten billion years; it was formed during the r-process, which probably occurs in supernovae and neutron star mergers. These violent events scattered it across the galaxy. The letter "r" stands for "rapid neutron capture", and occurs in core-collapse supernovae, where heavy seed nuclei such as 56Fe rapidly capture neutrons, running up against the neutron drip line, as neutrons are captured much faster than the resulting nuclides can beta decay back toward stability. Neutron capture is the only way for stars to synthesize elements beyond iron because of the increased Coulomb barriers that make interactions between charged particles difficult at high atomic numbers and the fact that fusion beyond 56Fe is endothermic. Because of the abrupt loss of stability past 209Bi, the r-process is the only process of stellar nucleosynthesis that can create thorium and uranium; all other processes are too slow and the intermediate nuclei alpha decay before they capture enough neutrons to reach these elements. Thorium is a naturally-occurring chemical element with atomic number 90, which means there are 90 protons and 90 electrons in the atomic structure. The chemical symbol for thorium is Th. Thorium was discovered in 1828 by Norwegian mineralogist Morten Thrane Esmark. Joens Jakob Berzelius, the Swedish chemist, named it after Thor, the Norse god of thunder. Thorium is a naturally-occurring element estimated to be about three times more abundant than uranium. Thorium is commonly found in monazite sands (rare earth metals containing phosphate minerals). Thorium has 6 naturally occurring isotopes. All of these isotopes are unstable (radioactive), but only 232Th is relatively stable with a half-life of 14 billion years, which is comparable to the age of the Earth (~4.5×109 years). Isotope 232Th belongs to primordial nuclides, and natural thorium consists primarily of isotope 232Th. Other isotopes (230Th, 229Th, 228Th, 234Th, and 227Th) occur in nature as trace radioisotopes, which originate from the decay of 232Th, 235U, and 238U. Histogram of estimated abundances of the 83 primordial elements in the Solar system Estimated abundances of the 83 primordial elements in the Solar system, plotted on a logarithmic scale. Thorium, at atomic number 90, is one of the rarest elements. In the universe, thorium is among the rarest of the primordial elements, because it is one of the two elements that can be produced only in the r-process (the other being uranium). POTASSIUM Potassium 40 is a radioisotope that can be found in trace amounts in natural potassium, is at the origin of more than half of the human body activity: undergoing between 4 and 5,000 decays every second for an 80kg man. Along with uranium and thorium, potassium contributes to the natural radioactivity of rocks and hence to the H"Earth". This isotope makes up one ten-thousandth of the potassium found naturally. In terms of atomic weight, it is located between two more stable and far more abundant isotopes (potassium 39 and potassium 41) that make up 93.25% and 6.73% of the Earth total potassium supply respectively. With a half-life of 1,251 billion years, potassium 40 existed in the remnants of dead stars whose agglomeration has led to the Solar System with its planets. Potassium 40 has the unusual property of decaying into two different nuclei: in 89% of cases beta-negative decay will lead to calcium 40, while 11% of the time argon 40 will be formed by electron capture followed by gamma emission at an energy of 1.46 MeV. This 1.46 MeV gamma ray is important, as it allows us to identify when potassium 40 decays. The beta electrons leading to calcium, however, are not accompanied by gamma rays, have no characteristic energies and rarely make it out of the rocks or bodies that contain potassium 40. Beta-minus decay indicates a nucleus with too many neutrons, electron capture a nucleus with too many protons. How can potassium 40 simultaneously have too many of both? The answer reveals one of the peculiarities of the nuclear forces. Everyone alive has roughly 140g of potassium = *0.016 grams of Potassium Isotope 40* The charge radius is a fundamental property of the atomic nucleus. Although it globally scales with the nuclear mass as A1/3, the nuclear charge radius also exhibits appreciable isotopic variations that are the result of complex interactions between protons and neutrons. Indeed, charge radii reflect various nuclear structure phenomena such as halo structures6, shape staggering7, shape coexistence8, pairing correlations9,10, neutron skins11, and the occurrence of nuclear magic numbers5,12,13. The term ‘magic number’ refers to the number of protons or neutrons corresponding to completely filled shells. In charge radii, a shell closure is observed as a sudden increase in the charge radius of the isotope just beyond magic shell closure, as seen, for example, at the well-known magic numbers N = 28, 50, 82 and 126 (refs. 5,12–14). In the nuclear mass region near potassium, the isotopes with proton number Z ≈ 20 and neutron number N = 32 are proposed to be magic on the basis of an observed sudden decrease in their binding energy beyond N = 32 (refs. 2,3) and the high excitation energy of the first excited state in 52Ca (ref. 1). Therefore, the experimentally observed a strong increase in the charge radii of calcium4 and potassium5 isotopes between N = 28 and N = 32, and in particular the large radius of 51K and 52Ca (both having 32 neutrons), have attracted substantial attention. https://www.nature.com/articles/s41567-020-01136-5.pdf “A cat has 9 lives” “On cloud 9” “Dressed to the nines” To go “the whole nine yards” “A stitch in time saves nine” “Nine-ness” seems to be synonymous with the maximum, with the furthest extent of what’s possible. With fullness, completion, and when every effort has been exhausted. In the ancient world (which is, let’s face it, is where numbers and their spiritual power were understood SO much more than they are today) the number 9 resonated with sacred structure, and the furthest limitations of this world, before human experience meets the Divine. Perhaps more than any other, the number nine had an extra special significance, which spread far and wide. It features across pretty much all cultures, worldwide, rippling through culture, mythology, history, law and time. Nine is the central number in the ancient Celtic tradition. Nine expresses through the triple Goddess (see Number 3) and in myths of the nine Celtic maidens, or sorceresses. In fact, stories of nine mystical women presiding over nature spread from England, Ireland and Wales, to Scandinavia, Iceland and even as far as Kenya. Even today, it’s tradition for nine groups of nine men to dance around Beltane fires. The limit of winter (which is what Beltane Almost all of the mythological tales from around the world have patterns of the number 9 weaving throughout. The Northern European sagas tell of Odin, who rules over the nine Norse worlds. His trial, to win the secrets of wisdom for mankind, was to hang on the Yggdrasil tree for nine days. Demeter, the Greek Goddess of the Earth searched for nine days for her daughter Persephone (who was in the underworld with Hades). Demeter is often depicted holding nine pieces of corn. Once recovered, Persephone was obliged to spend three months per year below the ground, and nine months above. Native American, Mayan and Aztec myths tell of a total of nine cosmic levels (and many of the temples comprise 9 stories). And in ancient China, nine was the most auspicious number of divine power: the Chinese had nine sacred rites, nine social laws, nine classes of officials in the government and built nine-story pagodas. In astrology, the planet Mars vibrates to the frequency of the nine. The ninth sign of the Zodiac is Sagittarius (where the Sun sails from November 22nd – December 21st) In Tarot, card number nine is the Hermit. In Hinduism, nine is the number of Brahma. In the Greek Sagas, the city of Troy was under siege for nine years. Azomite has 180ppm Thorium iirc.
Likes
45
Share
280nm = More than just a metric for a color of light, it is the frequency of the wave oscillation, 280nm is 0.00000028 meters, 2.8 x 10-7. For everything created by God is good, and nothing is to be rejected if it is received with thanksgiving, for it is made holy by the word of God and prayer (1 Timothy 4:4–5). Once a truck at work full of earth mixed with metal set off our radiation detector, after 4 positive tests for high radiation levels, the entire 18 wheeler had to be emptied and checked to find the source. No one could find anything, the nuclear technicians had to be called. they found that the rainwater had seeped out all the fertilizer from the soil, it was pottasium build-up to my disbelief. Unbeknown to us the earth was dug up from farmland. This was the backstory that set me off on a quest for this knowledge im about to share, I thought it was frickin awesome sauce. *puff puff pass* THORIUM Thorium, at atomic number 90, is one of the rarest elements. Named after Thor the God of thunder. 232Th is a primordial nuclide, having existed in its current form for over ten billion years; it was formed during the r-process, which probably occurs in supernovae and neutron star mergers. These violent events scattered it across the galaxy. The letter "r" stands for "rapid neutron capture", and occurs in core-collapse supernovae, where heavy seed nuclei such as 56Fe rapidly capture neutrons, running up against the neutron drip line, as neutrons are captured much faster than the resulting nuclides can beta decay back toward stability. Neutron capture is the only way for stars to synthesize elements beyond iron because of the increased Coulomb barriers that make interactions between charged particles difficult at high atomic numbers and the fact that fusion beyond 56Fe is endothermic. Because of the abrupt loss of stability past 209Bi, the r-process is the only process of stellar nucleosynthesis that can create thorium and uranium; all other processes are too slow and the intermediate nuclei alpha decay before they capture enough neutrons to reach these elements. Thorium is a naturally-occurring chemical element with atomic number 90, which means there are 90 protons and 90 electrons in the atomic structure. The chemical symbol for thorium is Th. Thorium was discovered in 1828 by Norwegian mineralogist Morten Thrane Esmark. Joens Jakob Berzelius, the Swedish chemist, named it after Thor, the Norse god of thunder. Thorium is a naturally-occurring element estimated to be about three times more abundant than uranium. Thorium is commonly found in monazite sands (rare earth metals containing phosphate minerals). Thorium has 6 naturally occurring isotopes. All of these isotopes are unstable (radioactive), but only 232Th is relatively stable with a half-life of 14 billion years, which is comparable to the age of the Earth (~4.5×109 years). Isotope 232Th belongs to primordial nuclides, and natural thorium consists primarily of isotope 232Th. Other isotopes (230Th, 229Th, 228Th, 234Th, and 227Th) occur in nature as trace radioisotopes, which originate from the decay of 232Th, 235U, and 238U. Histogram of estimated abundances of the 83 primordial elements in the Solar system Estimated abundances of the 83 primordial elements in the Solar system, plotted on a logarithmic scale. Thorium, at atomic number 90, is one of the rarest elements. In the universe, thorium is among the rarest of the primordial elements, because it is one of the two elements that can be produced only in the r-process (the other being uranium). POTASSIUM Potassium 40 is a radioisotope that can be found in trace amounts in natural potassium, is at the origin of more than half of the human body activity: undergoing between 4 and 5,000 decays every second for an 80kg man. Along with uranium and thorium, potassium contributes to the natural radioactivity of rocks and hence to the H"Earth". This isotope makes up one ten-thousandth of the potassium found naturally. In terms of atomic weight, it is located between two more stable and far more abundant isotopes (potassium 39 and potassium 41) that make up 93.25% and 6.73% of the Earth total potassium supply respectively. With a half-life of 1,251 billion years, potassium 40 existed in the remnants of dead stars whose agglomeration has led to the Solar System with its planets. Potassium 40 has the unusual property of decaying into two different nuclei: in 89% of cases beta-negative decay will lead to calcium 40, while 11% of the time argon 40 will be formed by electron capture followed by gamma emission at an energy of 1.46 MeV. This 1.46 MeV gamma ray is important, as it allows us to identify when potassium 40 decays. The beta electrons leading to calcium, however, are not accompanied by gamma rays, have no characteristic energies and rarely make it out of the rocks or bodies that contain potassium 40. Beta-minus decay indicates a nucleus with too many neutrons, electron capture a nucleus with too many protons. How can potassium 40 simultaneously have too many of both? The answer reveals one of the peculiarities of the nuclear forces. Everyone alive has roughly 140g of potassium = *0.016 grams of Potassium Isotope 40* The charge radius is a fundamental property of the atomic nucleus. Although it globally scales with the nuclear mass as A1/3, the nuclear charge radius also exhibits appreciable isotopic variations that are the result of complex interactions between protons and neutrons. Indeed, charge radii reflect various nuclear structure phenomena such as halo structures6, shape staggering7, shape coexistence8, pairing correlations9,10, neutron skins11, and the occurrence of nuclear magic numbers5,12,13. The term ‘magic number’ refers to the number of protons or neutrons corresponding to completely filled shells. In charge radii, a shell closure is observed as a sudden increase in the charge radius of the isotope just beyond magic shell closure, as seen, for example, at the well-known magic numbers N = 28, 50, 82 and 126 (refs. 5,12–14). In the nuclear mass region near potassium, the isotopes with proton number Z ≈ 20 and neutron number N = 32 are proposed to be magic on the basis of an observed sudden decrease in their binding energy beyond N = 32 (refs. 2,3) and the high excitation energy of the first excited state in 52Ca (ref. 1). Therefore, the experimentally observed a strong increase in the charge radii of calcium4 and potassium5 isotopes between N = 28 and N = 32, and in particular the large radius of 51K and 52Ca (both having 32 neutrons), have attracted substantial attention. https://www.nature.com/articles/s41567-020-01136-5.pdf “A cat has 9 lives” “On cloud 9” “Dressed to the nines” To go “the whole nine yards” “A stitch in time saves nine” “Nine-ness” seems to be synonymous with the maximum, with the furthest extent of what’s possible. With fullness, completion, and when every effort has been exhausted. In the ancient world (which is, let’s face it, is where numbers and their spiritual power were understood SO much more than they are today) the number 9 resonated with sacred structure, and the furthest limitations of this world, before human experience meets the Divine. Perhaps more than any other, the number nine had an extra special significance, which spread far and wide. It features across pretty much all cultures, worldwide, rippling through culture, mythology, history, law and time. Nine is the central number in the ancient Celtic tradition. Nine expresses through the triple Goddess (see Number 3) and in myths of the nine Celtic maidens, or sorceresses. In fact, stories of nine mystical women presiding over nature spread from England, Ireland and Wales, to Scandinavia, Iceland and even as far as Kenya. Even today, it’s tradition for nine groups of nine men to dance around Beltane fires. The limit of winter (which is what Beltane Almost all of the mythological tales from around the world have patterns of the number 9 weaving throughout. The Northern European sagas tell of Odin, who rules over the nine Norse worlds. His trial, to win the secrets of wisdom for mankind, was to hang on the Yggdrasil tree for nine days. Demeter, the Greek Goddess of the Earth searched for nine days for her daughter Persephone (who was in the underworld with Hades). Demeter is often depicted holding nine pieces of corn. Once recovered, Persephone was obliged to spend three months per year below the ground, and nine months above. Native American, Mayan and Aztec myths tell of a total of nine cosmic levels (and many of the temples comprise 9 stories). And in ancient China, nine was the most auspicious number of divine power: the Chinese had nine sacred rites, nine social laws, nine classes of officials in the government and built nine-story pagodas. In astrology, the planet Mars vibrates to the frequency of the nine. The ninth sign of the Zodiac is Sagittarius (where the Sun sails from November 22nd – December 21st) In Tarot, card number nine is the Hermit. In Hinduism, nine is the number of Brahma. In the Greek Sagas, the city of Troy was under siege for nine years. Azomite has 180ppm Thorium iirc.