The energy of a photon is directly proportional to its frequency.
(The proportionality constant is Planck's Konstant.)
If one photon has double the wavelength of another, then its frequency is
1/2 the frequency of the other one, and its energy is also half.
quadruple
Yes, increasing the amplitude of a wave does affect its energy. Energy is directly proportional to the square of the amplitude of a wave. This means that doubling the amplitude of a wave will increase its energy by a factor of four.
wellllll energy of the wave controls the amplitude of a wave
A high amplitude wave carries more energy because the amplitude of a wave is directly related to the wave's energy. The higher the amplitude, the more energy the wave has, as it represents a greater amount of mechanical energy being transferred through the medium. Thus, a high amplitude wave can cause more displacement and disturbances in the medium, resulting in the transmission of more energy.
The amplitude of a wave is directly proportional to the energy it carries. A higher amplitude wave carries more energy compared to a wave with a lower amplitude. This means that the larger the wave's amplitude, the more energy it can transfer.
quadruple
Yes, increasing the amplitude of a wave does affect its energy. Energy is directly proportional to the square of the amplitude of a wave. This means that doubling the amplitude of a wave will increase its energy by a factor of four.
wellllll energy of the wave controls the amplitude of a wave
A high amplitude wave carries more energy because the amplitude of a wave is directly related to the wave's energy. The higher the amplitude, the more energy the wave has, as it represents a greater amount of mechanical energy being transferred through the medium. Thus, a high amplitude wave can cause more displacement and disturbances in the medium, resulting in the transmission of more energy.
The amplitude of a wave is directly proportional to the energy it carries. A higher amplitude wave carries more energy compared to a wave with a lower amplitude. This means that the larger the wave's amplitude, the more energy it can transfer.
A low amplitude wave carries less energy compared to a high amplitude wave. The energy of a wave is proportional to the square of its amplitude. Therefore, a wave with a low amplitude will have lower energy.
The energy of a wave is directly proportional to its amplitude. This means that as the amplitude of a wave increases, so does its energy. Conversely, if the amplitude decreases, the energy of the wave will also decrease.
The intensity will increase if the energy increase. The intensity is proportional to the square of the amplitude of a wave.
The energy of a wave is directly proportional to the square of its amplitude. This means that as the amplitude of a wave increases, its energy also increases quadratically. A wave with greater amplitude carries more energy.
If the amplitude of a wave is increased, the energy that the wave carries also increases. Amplitude is directly proportional to energy in a wave, so as the amplitude grows, the energy of the wave increases.
The amplitude of a wave is related to the energy it carries. In general, a wave with higher amplitude carries more energy than a wave with lower amplitude. This is because the amplitude represents the maximum displacement from equilibrium, which correlates with the energy of the wave.
When energy is absorbed by a wave, the wave's amplitude decreases and its intensity weakens. This can cause the wave to lose momentum and eventually dissipate.