My answer is NO, since vibrating electric charge cannot exist independently (conservation of electric charge cannot be violated). Vibrating electric charge can only exist as part of electric charge wave.
No, a vibrating neutron would not produce an electromagnetic wave. Neutrons are electrically neutral and do not carry an electric charge, so they do not interact with electromagnetic fields in the same way that charged particles do.
An electron microscope uses a beam of accelerated electrons to produce magnified images of extremely small objects. This type of microscope offers much higher resolution and magnification capabilities compared to traditional light microscopes.
No, electromagnetic waves require the mutual generation of electric and magnetic fields. This reciprocal relationship allows the waves to propagate through space as self-sustaining oscillations. If only one field could generate the other but not vice versa, electromagnetic waves would not exist.
A smooth and polished metallic surface, such as silver or aluminum, would be the best reflector of electromagnetic energy. These surfaces have high reflectivity due to their free electron density, allowing them to efficiently reflect a wide range of electromagnetic frequencies.
In reality wherever there is harmony or matching then energy would be easily handed over or transferred. Same way as the electron status in an atom is in harmony with the falling electromagnetic radiation then that energy would be absorbed by the electron and so the electron would go to the higher energy level. This is what we call excitation. This is how heat is getting transferred to the molecules of fluid, atoms of solid etc. Light too gets absorbed by the leaves in the process of photo synthesis.
Stationary charge don't produce a magnetic field. because it has no velocity in it, without flow of electron we can't find electricity and for that we have no magnetic field for a stationary charge. It produce only electric field.
When a charge is stationary then an electric field exists. If that charge moves uniformly in space then magnetic field arises around the direction of movement of that charge. If the same charge gets accelerated then electromagnetic disturbance is produced in the space. So any charge oscillating or moving in a curved path would produce electromagnetic disturbance. Such a disturbance is known as electromagnetic waves.
Yes. Stationary electric (electrostatic) fields will act on each other and a force will be developed. If you had a standing electric field and could "beam in" an electron (a la Star Trek), the electron would react at once and move either toward a positive field source or away from a negative field source. The electron would know the field was there the instant it appeared.
no.
No, a vibrating neutron would not produce an electromagnetic wave. Neutrons are electrically neutral and do not carry an electric charge, so they do not interact with electromagnetic fields in the same way that charged particles do.
The Bohr radius, is the estimated distance between protons in the nucleus and electrons - but electrons aren't solid, stationary particles... The simple answer would be about one-twentieth of a nanometre. But this would only be reasonable if the electron were a solid particle.
Yes if the moon fell on earth it would definetly produce a noticable magnetic field.
Electron microscopes use electron beams to create images with high resolution, but electrons don't interact with light in the same way as photons do in optical microscopes, so they don't produce colored images. Instead, electron microscopes typically produce grayscale images based on the intensity of electron beams detected.
An electron microscope uses a beam of accelerated electrons to produce magnified images of extremely small objects. This type of microscope offers much higher resolution and magnification capabilities compared to traditional light microscopes.
I believe it would be stationary but i am not sure
No, electromagnetic waves require the mutual generation of electric and magnetic fields. This reciprocal relationship allows the waves to propagate through space as self-sustaining oscillations. If only one field could generate the other but not vice versa, electromagnetic waves would not exist.
Yes, because it has a charge (+). Any charged particle that vibrates produces an electromagnetic wave at the frequency determined by the number of vibrations per second. The magnitude is determined by the how far the particle goes from max. to min. on each cycle.