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Black body radiation
Black body is an ideal body that absorbs all incident radiation without reflecting any energy. As temperature increases, the peak wavelength emitted decreases and total energy emitted increases. Early models like Rayleigh-Jeans law failed to accurately predict blackbody radiation at small wavelengths, known as the ultraviolet catastrophe. Planck's law and other laws like Wien's displacement law, Stefan-Boltzmann law accurately describe blackbody radiation. Blackbody radiation spectrum depends only on temperature and not the object.
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Black body radiation
- 1. DISUSUN OLEH Rahmawati Th.Diamanti Ivone Pudihang Recky Lasut Aulinda Tambuwun Deyvita Montolalu
- 2. What is aBlack Body ? A black body is an ideal body which allows the whole of the incident radiation to pass into itself ( without reflecting the energy ) and absorbs within itself this whole incident radiation (without passing on the energy).
- 3. Black body radiationcurves showing peak wavelengths at various temperatures The graph shows: • As the temperature increases, the peak wavelength emitted by the black body decreases. • As temperature increases, the total energy emitted increases, because the total area under the curve increases.
- 4. BLACK BODY RADIATIONLAW The Rayleigh-Jeans Law. 2ckT I ( , T ) 4 • It agrees with experimental measurements for long wavelengths. • It predicts an energy output that diverges towards infinity as wavelengths grow smaller. • The failure has become known as the ultraviolet catastrophe
- 5. Planck's law ofblackbody radiation where • I(ν,T) is the energy per unit time (or the power) radiated per unit area of emitting surface in the normal direction per unit solid angle per unit frequency by a black body at temperature T; • h is the Planck constant; • c is the speed of light in a vacuum; • k is the Boltzmann constant; • ν is the frequency of the electromagnetic radiation; and • T is the temperature of the body in kelvins.
- 6. Wien's displacement law •Wien's displacement law shows how the spectrum of black body radiation at any temperature is related to the spectrum at any other temperature. If we know the shape of the spectrum at one temperature, we can calculate the shape at any other temperature. • A consequence of Wien's displacement law is that the wavelength at which the intensity of the radiation produced by a black body is at a maximum, λmax, it is a function only of the temperature
- 7. Stefan-Boltzmann Law The Stefan–Boltzmannlaw states that the power emitted per unit area of the surface of a black body is directly proportional to the fourth power of its absolute temperature: where j*is the total power radiated per unit area, T is the absolute temperature and σ = 5.67×10−8 W m−2 K−4 is the Stefan–Boltzmann constant.
- 8. BENCANA ULTRAVIOLET when theactual radiation emitted from a black-body was measured, it was seen not to shoot toward in infinite at the ultraviolet region of the electromagnetic scale (as the theories suggested), but rather to be highest toward the middle of the visible range of the spectrum, which seemed entirely counter-intuitive. It is for this reason that the discrepancy became known as The Ultraviolet Catastrophe.
- 9. CONCLUSION Blackbody radiation doesnot depend on the type of object emitting it. Entire spectrum of blackbody radiation depends on only one parameter, the temperature, T
- 10. H K Y O U