Your terminologies are inconsistent. Wave lengths are not high and low. They are long and short. Short wave (UHF) radio for example.
There are two wave characteristics that can be termed high and low: amplitudes and frequencies.
Assuming group S wave characteristics (e.g., water and light beam waves) the higher frequency and higher amplitude waves carry the most energy. Ditto for group P wave characteristics (e.g., seismic waves).
Yes, a photon with a wavelength of 420nm contains more energy than a photon with a wavelength of 790nm. This is because energy is inversely proportional to wavelength, meaning shorter wavelengths have higher energy.
The wave with the shorter wavelength will transmit more energy than the one with the longer wavelength if two waves have the same amplitude and same speed but differ in wavelength. The energy transmitted by the shorter wavelength will normally be four times more than the energy transmitted by the longer wavelength.
A high energy light will have a shorter wavelength than a low energy light. If the wavelength goes down, then the frequency goes up. When calculating energy in the equation, E=hv, frequency (v) is the variable, not the wavelength. So in the equation, if you wanted a more energy (E), you would have the frequency be large. For the frequency to be big, then the wavelength has to be low.
Short-wavelength light carries more energy than long-wavelength light. This is because energy is directly proportional to frequency, and shorter wavelengths have higher frequencies. This relationship is described by Planck's equation, E = h*f, where E is energy, h is Planck's constant, and f is frequency.
Violet light has more energy than red light because it has a shorter wavelength. In the electromagnetic spectrum, energy is directly proportional to frequency and inversely proportional to wavelength. Since violet light has a shorter wavelength, it has a higher frequency and therefore more energy compared to red light.
Yes, a photon with a wavelength of 420nm contains more energy than a photon with a wavelength of 790nm. This is because energy is inversely proportional to wavelength, meaning shorter wavelengths have higher energy.
The wave with the shorter wavelength will transmit more energy than the one with the longer wavelength if two waves have the same amplitude and same speed but differ in wavelength. The energy transmitted by the shorter wavelength will normally be four times more than the energy transmitted by the longer wavelength.
A high energy light will have a shorter wavelength than a low energy light. If the wavelength goes down, then the frequency goes up. When calculating energy in the equation, E=hv, frequency (v) is the variable, not the wavelength. So in the equation, if you wanted a more energy (E), you would have the frequency be large. For the frequency to be big, then the wavelength has to be low.
Energy varies with the wavelength. The shorter the wavelength the higher the energy. Ultraviolet much more energetic than red light.
A high energy light will have a shorter wavelength than a low energy light. If the wavelength goes down, then the frequency goes up. When calculating energy in the equation, E=hv, frequency (v) is the variable, not the wavelength. So in the equation, if you wanted a more energy (E), you would have the frequency be large. For the frequency to be big, then the wavelength has to be low.
Short-wavelength light carries more energy than long-wavelength light. This is because energy is directly proportional to frequency, and shorter wavelengths have higher frequencies. This relationship is described by Planck's equation, E = h*f, where E is energy, h is Planck's constant, and f is frequency.
The energy of infrared waves is greater than the energy of radio waves. This is because infrared waves has a smaller wavelength compared to radio waves. The smaller the wavelength, the higher the energy.
When an electron falls from n4 to n1, it releases more energy because it is transitioning between high energy states. This higher energy transition corresponds to a shorter wavelength of light being emitted, according to the energy of the photon being inversely proportional to its wavelength. In contrast, when an electron falls from n2 to n1, the energy released is less, resulting in a longer wavelength of light emitted.
if the photon energy is increased , wavelength is decrasing for this formulas E=hv=hc/λ and also we can give an example red colors has so high wavelength than purple . Therefore energy of red colors photon is bigger than other and efficiency high
Violet light has more energy than red light because it has a shorter wavelength. In the electromagnetic spectrum, energy is directly proportional to frequency and inversely proportional to wavelength. Since violet light has a shorter wavelength, it has a higher frequency and therefore more energy compared to red light.
Yes. The wavelength of radiation is w=hc/Energy. Gamma energy is larger than infrared energy, thus has shorter wavelength.
The shortest wavelengths have the most energy because it has the highest frequency. A high energy light will have a shorter wavelength than a low energy light. If the wavelength goes down, then the frequency goes up. When calculating energy in the equation, E=hv, frequency (v) is the variable, not the wavelength. So in the equation, if you wanted a more energy (E), you would have the frequency be large. For the frequency to be big, then the wavelength has to be low.