Momentum, energy, frequency, and wave number (but not wave vector.)
Energy of a photon of this wave would be (planck's constant) ( frequency) E = hf = 5.46 * 10-22 J So to find the energy of the whole wave, multiply the energy of a photon to the no. of photons in a wave.
The energy of the wave pulse depends on wave length and frequency.
A wave transports energy. The greater the energy, the greater the amplitude of the wave.
The answer is true. The greater the energy the greater the amplitude.
Momentum, energy, frequency, and wave number (but not wave vector.)
Energy of a photon of this wave would be (planck's constant) ( frequency) E = hf = 5.46 * 10-22 J So to find the energy of the whole wave, multiply the energy of a photon to the no. of photons in a wave.
it is a wave that is formed by energy
Any wave carries energy.
The energy of the wave pulse depends on wave length and frequency.
A wave transports energy. The greater the energy, the greater the amplitude of the wave.
The answer is true. The greater the energy the greater the amplitude.
Divided the wave's speed by its wavelength.
The type of wave that has the least amount of energy is the longitudinal wave. In contrast, the wave with the most amount of energy is a seismic wave.
What are the advantages and disadvantages of wave energy
wave transmitt energy the the force that the wave has
The energy of a wave moves forward with the wave. A wave is moving energy, and the wave carries it in the direction of propagation.