1. Solve Wien's Law for T, substitute in the values for wavelength. With the temperature you obtain, look on the H-R diagram for the corresponding spectral class.

(a) 9656 K Class A; (b) 19,313 K Class B; (c) 5267.2 K Class G; (d) 2317 K Class M

2. Substitute the temperatures into Wien's Law and obtain the wavelengths of the peak emission. Look up on a chart of the EM spectrum which region the wavelength falls into.

(a) 289.7 cm radio; (b) 3.62x10^-4 cm infrared; (c) 1.93x10^-5 cm ultraviolet;

(d) 1.65x10^-7 cm X-ray

Extension:

No astronomical objects are as cold as 0.001 Kelvin. The radio emission we observe is produced by electrons moving in magnetic fields (this is called synchrotron radiation).

Using the equation: distance = velocity x time,

Cygnus: 9.14x10¹⁴ km; Crab: 4.46x10¹³ km; Tycho: 6.96x10¹³ km; SN1006: 9.37x10¹³ km

The supernova occurred in the year 1604 and is known as Kepler's supernova. It was observed and documented by the astronomer Johannes Kepler.

Using the equation: mass = density x volume,

We are given that the volume of interest is 1.5 cm³. So what is the density of each of the objects? Density equals mass/volume, and the volume of a sphere is ⁴/₃ p r³, where r is the radius of the sphere. Plugging in the values for each of the types of stars, we find that our teaspoon of the Sun would contain 2.1 grams; of the white dwarf would contain 2.85x10⁶ grams; of the neutron star would contain 9.75x10¹⁴ grams. By looking up the density of water, air, and iron, you can calculate that each would be 1.5 grams, 1.935x10^-3 grams, and 11.7 grams, respectively.