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Structure of the Sun and Solar Features

Learn about the structure of the sun, including its layers and atmosphere, as well as various solar features such as sunspots, prominences, flares, and coronal mass ejections. Discover the role of nuclear fusion in the sun's core and its lifespan.

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Structure of the Sun and Solar Features

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  1. Warm-up Write at least three facts about the picture above.

  2. Objectives Learning Target: Develop a model based on evidence to illustrate the life span of the sun and the role of nuclear fusion in the sun’s core to release energy in the form of radiation. Success Criteria: • Create a model to show the structure of the sun. • Describe how helium and energy is created through fusion processes in the sun using hydrogen as its fuel source. • Explain that the sun (like all stars) has a lifespan based on initial mass and that our sun’s life span is about 10 billion years. • Using a model, predict how the relative proportions of hydrogen to helium change as the sun ages.

  3. Literacy: The Sun While you read… • Circle important vocabulary terms • Using 3 colors, highlight sentences that answer “Guide for Reading” Questions • Create Cornell notes to answer “Guide for Reading” Questions • Complete Worksheet using information from reading.

  4. Structure of the Sun Objective: Create a model to show the structure of the sun. • Notes should include pictures and important terms. • We will discuss: • Layers of the Sun • Interior • Exterior/Atmosphere • Important features

  5. Layers of the Sun • Sun’s interior • Core – where hydrogen fusion happens. • Radiative zone – energy carried toward surface by radiation (as light). • Convective zone – energy carried toward surface by convection (as heat). • Sun’s atmosphere • Photosphere – lowest layer – emits visible light – what we see. • Chromosphere – middle layer – transparent. • Corona – upper layer – transparent.

  6. INTERIOR of the Sun – 3 layers

  7. ATMOSPHERE of the Sun – 3 layers

  8. The bright visible surface of the Sun is called the photosphere. When looking at the Sun, the edges appear orange and darker than the central yellow region. This is known as limb darkening.

  9. Upon closer inspection, the Sun has a marbled pattern called granulation, caused by the convection of gases just beneath the photosphere.

  10. During an eclipse, sometimes you can see the layers of the Sun’s atmosphere just above the photosphere, which emits only certain wavelengths of light, resulting in a reddish appearance. We call this the sphere of color, or chromosphere.

  11. The solar chromosphere is characterized by jets of gas extending upward called spicules.

  12. THE SOLAR CORONA – source of the Solar Wind This x-ray image shows the million-degree gases. Seen in visible light during an eclipse.

  13. The Sun undergoes differential rotation. The rotation period of the Sun’s gases varies from 25 days in the equatorial region to 35 days near the solar poles.

  14. Therefore, the magnetic field lines of the Sun become intertwined after several rotations, creating regions of intense magnetic fields and thus producing sunspots and other spectacular features.

  15. The Sun’s Magnetic Field Creates Different Features • Sunspots – areas of concentrated magnetic field lines. • Prominences – magnetic loops above sunspots, can carry plasma (hot ionized gas). • Flares – twisted magnetic field lines relax and release huge amounts of X-rays. • Coronal Mass Ejections (CMEs) – twisted magnetic field lines relax and release huge amounts of plasma (up to 4 million mph).

  16. Sunspots Overlapping sunspots Sunspots have two regions: the inner, darker umbra and the outer penumbra.

  17. Sunspots are regions of intense magnetic fields

  18. The number of sunspots on the photosphere varies over an eleven-year cycle. Sunspot Maximum Sunspot Minimum

  19. Sunspots can be used to determine the rate of the sun’s rotation.

  20. Vital information about Sunspots • Areas of reduced temperature • Visible from Earth • Large Amount of Magnetic Activity • Can affect electronics due to the amount of geomagnetism produced.

  21. Ionized gases trapped by magnetic fields form prominences that arc far above the solar surface. Sometimes these gases are ejected into space.

  22. Solar prominences • Looping shape • Relatively cool clouds of gas suspended above the sun • Controlled by magnetic forces

  23. Violent eruptions called solar flares release huge amounts of X-rays. Solar flares are often associated with coronal mass ejections.

  24. On the sun, coronal mass ejections occur when solar magnetic field lines snake around each other, forming the letter "S". Usually, they go past each other. But if they connect, it's like a short circuit. The mid-section breaks loose and drives out a coronal mass ejection.

  25. Coronal Mass Ejections (CMEs) typically expel 2 trillion tons of plasma at up to 4 million mph. It reaches Earth two to four days later, and is fortunately deflected by our magnetic field. An x-ray view of a coronal mass ejection

  26. By following the trails of gases released during a coronal mass ejection, we can map the Sun’s magnetic field.

  27. Solar flares • Exploding areas on the sun • Releases huge amounts of energy • Magnetic field and atmosphere protect Earth from harmful effects • Airline pilots and Astronauts are most impacted by effects • Cause Aurora Borealis (Northern Lights)

  28. Activity: • Create a poster of the Sun. • Be sure to label • Solar flares • Solar prominences • Sunspots • Coronal Mass Projections • Core • Radiactive zone • Convective zone • Photosphere • Chromosphere • Corona

  29. Nuclear Fusion • Objective: Describe how helium and energy is created through fusion processes in the sun using hydrogen as its fuel source.

  30. Let’s Review Fusion!! • Hydrogen is the fuel!!! • Nuclei fuse to form Helium and energy as a product • Extreme temperatures are required for fusion to occur due to the repulsive forces of the nuclei (nuclei are positively charged) • The sun is stable because the force of gravity is balanced by the thermal pressure created by the reactions in the core

  31. The Sun is powered by thermonuclear fusion, which converts hydrogen into helium. Matter gets turned into energy in the process. E = mc2

  32. The Sun’s interior is held stable by a balance between radiation pressure forces and gravity, in a condition called hydrostatic equilibrium. GRAVITY – pulls in RADIATION PRESSURE FROM HYDROGEN FUSION – pushes out

  33. THE SOLAR INTERIOR

  34. Lifespan of the Sun • Objective: Explain that the sun (like all stars) has a lifespan based on initial mass and that our sun’s life span is about 10 billion years. • Our sun is a less massive star and will end as a white dwarf. • We are currently 5 billion years into its lifespan • Let’s watch a video to help us put all of this information together!

  35. Aging Sun and Nuclear Energy Objective: Using a model, predict how the relative proportions of hydrogen to helium change as the sun ages.

  36. Two (2) Hydrogen atoms fuse to make One (1) Helium atom theoretically but… Energy is released as atoms fuse and thus mass is lost as energy It actually takes 4 Hydrogen atoms to make 1 Helium atom

  37. Time to Think! • Let’s try to make sense of all of this! • Read and complete the worksheet: • How Does the Sun Get It’s Energy • Then, read the article cited below • Red Giant Stars: Facts, Definition & the Future of the Sun. Retrieved September 11, 2016, from http://www.space.com/22471-red-giant-stars.html • Create a timeline to show the lifecycle of our sun showing how hydrogen, helium, mass, fusion and gravity play a role in the life and death of our sun.

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