EMF Protection Fabrics Demonstration Of EMF Blocking

In this video, I explain how EMF protection fabrics actually work to prevent exposure to radiation from mobile devices, mobile networks, and WIFI routers.
These fabrics are made using metallic threads. The reason metal is used, is because metal is conductive (allows electrons to freely move through the material) as opposed to insulating materials with high resistance which block the flow of electrons.
In much the same way that a lightning rod works, the conductive metal rod of a lightning rod, when attached to a ground wire (or actual ground) allows the electrical charge to actually attract static electricity and act as a conduit to ground. A lightning rod is simple, yet magical. Just a metal stick stuck into the earth will draw lightning from great distances and allow lightning to strike the rod, diverting lightning away from buildings and thus affording them protection.
In testing the fabrics, I use two tests: 1) is to test for conductivity. Conductive materials can act as shields against harmful radiation due to their ability to absorb and/or reflect electromagnetic waves. When electromagnetic radiation, such as radio waves, microwaves, or even higher-energy forms like X-rays or gamma rays, encounters a conductive material, several mechanisms come into play:
* Reflection: Conductive materials can reflect electromagnetic waves. When radiation hits the surface of a conductive material, the free electrons in the material can move in response to the electric field of the incoming waves. This movement of electrons generates an opposing electric field that reflects the radiation.
* Absorption: Conductive materials can absorb electromagnetic energy. The free electrons in the material can absorb the energy from the incoming radiation, converting it into thermal energy. This absorption process reduces the amount of radiation that penetrates through the material.
* Conduction: In the case of high-frequency electromagnetic radiation, conductive materials can conduct electric currents induced by the radiation. These currents create their own electromagnetic fields that can cancel out or interfere with the incoming radiation.
* Screening or Faraday Cage Effect: Conductive materials can also create a Faraday cage effect. A Faraday cage is a conductive enclosure that blocks external static and non-static electric fields. This can prevent electromagnetic radiation from entering or leaving the enclosed space.
For example, when it comes to protecting electronic devices from electromagnetic interference (EMI) or radiofrequency interference (RFI), conductive materials like metals are often used to create shielding. This shielding helps prevent unwanted external electromagnetic exposure.

Not all fabrics are equal. EMF shielding fabrics are typically made of Iron, Nickel, or Silver-coated nylon. For the most effective protection, the most conductive fabric is preferred. In much the same way that lightning will find the lightning rod that has the most conductivity, EMF radiation will “aim” at the most conductive rod.Among silver, nickel, and copper, silver is the most conductive metal. The electrical conductivity of a material is typically measured in terms of its electrical conductivity or resistivity. Here are the approximate electrical conductivity values for these metals:

* Silver (Ag): Silver is the most conductive metal. It has a very high electrical conductivity, with a factor of 63 million s/m.
* Copper (Cu): Copper is also an excellent conductor of electricity. Its electrical conductivity is slightly lower than that of silver but still very high, typically around 58 million s/m.
* Nickel (Ni): Nickel has lower electrical conductivity compared to silver and copper. Its electrical conductivity is typically around 14 million S/m.