vaccines are liquid, not ferric metal (and before you say it, ferrofluids still contain ferric particles, hence the colour)
people have been sticking spoons to their forehead for decades, skin is sticky, check your ballsack for further research
magnetic permeability can be easily measured with a compass or the sensor in an iPhone, nobody in the video did this because they are all morons
anyone watching this without detecting a bullshit level of over 9000, is a moron
Here you go, faggot.
Recent Advances on Magnetic Sensitive Hydrogels in Tissue Engineering
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7068712/
Superparamagnetic nanoparticle delivery of DNA vaccine https://pubmed.ncbi.nlm.nih.gov/24715289/
gels are not liquid
tiny particles do not exhibit a magnetic permeability high enough to do what the video shows
refer to: "people have been sticking spoons to their forehead for decades, skin is sticky, check your ballsack for further research" for a more obvious explanation....
Watching the video there are several cases where your spoon comparison is rendered retarded.
The thing about your stance on this is that you are assuming that you are aware of all technologies. I show you where they're using gels, and superparamagnetic nano DNA vax, and your only response is "gels aren't a liquid/spoon sticks to head/tiny particles aren't capable of strong enough magnetic fields." Do you know for certain the vaccine isn't a gel? How viscous does the vaccine have to be before you consider it a gel instead of a liquid? Do you have any experience injecting anyone or thing with medicines to know what a tiny line there is between those two definitions? I have, and I am familiar with it. It's near impossible to tell with the eye, but the gauge of the needle must change for successful delivery.
A magnetic field results from the flow of current through wires or electrical devices and increases in strength as the current increases. Our bodies are excellent at conducting current. This is why being near radio/cellphone towers is bad, and why you don't want a smart meter in your home. There is a video of a guy measuring people who have been vaccinated and their EMF is in the 800-900 range, versus someone who is not vaccinated, around 20-30. So the tiny particles' size aren't the indicator of how strong of a magnetic pull is possible. The tech is the more important point.
I would also like to point out that they have been openly admitting to spraying our atmosphere with shit for decades. We're breathing in all kinds of unknown. A little tech injection to pull all of it together in their intended assembly is not out of the realm.
We literally live in a sci fi horror story at this point.
I’ve never seen anything like it. Ya it’s not likely nano-robots haha. And a chip? That’s that magnetic? Not exactly likely.
What do you make of this article? https://poal.co/s/AskPoal/362009
It's people confusing the concepts of 'magnetic/nanoparticle/vaccine', with unrelated things that can stick to your ballsack
magnetic particles looking really interesting though
Here's a list I found that says which metals are soluble and which are insoluble. Instead of only listing the ones that are soluble, to be fair and accurate, I'll include both soluble and insoluble metals.
Aluminum and compounds Aluminum metal reacts with dilute hydrochloric acid, sulfuric acid, potassium hydroxide, and sodium hydroxide. The salts of aluminum, including sodium aluminate, aluminum fluoride, aluminum chloride, and cryolite, are all soluble in water.
Arsenic and compounds Arsenic — Insoluble in hot and cold water; soluble in nitric acid. Arsenic trioxide and pentoxide — Soluble in cold and hot water, alcohol, alkalies, and hydrochloric acid; arsenic pentoxide is soluble in acids. Lead arsenate — Insoluble in cold water; soluble in hot water, nitric acid, and caustic alkalies. Calcium arsenate(s) — Insoluble in water and acids. Sodium arsenate(s) — Very soluble in water. Arsenic acid — Soluble in water and alcohol. Arsenic trisulfide — Practically insoluble in water.
Barium and compounds Barium metal — Insoluble in water; soluble in alcohol. Most of the compounds of barium are soluble in (cold or hot) water, for example, barium chloride, barium oxide, barium acetate, and barium cyanide. Barium hydroxide is slightly soluble in water. Barium carbonate is insoluble to slightly soluble in water, and is soluble in acids.
Beryllium and compounds Beryllium — Slightly soluble in hot water; insoluble in cold water; soluble in dilute alkalies and acids. Beryllium oxide — Insoluble in water; soluble in some acids and alkalies. Beryllium hydroxide — Insoluble in water; soluble in acids and alkalies. Beryllium fluoride — Soluble in cold and hot water, alcohol, and sulfuric acid. Beryllium sulfate — Soluble in water and concentrated sulfuric acid.
Chromium and compounds Chromium reacts with dilute hydrochloric acid and sulfuric acid, but not with nitric acid. Chromium metal — Insoluble in hot and cold water. Hexavalent chromium compounds, including chromium trioxide, the anhydride of chromic acid, chromates, dichromates, and polychromates, tend to be of low solubility in water and can be subdivided into two subgroups: 1.) Water-soluble hexavalent chromium compounds include chromic acid, its anhydride, and the monochromates and dichromates of sodium, potassium, ammonium, lithium, cesium, and rubidium. 2.) Water-insoluble hexavalent chromium compounds include zinc chromate, lead chromate, barium chromate, and sintered chromium trioxide. NOTE: Depending on the reference [CRC 2015, O’Neil 2006] both calcium chromate and strontium chromate are listed as soluble and insoluble in water.
Iron and compounds Iron, ferrous oxide, ferric oxide, and iron oxide — Insoluble in hot and cold water. Ferric chloride, ferric nitrate, ferric sulfate, ferrous sulfate and ferrous chloride — Soluble in hot and cold water. Ferric chloride — Soluble in ethanol, methanol, and ether. Ferric nitrate and ferrous chloride — Soluble in ethanol and acetone. Ferric sulfate — Sparingly soluble in ethanol; insoluble in acetone. Ferrous sulfate — Insoluble in ethanol.
Molybdenum and compounds Molybdenum — Insoluble in hot or cold water; soluble in nitric, sulfuric, and hydrochloric acids. Molybdic oxide — Sparingly soluble in water; soluble in acids and alkalies. Molybdenum disulfide — Insoluble in hot or cold water and dilute acids; soluble in hot sulfuric acid, aqua regia, and nitric acid. Ammonium molybdate — Soluble in hot or cold water, acids, and alkalies. Calcium molybdate — Insoluble in cold water; soluble in hot water. Lead molybdate — Insoluble in water and alcohol; soluble in acid and potassium hydroxide. Sodium molybdate — Soluble in hot and cold water.
Nickel and compounds Nickel — Insoluble in hot and cold water; soluble in nitric, sulfuric, and hydrochloric acids. Nickel oxide — Insoluble in hot and cold water; soluble in ammonium hydroxide and acids. Nickel acetate — Soluble in cold water; insoluble in alcohol [CRC 2015]; soluble in alcohol [O’Neil 2006]. Nickel carbonate — Soluble in cold water; insoluble in hot water. NIOSH Manual of Analytical Methods 5th Edition Chapter SM April 2016 Page SM-16 of SM-17 Sampling and Analysis of Soluble Metal Compounds Nickel hydrates — Some forms soluble, others insoluble (in water). Nickel sulfate — Soluble in hot and cold water.
Platinum and compounds Platinum — Insoluble in hot or cold water and single mineral acids; soluble in aqua regia; attacked by halogens, alkali cyanides, and caustic alkalies. Platinum forms are series of complex chloroplatinate salts that are water soluble.
Rhodium and compounds Rhodium — Insoluble in hot or cold water; soluble in hot sulfuric acid plus hydrochloric acid; slightly soluble in acids and aqua regia. Water-soluble rhodium compounds include rhodium trichloride, sodium chlororhodite, and rhodium carbonyl acetylacetonate.
Silver and compounds Silver — Insoluble in water and inert to most acids; reacts readily in dilute nitric acid or hot concentrated sulfuric acid; soluble in fused alkali hydroxides in the presence of air. Silver oxide — Soluble in hot and cold water, acids, and alkalies. Silver acetate — Soluble in hot or cold water and nitric acid. Silver bromide — Insoluble in hot or cold water and nitric acid. Silver chloride — Soluble in hot water; slightly soluble in cold water and ammonium hydroxide. Silver cyanide — Soluble in cold water, nitric acid, and ammonium hydroxide. Silver nitrate — Soluble in hot and cold water.
Thallium and compounds Thallium — Insoluble in hot and cold water; soluble in nitric, sulfuric, and hydrochloric acids. Thallous oxide — Soluble in water, acids, and alcohols. Thallic oxide — Insoluble in hot or cold water; soluble in acids. Thallous acetate and thallic chloride — Soluble in cold water and alcohol. Thallous bromide and chloride — Slightly soluble in water. Thallous sulfate — Soluble in hot or cold water. Thallous sulfide — Soluble in cold water.
Tungsten and compounds Tungsten — Insoluble in hot or cold water, hydrofluoric acid, and potassium hydroxide; soluble in mixtures of hydrofluoric and nitric acid; slightly soluble in sulfuric acid. Tungsten trioxide — Insoluble in hot or cold water and acids; soluble in hot alkalies and hydrofluoric acid. Tungstic acid — Insoluble in cold water and most acids; soluble in hot water, alkalies, hydrofluoric acid, and ammonia. Sodium tungstate — Soluble in hot and cold water; slightly soluble in ammonia; insoluble in acids and alcohol. Tungsten carbide — Insoluble in water; soluble in mixtures of hydrofluoric and nitric acid, and in aqua regia. Tungsten diboride — Insoluble in hot or cold water; soluble in aqua regia. Tungsten hexachloride — Soluble in hot water. Tungsten oxytetrachloride — Soluble in hot or cold water. Tungsten hexafluoride — Soluble in hot or cold water and alkalies. Tungsten disulfide — Insoluble in cold water and in alcohol; soluble in mixtures of hydrofluoric and nitric acid. Phosphotungstic acid — Soluble in cold water, alcohol, and ether. Ammonium paratungstate — Soluble in water; insoluble in alcohol.
Uranium and compounds Uranium — Insoluble in hot or cold water, alcohol, and alkali. Uranium dioxide — Insoluble in hot or cold water; soluble in nitric acid and concentrated sulfuric acid. Triuranium octoxide — Insoluble in hot or cold water; soluble in nitric acid and sulfuric acid. Uranium tetrafluoride — Insoluble in cold water, dilute acids, and alkalies; soluble in concentrated acids and alkalies.
a list I found that says which metals are soluble
nice list, however the question to be answered is: "tiny particles do not exhibit a magnetic permeability high enough to do what the video shows"
> the question to be answered is: "tiny particles do not exhibit
You're not asking a question, you're pushing an agenda. Instead of asking, "Do soluble metals exhibit" You're trying to push the answer.
If you were asking a question, the answer would be -
There definitely is a possibility.
But what also needs to be answered is what happens after those soluble metals are injected into human flesh. Specifically, what does human flesh do to the soluble material, how will the metals act after having the soluble material absorbed by the flesh, and what states are the material and metal in prior to, and after, the injection. - For example the Pfizer injections need to be stored at -80 degrees Celsius.
Dude. Watch the video. One girl you can see the magnet catch on the one
Watch the video.
videos are only useful where the constraints are obvious: 'he fired his gun, I saw the muzzle flash, there were multiple recordings of this event', 'the nigger dropped his drugs, look, there's the packet'
they are not so useful when you have a bunch of hidden variables, like if something is sticking to the skin and you want to prove this this is entirely because of something inside the skin, the same effect should also be demonstrable when the skin is covered with talc/cling-film.
but because we are dealing with morons, nobody thought of trying that.
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