Blackbody Spectrum - PhET Name Period INTRO NOTES: 1. Angstroms (Å), nanometers (nm) and micrometers (or microns, μm) are all units for very short distances like the wavelength of light. 2. One micron is one of a meter and one angstrom is of a meter while one nanometer is one of a meter. 3. Visible light is in the thousands of angstroms: 1000 Å = you can think of it a 1 μm = nm. nm = 4. Looking at the graph, the bottom axis is measured in part of the spectrum is found between what wavelengths? μm or and the visible & 5. Temperature is measured in units of K (kelvin) that is a measure of the “absolute” temperature of an object. Many application of science require that there are no negative numbers on the temperature scale so the kelvin (or absolute) scale is used. The kelvin scale is just the Celsius scale shifted by 273 degrees, so water that boils at 100 °C boils at 373 K on the kelvin scale. Notice the number of Celsius degrees is 273 less than the kelvin value. What is initial temperature? K= °C. 6. The “starburst” at the top of the screen represents the color that you would see if you saw a blackbody heat source that had the temperature shown. They have simplified the spectrum into three colors, blue, green and red. Which of these colors appears to be the brightest? 7. Look at the curved red line on the graph. This line represents the intensity of all of the “light” given off by an object at the temperature shown. Remember, to an astronomer “light” is all wavelengths not just visible, but also invisible. Is the red line at the same level for each of the three colors (blue, green & red) listed next to the starburst? 8. Where is infrared located on the graph, left or right of the spectrum? Would an infrared sensor be able to detect this source? Explain 9. Where is ultraviolet located on the graph? Would an ultraviolet sensor be able to detect this source? Explain 10. The source in this simulation is emitting EM radiation “light” at a wide range of wavelengths. What is the wavelength with the greatest intensity? μm = nm. 11. Wien’s law relates the peak wavelength of a blackbody source to its temperature in the 2.90 10 6 nm K 2,900,000 nm K equation T . Use the wavelength in nm from #10 to peak ,nm peak ,nm calculate the temperature of the blackbody in the simulation. How does it compare to the value recorded in #5 above? Now it is time to play with the simulation. Lower the temperature of the source. 12. Describe the change in the color of the source. 13. Describe the change in the shape of the graph. 14. How does the peak wavelength change? 15. What is the peak wavelength? nm. Use Wien’s law to estimate the temperature of the source. Show your calculation. How does the calculated temperature compare to the simulation? Now raise the temperature of the source. 16. Describe the change in the color of the source. 17. Describe the change in the shape of the graph. 18. How does the peak wavelength change? 19. What is the peak wavelength? nm. Use Wien’s law to estimate the temperature of the source. Show your calculation. How does the calculated temperature compare to the simulation? 20. At what temperature would an oven heating element just begin to glow red? K 21. What does this simulation assume is the average temperature of the earth’s surface? What would this be in Celsius? K °C 22. We see the earth by reflected light, but why don’t we see the earth glowing except at a few spots where there is an active volcano. Which of our senses would let us detect the EM radiation being given off by the earth? 23. According to this simulation, what is the color of an operating incandescent light bulb? 24. Which spectral primary color is needed the least to produce the light bulb color? 25. Is an incandescent light bulb primarily a light source or a heat source? Explain . Wien’s Law Practice http://astro.unl.edu/naap/hr/hr_background1.html UV V B G Y OR IR Star 1 Wien’s Law 𝑇= 2.90×106 𝐾∙𝑛𝑚 𝑝𝑒𝑎𝑘 Star 2 Star 3 Star 4 Wavelength 1. Use Wien’s Law to determine the temperature of each “star.” SHOW ONE EXAMPLE CALCULATION. These curves are for ideal blackbody radiators (ideal stars) and NOT real stars. Fill in the table. STAR Estimated Peak Wavelength (nm) Temperature (K) Predicted Color of Star 1 2 499.6 3 4 2. Which star has the highest temperature according to Wien’s Law? 3. The hottest star would appear to be what color? 4. By looking at the graph, predict the color of each star and record it in the table above.