its ARTIFICIAL RADIOACTIVITY....because during bombarding, the element used,contains electrons which reacts with the non-radioactive substance which on further emits radiations.......
The inverse process of the photoelectric effect is the emission of a photon when an excited electron transitions to a lower energy level within an atom or molecule, known as photoluminescence. This process involves the release of light energy in the form of a photon.
X-rays and the photoelectric effect are related because X-rays are high-energy electromagnetic waves that can cause the photoelectric effect to occur in matter, where electrons are ejected from atoms when X-rays are absorbed. This happens because X-rays have enough energy to overcome the binding energy of the electrons in the atoms they interact with. So, in essence, X-rays can trigger the photoelectric effect in materials due to their high energy levels.
The photoelectric effect demonstrates the particle nature of light. In this phenomenon, light is shown to behave like a stream of particles (photons) by ejecting electrons from a material when it hits the surface.
No, the reverse process of the photoelectric effect is not the Zeeman effect. The Zeeman effect is the splitting of spectral lines in the presence of a magnetic field, while the photoelectric effect is the emission of electrons from a material when exposed to light. They are two distinct phenomena in physics.
No, radio waves and microwaves do not produce the photoelectric effect. The photoelectric effect is the phenomenon where electrons are emitted from a material when it is exposed to light of sufficient frequency (typically ultraviolet or higher). Radio waves and microwaves have lower frequencies and energies than light, so they are not capable of causing the photoelectric effect.
The inverse process of the photoelectric effect is the emission of a photon when an excited electron transitions to a lower energy level within an atom or molecule, known as photoluminescence. This process involves the release of light energy in the form of a photon.
The inverse of the photoelectric effect is the Compton effect, where a photon interacts with an electron and loses energy in the process. This results in the photon scattering off the electron with a longer wavelength.
X-rays and the photoelectric effect are related because X-rays are high-energy electromagnetic waves that can cause the photoelectric effect to occur in matter, where electrons are ejected from atoms when X-rays are absorbed. This happens because X-rays have enough energy to overcome the binding energy of the electrons in the atoms they interact with. So, in essence, X-rays can trigger the photoelectric effect in materials due to their high energy levels.
conditions of photoelectric effect
The amount of xrays produced in a photoelectric effect varies. . . . alot.
The photoelectric effect demonstrates the particle nature of light. In this phenomenon, light is shown to behave like a stream of particles (photons) by ejecting electrons from a material when it hits the surface.
Certainly, of course, and you betcha. The presence of air has no function or involvement in the photoelectric effect.
No, the reverse process of the photoelectric effect is not the Zeeman effect. The Zeeman effect is the splitting of spectral lines in the presence of a magnetic field, while the photoelectric effect is the emission of electrons from a material when exposed to light. They are two distinct phenomena in physics.
No, radio waves and microwaves do not produce the photoelectric effect. The photoelectric effect is the phenomenon where electrons are emitted from a material when it is exposed to light of sufficient frequency (typically ultraviolet or higher). Radio waves and microwaves have lower frequencies and energies than light, so they are not capable of causing the photoelectric effect.
Solar energy uses the photoelectric effect to convert light energy into electrical energy. When sunlight shines on a solar panel, the photoelectric effect causes electrons to be released, creating an electric current.
In the photoelectric effect, light produces electrons when it strikes a material surface. The energy of the incident light is transferred to the electrons, causing them to be ejected from the material.
Increasing the intensity of light in the photoelectric effect results in an increase in the number of photons, which can lead to a higher number of photoelectrons being ejected from the metal surface. This results in an increase in the photoelectric current.