Photon Energy E=hf = hc/w thus wavelength w= hc/E or the wavelength is hc divided by the energy of the photon or w= .2 e-24 Joule meter/Photon Energy.
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Energy E=hf=hc/w where w is the wavelength.
They differ in wavelength, E =hf=hc/w.
Energy and wavelength are related by Planck's Energy formula E = hf = hc/w where w is the wavelength.
The energy is E=hf = hc/w where f is frequency, c is the velocity and w is the wavelength.
The heat of the sun reaches the earth by radiation, E = hf =hc/w.
Electromagnetic waves vary in wavelength, Energy and frequency E = hf = hc/w.
hf is the energy of photons incident on the surface
Photon Energy E=hf = hc/w thus wavelength w= hc/E or the wavelength is hc divided by the energy of the photon or w= .2 e-24 Joule meter/Photon Energy.
Planck's Energy formula E= hf = hc/w, provides a way to convert energy to wavelength.Wavelength w= hc/E = .2e-15 joule-nanometers/energy.
The particle (photon) and wave (wavelength) characteristics of light. E =hf = zQ2c/w where Q is the photon charge and w is the wavelength. One problem with the above answer: the charge of a photon is zero. E(photon) = hf where 'h' is Planck's Constant and 'f' is the frequency of the vibrations of light. hf = hc/w where 'c' is the speed of light and 'w' is the wavelength of the light. The more correct answer on "What are the dual characteristics of light" is that light will sometimes act like a wave and sometimes act like a particle -- and what it acts like depends on what experiment you are performing.
E=hf and E= (hc)/w E=energy h=planck's constant f=frequency of light c= speed of light w= wavelength of light (normally represented by the greek letter lambda)
apexvs answer 3.4 x 10-5