1 Chromospheric UV oscillations depend on altitude and local magnetic field Noah S. Heller and E.J. Zita, The Evergreen State College, Olympia, WA 98505.

Slides:



Advertisements
Similar presentations
MT4510 Solar Theory Thomas Neukirch
Advertisements

Back Reaction on the Photospheric Magnetic field in Solar Eruptions Dandan Ye.
Solar Theory (MT 4510) Clare E Parnell School of Mathematics and Statistics.
SDO/HMI multi-height velocity measurements Kaori Nagashima (MPS) Collaborators: L. Gizon, A. Birch, B. Löptien, S. Danilovic, R. Cameron (MPS), S. Couvidat.
Astronomy at Evergreen, 2003 an update from Dr. E.J. Zita Wed.8 Jan at SPSCC, 8:00 pm for the Southwest Washington Astronomical.
Spatial and temporal relationships between UV continuum and hard x-ray emissions in solar flares Aaron J. Coyner and David Alexander Rice University June.
High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR) The National Center for Atmospheric Research is operated by the University.
Using a DPS as a Coherent Scatter HF Radar Lindsay Magnus Lee-Anne McKinnell Hermanus Magnetic Observatory Hermanus, South Africa.
High Altitude Observatory (HAO) – National Center for Atmospheric Research (NCAR) The National Center for Atmospheric Research is operated by the University.
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.
Electromagnetic Radiation Electromagnetic radiation - all E-M waves travel at c = 3 x 10 8 m/s. (Slower in water, glass, etc) Speed of light is independent.
Sun-Earth Connections part of a symposium at the Tacoma campus of The Evergreen State College 14.Sept.2001 The Sun and the Earth are both getting hotter.
Solar Convection Simulations Bob Stein David Benson.
Ingolf E. Dammasch ROB/SIDC Brussels, Belgium Solar UV Spectroscopy with SUMER on SOHO (extended version for 11 Oct 2007)
Do magnetic waves heat the solar atmosphere? Dr. E.J. Zita The Evergreen State College Fri.30.May 2003 at Reed College NW Section.
Alfvén Waves in the Solar Corona S. Tomczyk, S. Mclntosh, S. Keil, P. Judge, T. Schad, D. Seeley, J. Edmondson Science, Vol. 317, Sep., 2007.
Chapter 7 The Sun. Solar Prominence – photo by SOHO spacecraft from the Astronomy Picture of the Day site link.
Influence of depth-dependent diffusivity profiles in governing the evolution of weak, large-scale magnetic fields of the sun Night Song and E.J. Zita,
Ringing Magnetic Stars A colloquium at the University College of the Cariboo, Kamloops, BC Many stars - including the sun - have magnetic fields, and many.
Sound Waves from the Northern Lights Photo courtesy of Bjorn Jorgensen, 18 January 2005, near Tromsø, Norway
Can magnetic waves in aurorae transform into acoustic waves? Jada Maxwell & E.J. Zita, The Evergreen State College, Olympia, WA Contact: Jada Maxwell,
Chromospheric UV oscillations depend on altitude and local magnetic field Noah S. Heller and E.J. Zita, The Evergreen State College, Olympia, WA
Magnetic & Acoustic Waves in the Aurora Jada Maxwell Photo: Michael Klensch Courtesy of
Temperature Minimum Region between the Minimum-Activity Epochs and W. Livingston and E. Avrett AGU Fall Meeting, 2003.
Dispersion diagrams of chromospheric MHD waves in a 2D simulation Chris Dove The Evergreen State College Olympia, WA with Tom Bogdan and E.J. Zita.
Why does the temperature of the Sun’s atmosphere increase with height? Evidence strongly suggests that magnetic waves carry energy into the chromosphere.
14 April 2006 Photo: Daryl Pedersen Crow Pass, AK 14 April 2006 Photo: Dave Parkhurst Matanuska-Susitna Valley, AK Can magnetic waves in the auroral region.
Sound Waves from the Northern Lights Photo courtesy of Bjorn Jorgensen, 18 January 2005, near Tromsø, Norway
1 Solar Radiation Physical Modeling (SRPM) J. Fontenla June 30, 2005b.
Radio Emission from Masuda Sources New Jersey Institute of Technology Sung-Hong Park.
Solar Physics at Evergreen Dr. E.J. Zita The Evergreen State College American Physical Society – NW section Spokane-Pullman, 21 May.
Do magnetic waves heat the solar atmosphere? Dr. E.J. Zita The Evergreen State College American Geophysical Union SF, Dec.2003 This.
Our Magnetic Sun and its Effects on Earth Dr. E.J. Zita The Evergreen State College Women in Science Symposium 12 April 2006, TESC.
1 Magnetic waves in sheared field regions E.J. Zita, The Evergreen State College, Olympia, WA Abstract How do magnetohydrodynamic (MHD) waves change.
Dispersion diagrams of chromospheric MHD waves in a 2D simulation Chris Dove The Evergreen State College Olympia, WA with Tom Bogdan and E.J. Zita.
Influence of depth-dependent diffusivity profiles in governing the evolution of weak, large-scale magnetic fields of the Sun Night Song and E.J. Zita,
Conversations with the Earth Tom Burbine
Five minute solar oscillation power within magnetic elements Rekha Jain & Andrew Gascoyne School of Mathematics and Statistics (SoMaS) University of Sheffield.
Seething Horizontal Magnetic Fields in the Quiet Solar Photosphere J. Harvey, D. Branston, C. Henney, C. Keller, SOLIS and GONG Teams.
1 Status of Ring-diagram Analysis of MOTH Data Kiran Jain Collaborators: F. Hill, C. Toner.
Physics of the Weird Solar Minimum: New observations of the Sun Dr. E.J. Zita The Evergreen St. College Olympia WA 98505
An Introduction to Helioseismology (Local) 2008 Solar Physics Summer School June 16-20, Sacramento Peak Observatory, Sunspot, NM.
Acoustic Holographic Studies of Solar Active Region Structure A. Malanushenko 1,2, D. Braun 3, S. Kholikov 2, J. Leibacher 2, C. Lindsey 3 (1) Saint Petersburg.
Solar Weather and Tropical Cyclone Activity Abstract Worldwide tropical cyclone energy and frequency data was obtained from the Unisys Weather database.
Probing Energy Release of Solar Flares M. Prijatelj Carnegie Mellon University Advisors: B. Chen, P. Jibben (SAO)
Interdependence of solar plasma flows and magnetic fields E.J. Zita & C. Smith, The Evergreen State College, Olympia, WA 98505; N.E. Hurlburt, LMSAL, Palo.
Our Star, the Sun Chapter Eighteen. The Sun’s energy is generated by thermonuclear reactions in its core The energy released in a nuclear reaction corresponds.
Solar Atmosphere A review based on paper: E. Avrett, et al. “Modeling the Chromosphere of a Sunspot and the Quiet Sun” and some others [Alexey V. Byalko]
Decay of a simulated bipolar field in the solar surface layers Alexander Vögler Robert H. Cameron Christoph U. Keller Manfred Schüssler Max-Planck-Institute.
Solar Physics at Evergreen Dr. E.J. Zita The Evergreen State College Southwest Washington Astronomical Society 12 Jan. 2005, SPSCC.
SHINE Meeting Kona, HI July 11-15, 2005 Does the Chromosphere Have Heliospheric Impact? Scott W. McIntosh Department of Space.
Using Realistic MHD Simulations for Modeling and Interpretation of Quiet Sun Observations with HMI/SDO I. Kitiashvili 1,2, S. Couvidat 2 1 NASA Ames Research.
Cosmic Ray Intensity Variation and Its Connection with the Total and Spectral Solar Irradiance Gigolashvili Marina, Kapanadze Natela Georgian National.
Atmosphere: Structure and Temperature Bell Ringers:  How does weather differ from climate?  Why do the seasons occur?  What would happen if carbon.
1 MET 112 Global Climate Change MET 112 Global Climate Change - Lecture 3 The Earth’s Energy Balance Dr. Eugene Cordero San Jose State University Outline.
17 Chapter 17 The Atmosphere: Structure and Temperature.
GOAL: To understand the physics of active region decay, and the Quiet Sun network APPROACH: Use physics-based numerical models to simulate the dynamic.
The Study of Light. The Electromagnetic Spectrum  includes gamma rays, X-rays, ultraviolet light, visible light, infrared radiation, microwaves, and.
The Electromagnetic Spectrum Scripps Classroom Connection
CHARACTERISTICS OF TURBULENT PROCESS IN THE SOLAR PHOTOSPHERE
Numerical Simulations of Solar Magneto-Convection
GOAL: To understand the physics of active region decay, and the Quiet Sun network APPROACH: Use physics-based numerical models to simulate the dynamic.
Wave heating of the partially-ionised solar atmosphere
SUN COURSE - SLIDE SHOW 7 Today: waves.
Atmospheres of Cool Stars
The Centre of the Solar System Earth Science 11
Emerging Active Regions: turbulent state in the photosphere
search of Alfvén waves in faculae
Presentation transcript:

1 Chromospheric UV oscillations depend on altitude and local magnetic field Noah S. Heller and E.J. Zita, The Evergreen State College, Olympia, WA Philip Judge, HAO, NCAR, Boulder, CO We analyze continuum timeseries data from the SUMER instrument aboard the SOHO spacecraft. We investigate how intensity oscillations depend on wavelength and on the magnetic environment. Our 30 data sets range in wavelength from nm, which sample heights from Mm above the photosphere. We distinguish between emissions from stronger field “network” regions and weaker field “internetwork” regions. We Fourier transform timeseries and average frequency power spectra over network and internetwork regions. For a frequency range of 2-5 mHz, corresponding to p-mode frequencies, we see a trend of increasing power with increasing wavelength. We discuss the possibility of photospheric p-mode power transfer to chromospheric heating and MHD mode conversion. We find that different frequencies dominate in different magnetic environments.

2 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Introduction: Chromosphere emits UV UV continuum emissions are brighter where gas is hotter, that is at higher altitudes Average height of formation decreases with wavelength UV continua are brighter in strong magnetic regions (network) UV continuum intensity oscillations track photospheric waves traveling up through chromosphere T h

3 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. SUMER measures chromospheric UV emissions Image courtesy of Max-Planck-Institut für Aeronomie The Solar Ultraviolet of Emitted Radiation is a UV spectrograph Parameters include slit size, cadence and wavelength Timeseries data track a region of the chromosphere in time

4 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. UV oscillations vary in space and time Gray scale plots show intensity variations in space and time Variations in space correlate to magnetic field strength we call brightest 30% network and dimmenst 40% internetwork Variations in time give clues to chromospheric dynamics

5 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Strong field regions correlate with bright regions MDI measures line of sight magnetic field strength at 0.2Mm mean UV intensity in network regions tends to be brighter than internetwork intensity Note correspondence of UV bright strip at x=20 in MDI data

6 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Fourier transform  frequency power spectra I f Integrated power For each  we Fourier transform oscillations in time for each position along the slit We average over each network spatial position Characteristic noise is where power levels off We integrated power for each of three frequency ranges: (LF) 0-2 mHz, (MF) 2-5 mHz, (HF) 5-10 mHz, normalized to noise level

7 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. 2-5 mHz oscillation power increases with wavelength Oscillation power decreases with height above photosphere Heating due to gas compression Transformation to MHD waves (“mode conversion”) p-modes are a source of chromospheric UV oscillations Network + Internetwork

8 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Oscillation power depends on local field strength stronger LF oscillations in strong-field (network) regions stronger HF oscillations in weaker-field regions

9 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Magnetic environment can transform waves Parallel acoustic waves can propagate freely to field lines Oblique acoustic waves can excite magnetic waves and lose energy

10 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. SUMMARY: chromospheric UV oscillations reveal: Significance: p-modes heat chromosphere and weaken as they rise Magnetic field strength and topology affects mode propagation and transformation

11 Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Next steps: Compare to MDI data on local magnetic fields: check correspondence between intense UV and strong “network” fields investigate magnetic topology: expect p-modes to propagate freely in regions with weak or vertical fields expect p-modes to transform to MHD waves in regions with strong and oblique fields, as evident in 2D MHD code data (Johnson, Petty-Powell, Zita)

12 Acknowledgements Heller, Zita (TESC) and Judge (HAO), SHINE meeting, Banff CA, 2002 Aug. Thanks to Phil Judge and the staff at the High Altitude Observatory (HAO) at the National Center for Atmospheric Research (NCAR) for hosting our summer visits and teaching us to analyze numerical and satellite data, and to Tom Bogdan for initiating this collaboration between HAO and The Evergreen State College. This work is supported by NASA under the Sun-Earth Connection Guest Investigator Program, NRA 00--OSS--01 SEC

Feedback: Privacy Policy Feedback
Do Not Sell My Personal Information
About project: SlidePlayer Terms of Service

© 2025 SlidePlayer.com. Inc. All rights reserved.