If the frequency stays the same, then the wavelength stays the same.
The wavelength decreased and the frequency increased.
... frequency of the electromagnetic radiation of which the photon is a particle.
Once the wave has left the source that generated it, the frequency can't be changed.If you happen to be moving toward or away from the source at a high enoughspeed, then the frequency of the radiation may appear to you to be changed.But it's not.
Pitch is affected by the frequency and wavelength of a sound wave. When the frequency is lower there are not as many waves per second, and the wavelength becomes longer. A low pitch is made by the low frequency and long wavelength of a sound wave.
The difference is the wavelength's of the two colors, Red is on the "right" end of the visible light spectrum and thus "bigger" wavelength about 640-700 nanometers while Green is more on the "left" side at around 500 nanometers.
The wavelength decreased and the frequency increased.
The mass remain unchanged.
draw a triangle and make 3 areas in the triangle. on the top is S or Speed. on the bottom left is F or Frequency. and on the bottom right is a bckwards/upside down Y for Wavelength. then S divided by For Y. and F times Y. will get you wavelength and what you need. draw what i just said.
... frequency of the electromagnetic radiation of which the photon is a particle.
Question is to be corrected as to find the velocity of the sound waves Formula for velocity of the wave = frequency x wavelength Given frequency = 262 Hz and wavelength = 1.3 m So velocity = 262 x 1.3 = 340.6 m/s
As you go farther right down the spectrum (radio waves, microwaves, infrared waves, visible light, ultraviolet light, x-rays, and gamma rays), the waves' wavelengths decrease as their frequencies decrease. For example, x-rays have a shorter wavelength and higher frequency than ultraviolet light. Radio waves on the left end have the longest wavelength and shortest frequency, while gamma rays on the right end have the shortest wavelength and highest frequency.
Once the wave has left the source that generated it, the frequency can't be changed.If you happen to be moving toward or away from the source at a high enoughspeed, then the frequency of the radiation may appear to you to be changed.But it's not.
The oscillator starts at relatively low frequency and emits electromagnetic radiation of relatively low frequency (or long wavelength) and low intensity. As the heating continues, the frequency of oscillation also increases as does the frequency of the emitted radiation and the intensity of the radiation. A graph of intensity vs. wavelength would start high on the left (at short wavelengths) and fall off to the right exponentially to low intensity at long wavelengths. This graph would be at odds with the experimentally established graph of intensity vs. wavelength(which shows low intensity at short wavelengths) because the classical assumption that frequency of oscillation can increase continuously as the oscillators are heated is not correct. Frequency of oscillation can increase only in integral multiples of the fundamenal frequency.
Pitch is affected by the frequency and wavelength of a sound wave. When the frequency is lower there are not as many waves per second, and the wavelength becomes longer. A low pitch is made by the low frequency and long wavelength of a sound wave.
A controlled variable is a variable left unchanged in an experiment
It would be left unchanged.
The difference is the wavelength's of the two colors, Red is on the "right" end of the visible light spectrum and thus "bigger" wavelength about 640-700 nanometers while Green is more on the "left" side at around 500 nanometers.