Plasmas in Space: From the Surface of the Sun to the Orbit of the Earth Steven R. Spangler, University of Iowa Division of Plasma Physics, American Physical.

Slides:

Advertisements

Similar presentations

Lectures in Plasma Physics

Advertisements

The Propagation Distance and Sources of Interstellar Turbulence Steven R. Spangler University of Iowa.

The Solar Corona and Solar Wind Steven R. Cranmer Harvard-Smithsonian Center for Astrophysics.

The Sun’s Dynamic Atmosphere Lecture 15. Guiding Questions 1.What is the temperature and density structure of the Sun’s atmosphere? Does the atmosphere.

Weaker Solar Wind Over the Protracted Solar Minimum Dave McComas Southwest Research Institute San Antonio, TX With input from and thanks to Heather Elliott,

“The Role of Atomic Physics in Spectroscopic Studies of the Extended Solar Corona” – John Kohl “High Accuracy Atomic Physics in Astronomy”, August.

Review Vocabulary magnetic field: the portion of space near a magnetic or current-carrying body where magnetic forces can be detected The Sun contains.

Ryan Payne Advisor: Dana Longcope. Solar Flares General  Solar flares are violent releases of matter and energy within active regions on the Sun.  Flares.

Announcements Pick up graded homework Seminar on gravitational waves today, 1:00, SL 240 No class this Friday! Test next week on material through today’s.

Test #1, Wednesday, Feb 10 I will post a review for Test 1 in the A101 homepage under the link to “Lectures” this week. I will tell you the topics to review.

Astronomy Picture of the Day. The Sun Core temperature - 15 million K Surface temperature K 99.9% of all of the matter in the solar system Entirely.

Measuring the Magnetic Field in the Sun and the Interstellar Medium Steven R. Spangler… University of Iowa.

Is There Life Out There? Our Solar System (and beyond) Draw a picture of what you think life would look like on another planet, if it existed. Describe.

Our Sun 16 October Today: Basic facts about the sun Solar details: Granulation, sunspots, magnetic fields, flares, prominences, corona, solar wind.

Interplanetary Scintillations and the Acceleration of the Solar Wind Steven R. Spangler …. University of Iowa.

What coronal parameters determine solar wind speed? M. Kojima, M. Tokumaru, K. Fujiki, H. Itoh and T. Murakami Solar-Terrestrial Environment Laboratory,

Physical analogies between solar chromosphere and earth’s ionosphere Hiroaki Isobe (Kyoto University) Acknowledgements: Y. Miyoshi, Y. Ogawa and participants.

The Solar Corona Steven R. Spangler Department of Physics and Astronomy University of Iowa.

Coronal Heating of an Active Region Observed by XRT on May 5, 2010 A Look at Quasi-static vs Alfven Wave Heating of Coronal Loops Amanda Persichetti Aad.

The Sun and the Heliosphere: some basic concepts…

The Sun Earth Science - Mr. Gallagher. The Sun is the Earth's nearest star. Similar to most typical stars, it is a large ball of hot electrically charged.

The Sun. Solar Prominence Sun Fact Sheet The Sun is a normal G2 star, one of more than 100 billion stars in our galaxy. Diameter: 1,390,000 km (Earth.

Radio Remote Sensing of the Corona and the Solar Wind Steven R. Spangler University of Iowa.

Our Star, the Sun and The Nature of the Stars Chapter 18 & 19 Sun Energy source Interior structure and helio-seismology Surface features Atmosphere of.

The Sun The Sun is a star Huge ball of glowing ionized gas… plasma. Gravity vs. Nuclear Fusion Gravity wants to crush the star Fusion wants to explode.

The Sun Section 26.1.

Space Weather from Coronal Holes and High Speed Streams M. Leila Mays (NASA/GSFC and CUA) SW REDISW REDI 2014 June 2-13.

Plasmas. The “Fourth State” of the Matter The matter in “ordinary” conditions presents itself in three fundamental states of aggregation: solid, liquid.

Solar Wind and Coronal Mass Ejections

By Elisha. » The Sun » The sun is the star in the centre of the solar system in which the earth orbits around and is about 149,600,000 km away from earth.

Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display 1 Announcements: Homework #6 due Tuesday Last problem requires.

Faraday Rotation: Unique Measurements of Magnetic Fields in the Outer Corona Justin C. Kasper (UM), Ofer Cohen (SAO), Steven Spangler (Iowa), Gaetan Le.

1 Nature of Light Wave Properties Light is a self- propagating electro- magnetic wave –A time-varying electric field makes a magnetic field –A time-varying.

Space Science MO&DA Programs - September Page 1 SS It is known that the aurora is created by intense electron beams which impact the upper atmosphere.

Simultaneous VLA and UVCS/SOHO Observations of the Solar Corona Steven R. Spangler (University of Iowa), Mari Paz Miralles, Steven R. Cranmer, and John.

Partially Ionized Plasma Effect in Dynamic Solar Atmosphere Naoki Nakamura 2015/07/05 Solar Seminar.

The ionosphere of Mars never looked like this before Paul Withers Boston University Space Physics Group meeting, University of Michigan.

Radio Waves Interaction With Interstellar Matter

PHYS 1621 Proton-proton cycle 3 steps. PHYS 1622 Layers of the Sun Mostly Hydrogen with about 25% Helium. Small amounts of heavier elements Gas described.

The Sun Youra Taroyan. Age 4.5 ×10 9 years Mean diameter 1.392×10 6 km, 109 × Earth Mass ×10 30 kg, 333,000 × Earth Volume 1.412×10 18 km 3, 1,300,000.

-1- Coronal Faraday Rotation of Occulted Radio Signals M. K. Bird Argelander-Institut für Astronomie, Universität Bonn International Colloquium on Scattering.

Topics in Space Weather Earth Atmosphere & Ionosphere

Strength and Structure of the Coronal Magnetic Field Steven R. Spangler University of Iowa.

Radio Sounding of the Near-Sun Plasma Using Polarized Pulsar Pulses I.V.Chashei, T.V.Smirnova, V.I.Shishov Pushchino Radio Astronomy Obsertvatory, Astrospace.

Measuring the Magnetic Field in the Solar Corona Steven R. Spangler… University of Iowa.

Stuart D. BaleFIELDS SOC CDR – Science Requirements Solar Probe Plus FIELDS SOC CDR Science and Instrument Overview Science Requirements Stuart D. Bale.

Universe Tenth Edition Chapter 16 Our Star, the Sun Roger Freedman Robert Geller William Kaufmann III.

Probing Coronal Mass Ejections with Faraday Rotation Measurements Steven R. Spangler and Catherine A. Whiting University of Iowa.

Introduction to Space Weather Jie Zhang CSI 662 / PHYS 660 Spring, 2012 Copyright © The Sun: Magnetic Structure Feb. 16, 2012.

Probing the Solar Corona with Radioastronomical Observations Steven R. Spangler.

The Sun. The Sun.  Is located in the outer bands of our Galaxy  Is the center of our Solar System  Is a STAR!!!  Rotation: once in about 25 days 

A Global Hybrid Simulation Study of the Solar Wind Interaction with the Moon David Schriver ESS 265 – June 2, 2005.

Proton-proton cycle 3 steps

Faraday Rotation as a Diagnostic of Cosmic Magnetic Fields

Interstellar Turbulence and the Plasma Environment of the Heliosphere

Solar and heliosheric WG

Jason E. Kooi1,2 and Steven R. Spangler2

CH29: The Sun Mrs. Kummer, 2016.

2005 Joint SPD/AGU Assembly, SP33A–02

Radio Remote Sensing of the Solar Corona

NASA Nasa's Parker Solar Probe mission set off to explore the Sun's atmosphere in the summer of The probe will swoop to within 4 million miles of.

How does the solar atmosphere connect to the inner heliosphere?

Earth’s Ionosphere Lecture 13

Exploring the ionosphere of Mars

The sun gives off tremendous amounts of energy

The Layered Atmosphere:

Radar Soundings of the Ionosphere of Mars

Presentation transcript:

Plasmas in Space: From the Surface of the Sun to the Orbit of the Earth Steven R. Spangler, University of Iowa Division of Plasma Physics, American Physical Society

To gain a perspective on gaseous media in space, first consider a more familiar gaseous medium….the Earth’s atmosphere Physical conditions: T=290K, Ionization state: neutral (molecular collisions not energetic enough to ionize)

Forces that act on gas in neutral atmosphere Gravity Pressure gradients Coriolis forces These forces lead to interesting fluid motions on scales from continental (frontal systems) to pocket-sized. These includes waves and turbulence, convective motions, etc.

How high does the atmosphere extend? Hydrostatic equilibrium

Now let’s look at the interplanetary perspective 1 astronomical unit

The Sun mass radius density

What are the conditions in the solar atmosphere? Compare solar spectrum with Planck function

What are the conditions in the solar atmosphere?

Physical conditions in the solar atmosphere: the remarkable achievements of spectroscopy pressure number density temperature Temperature still too low to ionize hydrogen Atmospheric scale height 174 km

The fascinating nature of the solar corona Extends much higher than 174 km

A clue to the nature of the corona: the red and green emission lines

Formation temperatures of FeX and FeXIV T~ 800,000K The corona is heated, and at these temperatures, becomes ionized

The outer atmosphere of the Sun (the corona) is heated to temperatures of 1-2 million K, and is nearly fully ionized (a plasma)

A gas heated to high temperatures and at high altitude should begin to flow outwards…the solar wind

Spacecraft in interplanetary space (e.g. ACE) can directly measure the solar wind

Plasmas are interesting media

Some basic properties of plasmas Plasma frequency Cyclotron frequency DeBye length

What are the plasma properties of the solar corona at r = 10 solar radii? Electron density Plasma frequency Magnetic field strength Proton gyrofrequency Temperature DeBye length

Faraday Rotation as a Probe of the Coronal Magnetic Field

Faraday Rotation in the corona Rotation measure

Trans-coronal sources for Faraday rotation measurements Spacecraft transmitters (M. Bird, E. Jensen) Pulsars (provide both RM and DM) Extragalactic radio sources (numerous, provide “constellations” and possibility of multiple lines of sight)

Constellation of radio galaxies around the Sun Constellation of radio sourcesLASCO coronagraph image during observing session Ingleby et al, ApJ 668, 520, 2007

Fig. 3.— Illustration of data used to obtain the coronal Faraday rotation for one of the lines of sight, that to 2325−049 on March 12. In all three panels, the orientation and length of the plotted lines correspond to the polarization position angle and the polarized intensity, respectively, at that position in the source. The contours are of total intensity (Stokes parameter I). (a) The 1465 MHz polarization position angle map on March 12, when the line of sight passed through the corona. (b) Similar map of the source on May 29, when the corona was far from the source. (c) Position angle difference between the two maps, Δχ, which is the Faraday rotation due to the corona. For both components of the source, the Faraday rotation is 14°, corresponding to an RM of 6 rad m−2. The resolution of all three maps is about 5$\arcsec$ (angular diameter FWHM of the restoring beam). From The Astrophysical Journal 668(1):520–532. © 2007 by The American Astronomical Society. For permission to reuse, contact

Fig. 3.— Illustration of data used to obtain the coronal Faraday rotation for one of the lines of sight, that to 2325−049 on March 12. In all three panels, the orientation and length of the plotted lines correspond to the polarization position angle and the polarized intensity, respectively, at that position in the source. The contours are of total intensity (Stokes parameter I). (a) The 1465 MHz polarization position angle map on March 12, when the line of sight passed through the corona. (b) Similar map of the source on May 29, when the corona was far from the source. (c) Position angle difference between the two maps, Δχ, which is the Faraday rotation due to the corona. For both components of the source, the Faraday rotation is 14°, corresponding to an RM of 6 rad m−2. The resolution of all three maps is about 5$\arcsec$ (angular diameter FWHM of the restoring beam). From The Astrophysical Journal 668(1):520–532. © 2007 by The American Astronomical Society. For permission to reuse, contact

Fig. 3.— Illustration of data used to obtain the coronal Faraday rotation for one of the lines of sight, that to 2325−049 on March 12. In all three panels, the orientation and length of the plotted lines correspond to the polarization position angle and the polarized intensity, respectively, at that position in the source. The contours are of total intensity (Stokes parameter I). (a) The 1465 MHz polarization position angle map on March 12, when the line of sight passed through the corona. (b) Similar map of the source on May 29, when the corona was far from the source. (c) Position angle difference between the two maps, Δχ, which is the Faraday rotation due to the corona. For both components of the source, the Faraday rotation is 14°, corresponding to an RM of 6 rad m−2. The resolution of all three maps is about 5$\arcsec$ (angular diameter FWHM of the restoring beam). From The Astrophysical Journal 668(1):520–532. © 2007 by The American Astronomical Society. For permission to reuse, contact

An illustration of Faraday rotation Position angle rotation (1465 MHz) = 14 degrees Coronal RM = 6 rad/sq-m Ingleby, Spangler, Whiting 2007, ApJ 668, 520

What are the results for the coronal field? Monthly Notices of the Royal Astronomical Society Volume 422, Issue 2, pages , 14 MAR 2012 DOI: /j x Volume 422, Issue 2, You et al 2012

Topics of Interest Large scale coronal magnetic field MHD turbulence in the corona Probing electrical currents Faraday rotation as a probe of CMEs Future extensions of the technique (closer to and further from the Sun)

Main topics in heliospheric plasma physics Nature of plasma turbulence Heating of the solar corona and solar wind Acceleration of charged particles to relativistic energies Energy conversion through magnetic reconnection The basic physics of “Space Weather”

There are many exciting things to study in astrophysical plasma physics and plasma physics in general. Come join us!