For a body emitting blackbody radiation, the total power emitted is proportional to the 4th power of the body's absolute temperature: Pc 7 (T in kelvins) and the wavelength of the emitted EM radiation that has the highest intensity is inversely proportional to the body's absolute temperature according to: Am 0.0029 T (Amin meters, 7 in kelvins) Assume an object is emitting blackbody radiation. A body in a room at 300 K is heated to 3,000 K. The wavelength of the most intense EM radiation emitted by the body at 3,000 K is the wavelength of the most intense EM radiation at 300 K. a. 10 times b. the same as c. 10,000 times d. 0.0001 times Ce.0.1 times For a body emitting blackbody radiation, the total power emitted is proportional to the 4th power of the body's absolute temperature: Pc 7 (Tin kelvins) and the wavelength of the emitted EM radiation that has the highest intensity is inversely proportional to the body's absolute temperature according to: 0.0029 (ma in meters, Tin kelvins) Assume an object is emitting blackbody radiation. As the temperature of an object increases, the wavelength of the brightest light emitted a. doesn't change. b. decreases. c. depends on the size of the body. d. increases. e. depends on the composition of the body.