Shorter wavelength indicates higher frequency and higher energy per photon.
As the wavelength of electromagnetic waves gets shorter, the energy carried by the waves increases. This is because energy is directly proportional to frequency, and shorter wavelengths correspond to higher frequencies. Therefore, as the wavelength decreases, the energy carried by the waves increases.
If the amount of energy a wave carries is increased, the frequency would increase while the wavelength decreases. This is because energy is directly proportional to frequency and inversely proportional to wavelength in a wave.
-- Frequency and wavelength of a wave are inversely proportional. So knowing one of them determines what the other one must be. -- Amplitude has no relationship to frequency or wavelength, and no effect on them.
As the wavelength of light decreases, the energy of the photons increases. This means that shorter wavelengths can carry higher energy. For example, ultraviolet and X-ray light have shorter wavelengths than visible light and carry more energy.
True. Shorter wavelengths of electromagnetic radiation correspond to higher energy levels. This relationship is described by the equation E=hf, where E is energy, h is Planck's constant, and f is frequency. The higher the frequency (related to wavelength inversely), the more energy the wave carries.
As the wavelength of electromagnetic waves gets shorter, the energy carried by the waves increases. This is because energy is directly proportional to frequency, and shorter wavelengths correspond to higher frequencies. Therefore, as the wavelength decreases, the energy carried by the waves increases.
If the amount of energy a wave carries is increased, the frequency would increase while the wavelength decreases. This is because energy is directly proportional to frequency and inversely proportional to wavelength in a wave.
-- Frequency and wavelength of a wave are inversely proportional. So knowing one of them determines what the other one must be. -- Amplitude has no relationship to frequency or wavelength, and no effect on them.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
Higher energy is carried by electromagnetic radiation with higher frequency (shorter wavelength). Of the items listed in the question, the one with the highest frequency (shortest wavelength) is blue light.
As the wavelength of light decreases, the energy of the photons increases. This means that shorter wavelengths can carry higher energy. For example, ultraviolet and X-ray light have shorter wavelengths than visible light and carry more energy.
Their wavelength (or frequency), the energy carried by each photon, and the names we give them. Their speeds are all the same.
True. Shorter wavelengths of electromagnetic radiation correspond to higher energy levels. This relationship is described by the equation E=hf, where E is energy, h is Planck's constant, and f is frequency. The higher the frequency (related to wavelength inversely), the more energy the wave carries.
Your question makes no sense.
They differ in frequency. (That's exactly the same thing as saying that they differ in wavelength, since frequency and wavelength are firmly connected.) (That's also the same thing as saying that they differ in the quantity of energy carried by each photon, since the amount of energy carried by each photon is firmly connected to frequency.)
Radio waves, microwaves, and other parts of the electromagnetic spectrum differ in their frequency and wavelength. Radio waves have the lowest frequency and longest wavelength, while microwaves have a higher frequency and shorter wavelength. Other parts of the spectrum, such as infrared, visible light, ultraviolet, X-rays, and gamma rays, have progressively higher frequencies and shorter wavelengths. Each part of the spectrum interacts with matter in unique ways, influencing their applications in technology and communication.
The energy of electromagnetic waves is carried by photons, which are particles of light. The energy of electromagnetic waves increases as the frequency of the waves increases.