1 / 32

Dr. Laura Peticolas Space Sciences Laboratory University of California at Berkeley

2009 International Year of Astronomy The Sun-Earth Connection. Dr. Laura Peticolas Space Sciences Laboratory University of California at Berkeley. Tonight’s main talking points. We learn about our connection to the Sun through careful observations.

mei
Download Presentation

Dr. Laura Peticolas Space Sciences Laboratory University of California at Berkeley

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. 2009 International Year of Astronomy The Sun-Earth Connection Dr. Laura Peticolas Space Sciences Laboratory University of California at Berkeley

  2. Tonight’s main talking points • We learn about our connection to the Sun through careful observations. • Tools (such as telescopes, satellites, computers) help us to understand this connection. • The Sun emits light of many different colors (wavelengths/frequencies) known as the electromagnetic spectrum.

  3. Tonight’s main talking points • The Sun is a magnetic and dynamic star, ever changing in its output of light and particles. • Earth is a giant electromagnet. • The northern and southern lights (auroras) are global, dynamic glowing light displays originating at the boundary between Earth’s atmosphere and space. • The Sun’s particles affect the magnetic field surrounding Earth in a dynamic way.

  4. 1600s:Birth of the Telescope Telescopes increased the ability of people to see details in astronomical objects such as the moons around Jupiter and spots on the Sun. Johannes Hevelius observing with one of his telescopes (from galileo.rice.edu) Galileo’s telescopes (from galileo.rice.edu)

  5. Sunspots: Observations In 1612 during the summer months, Galileo made a series of sunspot observations which were published in Istoria e Dimostrazioni Intorno Alle Macchie Solari e Loro Accidenti Rome (History and Demonstrations Concerning Sunspots and their Properties, published 1613). Galileo’s sunspot drawing (from galileo.rice.edu)

  6. Sunspots: Observations Because these observations were made at approximately the same time of day, the motion of the spots across the Sun can easily be seen. Conclusion: the Sun rotates on its axis. Movie made from Galileo’s sunspot drawings from June 2, 1613 – July 8, 1613 (from galileo.rice.edu)

  7. Sunspots: A modern understanding • Sunspots are about 2,000 degrees Kelvin cooler than the average temperature on the photosphere (5,000 degrees Kelvin). • They are bright but appear to be dark only in comparison to their very bright surroundings. • Following long-lived sunspots through time allows one to determine the rotation rate of the Sun (25-36 days). • The Sun spins faster at the equator (25 days) than at the poles (36 days).

  8. What is the Sun? The Sun is a Star, but seen close-up. The Stars are other Suns but very far away. Stars, including the Sun, are giant balls of very hot, mostly ionized gas that shine under their own power (from nuclear fusion).

  9. Modern Solar Science: Careful Observations In 2006 NASA launched the STEREO (Solar Terrestrial Relations Observatory) spacecraft to continue our study of the Sun in ways not possible on Earth. To understand why the scientific instruments (tools) on the spacecraft needed to be above Earth’s atmosphere and magnetic field, we need a little more background.

  10. Light: Careful Observations 1666 A.D. Sir Isaac Newton used a prism to show that white light from the Sun disperses to form a series of colors called the spectrum Prism with white light shining through the prism, shown at the top of the image, and the rainbow of colors (spectrum) coming out of the prism, shown at the bottom of the image.

  11. Electromagnetic Spectrum 1800 A.D. Fredrick W. Herschel used a prism and thermometers to measure the temperature of each color of light. During this experiment he placed a thermometer to one side of the spectrum and discovered infrared light.

  12. The Multiwavelength Sun Looking at the Sun in different wavelengths of light reveals different parts of the Sun with different temperatures. 2 bright spots Fe XII Extreme Ultraviolet light: Wavelength = 19.5 nm T = 1.5 million K 2 dark spots Visible light (white light): Wavelength = 400-700 nm T = 5,800 K 2 bright spots He II Extreme Ultraviolet light: Wavelength = 30.4 nm T = 60,000-80,000 K 2 bright spots Fe IX, X Extreme Ultraviolet light: Wavelength = 17.1 nm T = 1 million K

  13. The Multiwavelength Sun The Extreme Ultraviolet Light (EUV light) is blocked by our atmosphere – we have to go to space to get these images. 2 bright spots Fe XII Extreme Ultraviolet light: Wavelength = 19.5 nm T = 1.5 million K 2 dark spots Visible light (white light): Wavelength = 400-700 nm T = 5,800 K Space-based image (STEREO) Earth-based image 2 bright spots He II Extreme Ultraviolet light: Wavelength = 30.4 nm T = 60,000-80,000 K 2 bright spots Fe IX, X Extreme Ultraviolet light: Wavelength = 17.1 nm T = 1 million K Space-based image (STEREO) Space-based image (STEREO)

  14. Observations of the Sun Images from NASA TRACE ‘Zoom in’ images of the Sun in ultraviolet light reveal loops of hot ionized gas (plasma) trapped in magnetic fields above the locations of Sunspots.

  15. N S The Magnetic Sun Above: Magnetic field tracing above sunspots on the visible Sun. Left: Magnetic field tracing using a compass around two magnetic poles

  16. STEREO Views: June 2007 http://stereo-ssc.nascom.nasa.gov STEREO camera B STEREO camera A STEREO Viewing geometry.

  17. The Sun in 3D

  18. STEREO Views: April 2009 http://stereo-ssc.nascom.nasa.gov STEREO camera B SOHO camera STEREO camera A Now we can study the sides of the Sun we cannot normally take images of. STEREO Viewing geometry. SOHO is located near Earth between Earth and the Sun (i.e. looking straight to the Sun from Earth)

  19. Atmosphere of the Sun During a total eclipse of the Sun, the very bright Photosphere is blocked and the Sun’s outer atmosphere becomes visible (in white light). We call it the Corona. Spacecraft, like SOHO and STEREO, place a disk in front of their cameras to create an eclipse. They are then able to take images with a larger view of the Sun’s Corona. It extends far out into the Solar System, in fact we live in it!

  20. Solar Flares & CMEs Coronal Mass Ejections (CMEs) are literally ejections of mass from the Sun’s corona. CMEs occur when large-scale magnetic fields “break” and release energy and enormous amounts of matter into space. Solar flares are enormous explosions in the atmosphere of the Sun.They release energy in the form of light, heat, and the movement of large amounts of plasma.

  21. STEREO CMEs – new! Coronal Mass Ejections (CMEs) are literally ejections of mass from the Sun’s corona. CMEs occur when large-scale magnetic fields “break” and release energy and enormous amounts of matter into space. CME continues into the solar system

  22. The Solar Wind The solar wind is a stream of mostly charged particles that emanate from the Sun and blow throughout the Solar System. The Suns Magnetic field flows with these particles. We have turned the data from these charged particles and magnetic fields into sounds and put the sounds with a movie of the outermost atmosphere of the Sun from STEREO. We are watching the Sun’s outer atmosphere from far away while listening to the solar wind data nearby the spacecraft. Find out more here http://cse.ssl.berkeley.edu/impact/sounds.html

  23. Earth

  24. Earth’s Magnetic Field: Careful Observations In the late 1500's, William Gilbert realized that the compass was a tiny magnet and it was interacting with a larger magnetic field in order to point north. In 1600, he published "De Magnete" explaining that "the globe of the earth is magnetic, a magnet," Chapter 17, Book 1.

  25. Satellite observations: Earth’s Magnetosphere The solar wind is electrically and magnetically connected to Earth’s magneto-sphere Satellite data (from sophisticated compasses and particle detectors) out into space compared with computer models gives us this model for Earth’s Magnetosphere.

  26. Aurora Observations in 1800s La Recherche Expedition, 1838-1840 (woolgathersome.blogspot.com)

  27. August 28, 1859 Galveston, Texas: “August 28 as early as twilight closed, the northern sky was reddish, and at times lighter than other portions of the heavens. At 7:30 PM a few streamers showed themselves. Soon the whole sky from Ursa Major to the zodiac in the east was occupied by the streams or spiral columns that rose from the horizon. Spread over the same extent was an exquisite roseate tint which faded and returned. Stately columns of light reaching up about 45 degrees above the horizon moved westward. There were frequent flashes of lightning along the whole extent of the aurora. At 9:00 PM the whole of the streaking had faded leaving only a sort of twilight over the northern sky.”

  28. Observations from Space North Oval Aurorae are found in an oval around the North and South Magnetic Poles. These ovals are always present. South Oval Images on the left are from the IMAGE satellite in 2001 and 2004 (UV Light) with continents drawn on image. Cusp Aurora Image on the right is from the Polar Satellite, 2001 (UV Light.) Both Ovals

  29. Aurora observed in 2008 from the ground (aurora oval detail) THEMIS All-sky camera mosaic image of aurora across the Northern American Continent. The cameras looking up using cameras with a wide field-of-view.

  30. Sun-Earth Connection (1128 A.D.) In 2001, Astronomers drew a link between the earliest known record of sunspots, drawn by John of Worcester in England in AD 1128, and the aurora borealis (northern lights) recorded in Korea five days later. http://www.abc.net.au/science/articles/2001/07/18/330954.htm

  31. Space Weather Effects • Energy from Solar Flares and CMEs can damage satellites and change orbits. • Disrupt radio communications • CME particles traveling near the speed of light threaten Astronauts. • CMEs can intensify auroras (Northern and Southern Lights) • Electric currents from intense aurora can cause power surges and blackouts. • Electric currents from intense aurora create interesting magnetic field variations detectable on Earth.

  32. Magnetic Reconnection Model – confirmed for one case in 2008 • When a CME passes Earth, it can “drag” the magnetic tail far out into space. • Stretched magnetic lines can break and then reconnect into a different shape. • Electrons, guided by the magnetic field, speed up towards Earth and enhance auroras.

More Related