The most dangerous frequencies of electromagnetic energy are X-rays, gamma rays, ultraviolet light and microwaves. X-rays, gamma rays and UV light can damage living tissues, and microwaves can cook them.
10 out of 10 people die... Do you still feel special?
from my understanding...
ionizing radiation is the most dangerous to cells... gamma/xray waves
non-ionizing radiation is still bad, but does not mutate cells into cancer at the level ionizing does ... micro/radio waves
Who better to ask?
https://www.who.int/news-room/q-a-detail/radiation-ionizing-radiation
Ionizing radiation is radiation with enough energy that to remove tightly bound electrons from the orbit of an atom, causing that atom to become charged or ionized.
Here we are concerned with only one type of radiation, ionizing radiation, which occurs in two forms: waves or
particles.
Ionizing radiation is any type of particle or electromagnetic wave that carries enough energy to ionize or remove electrons from an atom.
Ionizing radiation is a type of energy released by atoms that travels in the form of electromagnetic waves (gamma or X-rays) or particles (neutrons, beta or alpha). The spontaneous disintegration of atoms is called radioactivity, and the excess energy emitted is a form of ionizing radiation.
the excess energy emitted is a form of ionizing radiation.
A radical ion is a free radical species that carries a charge.
Electron ionization (EI, formerly known as electron impact ionization and electron bombardment ionization) is an ionization method in which energetic electrons interact with solid or gas phase atoms or molecules to produce ions. EI was one of the first ionization techniques developed for mass spectrometry.
The high energy electrons come from an 'electron gun' which is a hot wire filament with a current running through it that emits electrons. This usually knocks off one electron from each particle forming a 1+ ion.
Superparamagnetic iron oxide nanoparticles (SPIONs) are the most extensively used functional nanomaterials as antibacterial agents, and for other biomedical applications due to their unique physical, chemical, magnetic and biocompatibility properties.
Applications of iron oxide nanoparticles include terabit magnetic storage devices, catalysis, sensors, superparamagnetic relaxometry, high-sensitivity biomolecular magnetic resonance imaging, magnetic particle imaging, magnetic fluid hyperthermia, separation of biomolecules, and targeted drug and gene delivery for medical diagnosis and therapeutics. These applications require coating of the nanoparticles by agents such as long-chain fatty acids, alkyl-substituted amines, and diols.[citation needed] They have been used in formulations for supplementation.
