2.0Hz.
As all EM waves do a constant speed ('c'). If the frequency increases (i.e. the waves are more frequent) the distance between the wave peaks (wavelength) must reduce. For visible light waves, this produces a 'blue shift.'
A low temp source emits low-frequency, long wavelength waves. A medium temp source emits medium frequency, medium wavelength waves. A high temp source emits high frequency, short wavelength waves.
68 Hertz.
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.
Shorter wavelengths produce a higher resolution because it allows you to see points that are closer together.
As all EM waves do a constant speed ('c'). If the frequency increases (i.e. the waves are more frequent) the distance between the wave peaks (wavelength) must reduce. For visible light waves, this produces a 'blue shift.'
A low temp source emits low-frequency, long wavelength waves. A medium temp source emits medium frequency, medium wavelength waves. A high temp source emits high frequency, short wavelength waves.
there are two answers, one involves wavelength and the other frequency
68 Hertz.
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.
Shorter wavelengths produce a higher resolution because it allows you to see points that are closer together.
The longest whistle recorded belongs to a blue whale, which can produce sounds that can travel hundreds of miles underwater. Their low-frequency whistles can reach lengths of up to 188 decibels.
Yes, although whether or not a human could produce such a scream is debatable. Dogs have hearing that extends into a higher frequency than a human's hearing range, which is why dog whistles work like they do.
Energy per photon is proportional to frequency. That tells us that it's alsoinversely proportional to wavelength.So if Photon-A has wavelength of 400-nm, then wavelength of Photon-Bwith twice as much energy is 200-nm .
A single electron can produce different types of radiation. Radiation, frequency, and wavelength all rely on each other. If an electron can produce multiple types of radiation, it can also produce different wavelengths and frequencies, because the wavelengths and frequencies are dependent on the radiation type.
What is to be produced? How will it be produced? For whom will it be produced? The questions are What to produce, How to produce and For whom to produce
The smallest drop of an electron between two energy states in an atom flips out a photon of radio with a frequency of about 1,420 MHz (wavelength = about 21 centimeters).