Frankster
Never trust a doctor who's plants have died.
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When your thinking salts, you've always got to understand basics about cation/anion exchange, and how energy is either conserved, or destroyed.
Alright, I've been working on this in the background for awhile, and I think it's a good time to bring it out and let others take a look at what I'm doing here. Many thanks for Aquaman for all his input in this endeavor and helping me bring things full circle. It's been a long road, and many have suggested that organics and salts couldn't be connected, but I knew it could be done on some levels, I just didn't know the "how" up till a little while ago, and I've been working to update and refine this process a little further.
I think the best way to show this, is to see what I'm working with here, the results side first speak volumes, then we can get into the specifics, and the ratio's later. I'll start with this; pH<4 = bad news bruh... not.
Here's a little video, and some pics of why I call it a "Living salt", or probably more accurate term would simply be a sugar salt, or an enzymatic salt. Listen to the sound of the formula as it's opened. It's like opening a bottle of wine, or beer. The pH is perfectly "optimized"@6-6.2 naturally, by fermentation of select organisms.
Some pics also: of the expansion that's occurring, and the CO2 being generated.
Alright, the basics.
Cations;
A positively charged ion, i.e. one that would be attracted to the cathode in electrolysis. Usually in our case, it's a metal. Ca++ is a good example, it's got 2+ with a 2,8,8,2 shell config.
Anions;
A negatively charged ion, i.e. one that would be attracted to the anode in electrolysis. Lets think hydroxide this time around. We know from above it's got a 2,6 ring config, and has six valence electrons, two in the 2s subshell and four in the 2p subshell. Each hydrogen atom has one valence electron and is univalent. so we have -1 charge.
What I'm doing here, is forcing a "chemical" reaction into the solutions, creating an anionic mixture.
Here's some in-depth explanation of what I'm trying to develop here.
www.frontiersin.org
How cells position their division plane is a critical component of cell division. Indeed, it defines whether the two daughter cells divide symmetrically (with equal volumes) or not, and as such is critical for cell differentiation and lineage specification across eukaryotes. However, oriented cell divisions are of special significance for organisms with cell walls, such as plants, because their cells are embedded and cannot relocate. Correctly positioning the division plane is therefore of prevailing importance in plants, as it controls not only the occurrence of asymmetric cell division, but also tissue morphogenesis and organ integrity.
Recent research has shown that strict regulation of the levels and distribution of anionic lipids, which are minor components of the cell membrane’s lipids, is required for successful cytokinesis in non-plant organisms. This review focused on the recent evidence pointing to whether such signaling lipids have roles in plant cell division.
So what I'm doing here, is "pre-load" the specific ratio's into an catalyst solution, converting it into an anionic mixture via (fermentation) organisms (mixed with very specific ratio's creating new "in vitro" organic phospholipid) so that the plant (in flower) can readily absorb it and everything is optimized, plus C02 is the by-product of this process. An added benefit. If that makes sense. Everything it carefully blended to improve optimum nutrient availability and pH. By optimizing bacterial, fungal and yeast growth in the solutions, so that it also lends beneficial organic enzymatic and hormone regulators as well.
Alright, I've been working on this in the background for awhile, and I think it's a good time to bring it out and let others take a look at what I'm doing here. Many thanks for Aquaman for all his input in this endeavor and helping me bring things full circle. It's been a long road, and many have suggested that organics and salts couldn't be connected, but I knew it could be done on some levels, I just didn't know the "how" up till a little while ago, and I've been working to update and refine this process a little further.
I think the best way to show this, is to see what I'm working with here, the results side first speak volumes, then we can get into the specifics, and the ratio's later. I'll start with this; pH<4 = bad news bruh... not.
Here's a little video, and some pics of why I call it a "Living salt", or probably more accurate term would simply be a sugar salt, or an enzymatic salt. Listen to the sound of the formula as it's opened. It's like opening a bottle of wine, or beer. The pH is perfectly "optimized"@6-6.2 naturally, by fermentation of select organisms.
Your browser is not able to display this video.
Some pics also: of the expansion that's occurring, and the CO2 being generated.
Alright, the basics.
Cations;
A positively charged ion, i.e. one that would be attracted to the cathode in electrolysis. Usually in our case, it's a metal. Ca++ is a good example, it's got 2+ with a 2,8,8,2 shell config.
Anions;
A negatively charged ion, i.e. one that would be attracted to the anode in electrolysis. Lets think hydroxide this time around. We know from above it's got a 2,6 ring config, and has six valence electrons, two in the 2s subshell and four in the 2p subshell. Each hydrogen atom has one valence electron and is univalent. so we have -1 charge.
What I'm doing here, is forcing a "chemical" reaction into the solutions, creating an anionic mixture.
Here's some in-depth explanation of what I'm trying to develop here.
Frontiers | Anionic Lipids: A Pipeline Connecting Key Players of Plant Cell Division
How cells position their division plane is a critical component of cell division. Indeed, it defines whether the two daughter cells divide symmetrically (wit...
How cells position their division plane is a critical component of cell division. Indeed, it defines whether the two daughter cells divide symmetrically (with equal volumes) or not, and as such is critical for cell differentiation and lineage specification across eukaryotes. However, oriented cell divisions are of special significance for organisms with cell walls, such as plants, because their cells are embedded and cannot relocate. Correctly positioning the division plane is therefore of prevailing importance in plants, as it controls not only the occurrence of asymmetric cell division, but also tissue morphogenesis and organ integrity.
Recent research has shown that strict regulation of the levels and distribution of anionic lipids, which are minor components of the cell membrane’s lipids, is required for successful cytokinesis in non-plant organisms. This review focused on the recent evidence pointing to whether such signaling lipids have roles in plant cell division.
So what I'm doing here, is "pre-load" the specific ratio's into an catalyst solution, converting it into an anionic mixture via (fermentation) organisms (mixed with very specific ratio's creating new "in vitro" organic phospholipid) so that the plant (in flower) can readily absorb it and everything is optimized, plus C02 is the by-product of this process. An added benefit. If that makes sense. Everything it carefully blended to improve optimum nutrient availability and pH. By optimizing bacterial, fungal and yeast growth in the solutions, so that it also lends beneficial organic enzymatic and hormone regulators as well.
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