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Blackbody radiation

Blackbody radiation. Goals: Understand properties of Black body radiation ; Radiation power, intensity and angle dependence. Summary. Radiation power mainly concentrated in an interval of

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Blackbody radiation

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  1. Blackbody radiation • Goals: • Understand properties of Black body radiation; • Radiation power, intensity and angle dependence

  2. Summary • Radiation power mainly concentrated in an interval of • wavelengths near the peak. The peak in the power spectrum moves to longer wavelengths when T decreases. • The integrated (the area below the power spectrum) or total radiation power per unit surface area decreases as T decreases. Wien’s displacement law Stefan-Boltzmann Law

  3. Q1 At about 6000K, the sun is radiating light with peak wavelength about 480nm. For human bodies, estimate the peak wavelength of the blackbody radiation. • 1 nm; • 100 nm; • 9,600 nm; 4) 1 mm;

  4. Blackbody radiation at T=310K Estimate a human body radiation power.

  5. Blackbody radiation at T=3K

  6. Q2 Currently, the temperature of our universe is measured to be 2.7 K. Find the ratio between the radiation power per unit area of the universe (P1) and the radiation power per unit area of our human bodies (P2), i.e. P1/P2. 1) 10,000; 2) 1; 3) 10^(-2); 4) 10^(-8).

  7. Power (P) and Intensity (I) of sources Power: Radiation energy emitted per unit time; P=E/t Intensity: radiation power per unit time per unit area I=Total Power/Total Area. For the box shown here, the incoming radiation power is: P=I X The top surface area of

  8. Incident-angle (theta) dependence of instensity . theta

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