Astron 104 Laboratory #7 Sunspots and the Solar Cycle

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Name: Section: Astron 104 Laboratory #7 Sunspots and the Solar Cycle Section 9.4 In this exercise, you will observe how the physical appearance of the Sun changes from day to day over the period of one month. You will look at images obtained (mostly) from the Big Bear Solar Observatory in California over the month of Dec 2011 and the beginning of Jan 2012. Find a set of images at: http://www.gravity.phys.uwm.edu/~kaplan/astron104/sun_month.html Click on each image for a larger view. You can also navigate directly from the individual pages. In these white-light images, features such as sunspots and limb-darkening are clearly visible. At the time these data were taken, we were approaching a maximum in the 11 year sunspot cycle, so there are a fair number of sunspots visible on most of the days. You will be both counting and sketching the appearance of these sunspots. Sunspots Procedure: On the computer, look at the image for each date in the period. Count the number of sunspots visible on the Sun for that day, and record your results on the answer sheet. You can also use the comment column to make notes on the clarity of the image and/or how easy it was to see the sunspots on that day. [30 pts] Look again at each of the 6 images for Dec 30 to Jan 4. On the sheet provided, sketch the approxiate size and location of the sunspots you see for each day. The resulting set of drawings will show the changes from one day to the next. They will also show the rotation of the Sun. (Note: be sure to label each drawing with the correct date). [5 pts each] The Sun rotates once in about a month. The exact rate varies depending on the latitude: at the equator, the period is about 25 days, while at the poles it is close to 35 days. Compare the images from the beginning of the period with those from the end. Since larger sunspot groups can last for two months, see if you can find the same sunspot group in images taken a month apart. Astron 104 Fall 2013 1

Questions: 1. Is it always clear just what is a single sunspot? Do you think it better to split complicated regions into multiple spots, or lump them all in together? [5 pts] 2. Sunspots are related to strong magnetic fields on the Sun. These magnetic fields work like particle accelerators, producing photons with very high energies compared to most of the Sun. Given that, what type of radiation do you expect to detect from the regions of the sunspots? Why? [5 pts] 3. How could sunspot activity affect the weather on Earth? There are two effects to consider: the total amount of radiation emitted by the Sun, and the energetic particles coming in the Solar wind. [5 pts] Astron 104 Fall 2013 2

4. The photosphere (the visible surface of the Sun) is at a temperature of 5800 K and sunspots on average are around 4200 K. What is the percent difference in temperature between the photosphere and sunspots? At what wavelength does the radiation emitted by each region peak? (Hint: use Wien s law, which says that the peak wavelength λ peak = 3 10 6 nm/t, where T is in Kelvin) [10 pts] 5. Now figure out the percentage change in the flux from the normal photosphere (5800 K) compared to the sunspots (4200 K). Use the Stefan-Boltzmann law: F = σt 4, where T is in Kelvin and σ = 5.7 10 8 W/m 2 /K 4. Does this help explain why the sunspots look so much darker? [10 pts] Astron 104 Fall 2013 3

Solar Cycle Now you will look at data taken once per month for 6 years (which is approximately half of a Solar Cycle): http://www.gravity.phys.uwm.edu/~kaplan/astron104/sun_cycle.html 1. Look at the images for each date. Can you notice any trends between the beginning of the period (at the bottom of the page) and the end of the period (at the top)? Which do you think is closer to the maximum of the Solar Cycle, when sun-spot activity is highest? [10 pts] 2. Look at the images for each date. Can you notice any trends in the overall size of the Sun in each image? What might cause this? [5 pts] Astron 104 Fall 2013 4

Date Number of Sunspots Comments Nov 30 Dec 01 Dec 02 Dec 03 Dec 04 Dec 05 Dec 06 Dec 07 Dec 08 Dec 09 Dec 10 Dec 11 Dec 12 Dec 13 Dec 14 Dec 15 Dec 16 Dec 17 Dec 18 Dec 19 Dec 20 (continued on next page...) Astron 104 Fall 2013 5

Date Number of Sunspots Comments Dec 21 Dec 22 Dec 23 Dec 24 Dec 25 Dec 26 Dec 27 Dec 28 Dec 29 Dec 30 Dec 31 Jan 01 Jan 02 Jan 03 Jan 04 Astron 104 Fall 2013 6

Astron 104 Fall 2013 7

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