It is a very vague question, so i will throw some equations at you:
For relating energy of photon to the frequency:
E = hf = hc/L
h = planck's constant = 6.63 X 10^-34
f = frequency of wave (Hz)
L = wavelength (metres)
For relating luminosity (power) to surface area and temperature:
Luminosity = Energy/Time = K*A*T^4
where A = surface area, K is stefan-Boltzmann constant = 5.67 X 10^-8 and T = temperature (in Kelvin).
For relating Temp to wavelength, use Wien's Law:
Wavelength(in Nanometres) = (2.9 X 10^6)/Temperature (in Kelvin)
For intensity as a function of distance(d (in metres)) from source and power of source:
I = Power of source/(4 * Pi * d^2)
also
Intensity is proportional to amplitude squared.
Hope this helps in some way.
It is emitted in waves.
It is emitted in waves.
in the form of electromagnetic waves.
No! radiation is the transfer of energy in the form of electromagnetic waves.
radio wave is form of electromagnetic energy which has the longest wavelength in electromagnetic spectrum
Ultrasonic waves are high frequency sonic waves. They're sound, which is mechanical energy. Electromagnetic waves are waves of electromagnetic energy, like radio waves or light. Mechanical energy is different from electromagnetic energy, hence the reason for ultrasonic waves not taking the form of electromagnetic waves.
It is emitted in waves.
It is emitted in waves.
Answer: RadiationThis includes visible light, gamma rays, UV rays and other waves. They can be seen in the electromagnetic spectrum.
in the form of electromagnetic waves.
In Electromagnetic waves
Electromagnetic waves
In Electromagnetic waves
radio wave is form of electromagnetic energy which has the longest wavelength in electromagnetic spectrum
No! radiation is the transfer of energy in the form of electromagnetic waves.
radio waves
What form of energy emission accompanies the return of excited electrons to the ground state?