7.5*
The frequency range for visible light is 400-790 THz
1 x 1012 - 4.3 x 1014 Hz the frequency is 300 to 400 thz (tera hertz). the wave length is 1mm to .0008mm
the energy of the wave brah
Wavelength = (speed)/(frequency)For a 10,000 Hz wave:,Wavelength = (speed)/(10,000) metersThat's (speed) x 100,000 nanometers.,For a 20,000 Hz wave:,Having doubled the frequency, the wavelength has now been reduced by half.So wavelength is now (speed) x 50,000 nanometers.,Note: It's often nice to be able to work with sine waves, but when you're only talking about frequency and wavelength, the wave-shape doesn't matter.
The answer is 5.0*1014 Hertz.
The wavelength of an ultraviolet wave typically ranges from about 10 nanometers to 400 nanometers. This places ultraviolet waves just outside the visible light spectrum, which generally ranges from 400 to 700 nanometers.
The frequency range for visible light is 400-790 THz
1 x 1012 - 4.3 x 1014 Hz the frequency is 300 to 400 thz (tera hertz). the wave length is 1mm to .0008mm
the energy of the wave brah
Wavelength = (speed)/(frequency)For a 10,000 Hz wave:,Wavelength = (speed)/(10,000) metersThat's (speed) x 100,000 nanometers.,For a 20,000 Hz wave:,Having doubled the frequency, the wavelength has now been reduced by half.So wavelength is now (speed) x 50,000 nanometers.,Note: It's often nice to be able to work with sine waves, but when you're only talking about frequency and wavelength, the wave-shape doesn't matter.
The answer is 5.0*1014 Hertz.
The laser light is the type of light that only has one wavelength in its phase. Coherent light is light that has a single frequency and wavelength, and can be described with a single wave equation.
Short answer: Very short More precise answer: 10 nanometers to 400 nanometers for one full wave (depending on how 'ultra' it is)
The frequency of a wave can be calculated using the formula: frequency = speed of light / wavelength. Given that the speed of light is approximately 3 x 10^8 meters per second and the wavelength is 500 nanometers (which is 500 x 10^-9 meters), the frequency would be approximately 6 x 10^14 hertz.
No. The higher the frequency of a wave, the higher the energy.
400 nanometers = 4.0 × 10-10 kilometers
The period of a sine wave is the reciprocal of the frequency. So, if the time period is 2.5 microseconds, the frequency would be 1 / 2.5 microseconds, which is 400 kHz.