When you increase the energy of a wave, its wavelength decreases. This relationship is described by the equation E = h * c / λ, where E is energy, h is Planck's constant, c is the speed of light, and λ is the wavelength. Therefore, as energy increases, the wavelength decreases.
When you decrease the wavelength of a wave, its frequency and energy increase. This is known as blue shift and is common in light waves. Conversely, when you increase the wavelength of a wave, its frequency and energy decrease. This is known as red shift and is also observed in light waves.
Increasing the wavelength typically does not have a direct effect on the amplitude of a wave. The amplitude of a wave is usually determined by the energy or disturbance that created the wave, which is independent of its wavelength.
An increase in energy would generally lead to a decrease in wavelength and an increase in amplitude for a wave. Conversely, a decrease in energy would result in an increase in wavelength and a decrease in amplitude. This is because energy is directly related to the frequency and intensity of a wave, which in turn impacts its wavelength and amplitude.
When the wavelength of light is doubled, the energy of photons decreases by half.
Its frequency increases. Its energy increases (all other parameters being equal).
When you decrease the wavelength of a wave, its frequency and energy increase. This is known as blue shift and is common in light waves. Conversely, when you increase the wavelength of a wave, its frequency and energy decrease. This is known as red shift and is also observed in light waves.
If the frequency remains constant, then the wavelength increases.
Increasing the wavelength typically does not have a direct effect on the amplitude of a wave. The amplitude of a wave is usually determined by the energy or disturbance that created the wave, which is independent of its wavelength.
An increase in energy would generally lead to a decrease in wavelength and an increase in amplitude for a wave. Conversely, a decrease in energy would result in an increase in wavelength and a decrease in amplitude. This is because energy is directly related to the frequency and intensity of a wave, which in turn impacts its wavelength and amplitude.
Remember that wavelength x frequency = speed of the wave.If you increase the wavelength, the frequency will decrease - since the speed of most waves is more or less independent of the frequency or wavelength.
When the wavelength of light is doubled, the energy of photons decreases by half.
Light cannot increase its speed, but it can increase its energy. Doing so will increase its frequency, or equivalently shorten its wavelength. It will thus be blue shifted.
Provided the speed of the wave remains constant, as we increase the frequency of wave then wavelength decreases. Because frequency and wavelength are inversely related.
Increase
Its frequency increases. Its energy increases (all other parameters being equal).
If the speed is increased and the frequency stays the same, the wavelength will also increase. Wavelength is inversely proportional to speed for a constant frequency, so as the speed increases, the wavelength will also increase.
If wavelength increases, frequency decreases inversely. Wave energy remains the same since it is determined by amplitude and not by wavelength or frequency.