Presentation is loading. Please wait.

Presentation is loading. Please wait.

+ Criteria for Candidates Altitude > 40°; Apparent Magnitude > 14; Available Distance and Angular Radius; Available Spectra Criteria for Candidates Altitude.

Published byLoreen Foster Modified over 8 years ago

Similar presentations

Presentation on theme: "+ Criteria for Candidates Altitude > 40°; Apparent Magnitude > 14; Available Distance and Angular Radius; Available Spectra Criteria for Candidates Altitude."— Presentation transcript:

1 + Criteria for Candidates Altitude > 40°; Apparent Magnitude > 14; Available Distance and Angular Radius; Available Spectra Criteria for Candidates Altitude > 40°; Apparent Magnitude > 14; Available Distance and Angular Radius; Available Spectra Introduction Planetary nebulae are crucial in returning heavier metals into the interstellar medium, influencing later star and galaxy formation (Aller & Keyes, 87). Introduction Planetary nebulae are crucial in returning heavier metals into the interstellar medium, influencing later star and galaxy formation (Aller & Keyes, 87). Project Goals -Identify emission lines -Identify ionization potentials -Determine Density, Volume and Mass Project Goals -Identify emission lines -Identify ionization potentials -Determine Density, Volume and Mass Purpose To find a correlation between mass and ionization potentials as well as to see if mass affects elements expelled into interstellar medium Purpose To find a correlation between mass and ionization potentials as well as to see if mass affects elements expelled into interstellar medium Pictures of Candidates and Spectra from Williams (from top) NGC 7662; IC 1747; IC 289; M1-4; M2-2; NGC 7008; NGC 7534 Chart is a template that was used to determine spectral lines. Probable chemical composition for planetary nebula. Knowledge Base Literature Review -C. Szyka, JR Walsh et al determined the highest ionization potential of planetary nebula NGC 6302 by use of spectral analysis. They also calculated temperature. -K. Hermann et al determined the mass of several planetary nebulae and found distance using the luminosity function. -B Webster studied emissions of magellanic clouds as determined approximated distances. Literature Review -C. Szyka, JR Walsh et al determined the highest ionization potential of planetary nebula NGC 6302 by use of spectral analysis. They also calculated temperature. -K. Hermann et al determined the mass of several planetary nebulae and found distance using the luminosity function. -B Webster studied emissions of magellanic clouds as determined approximated distances. Figure 1 Stratification of ions: higher near core, lower farther from star Arnold, Jacob (2008) Figure 1 Stratification of ions: higher near core, lower farther from star Arnold, Jacob (2008)

2 Results Direct Correlation found between mass and highest ionization potential value, p=.994 (graph) Direct Correlation found between mass and highest ionization potential value, p=.994 (graph) Chemical elements identified, generally lighter Chemical elements identified, generally lighter  heaviest overall- Ar Results Direct Correlation found between mass and highest ionization potential value, p=.994 (graph) Direct Correlation found between mass and highest ionization potential value, p=.994 (graph) Chemical elements identified, generally lighter Chemical elements identified, generally lighter  heaviest overall- Ar Discussion Goals: identify elements, calculate ionization potentials/mass, find relationship Goals: identify elements, calculate ionization potentials/mass, find relationship supports findings of Harrington (1969), Szyszka et. al (2009) supports findings of Harrington (1969), Szyszka et. al (2009) Correlation: more massive PN, greater value of highest ionization potential Correlation: more massive PN, greater value of highest ionization potential  More energy required- greater mass Chemicals returned to interstellar medium lighter Chemicals returned to interstellar medium lighter  heaviest element: Argon lightest element: Hydrogen  PNe early stages of life, only ionizing outer shells (seen in Figure 1) Discussion Goals: identify elements, calculate ionization potentials/mass, find relationship Goals: identify elements, calculate ionization potentials/mass, find relationship supports findings of Harrington (1969), Szyszka et. al (2009) supports findings of Harrington (1969), Szyszka et. al (2009) Correlation: more massive PN, greater value of highest ionization potential Correlation: more massive PN, greater value of highest ionization potential  More energy required- greater mass Chemicals returned to interstellar medium lighter Chemicals returned to interstellar medium lighter  heaviest element: Argon lightest element: Hydrogen  PNe early stages of life, only ionizing outer shells (seen in Figure 1) Conclusion Mass and highest ionization potentials have correlation: greater mass related to larger ionization potential values Mass and highest ionization potentials have correlation: greater mass related to larger ionization potential values Chemicals returned to interstellar medium identified Chemicals returned to interstellar medium identified PNe relatively early in life cycles PNe relatively early in life cycles  ionizing lighter ions, have not begun to ionize heavier materials near central star Predict stellar evolution Predict stellar evolution Conclusion Mass and highest ionization potentials have correlation: greater mass related to larger ionization potential values Mass and highest ionization potentials have correlation: greater mass related to larger ionization potential values Chemicals returned to interstellar medium identified Chemicals returned to interstellar medium identified PNe relatively early in life cycles PNe relatively early in life cycles  ionizing lighter ions, have not begun to ionize heavier materials near central star Predict stellar evolution Predict stellar evolution Future Studies Goncalvez et. al (2009)- relation between ionization and temperature Goncalvez et. al (2009)- relation between ionization and temperature Relate ionization potentials to surface temperature and compare to mass Relate ionization potentials to surface temperature and compare to mass Future Studies Goncalvez et. al (2009)- relation between ionization and temperature Goncalvez et. al (2009)- relation between ionization and temperature Relate ionization potentials to surface temperature and compare to mass Relate ionization potentials to surface temperature and compare to mass Limitations Originally planned for self- viewing and astrophotography Originally planned for self- viewing and astrophotography availablility of instruments availablility of instruments Limitations Originally planned for self- viewing and astrophotography Originally planned for self- viewing and astrophotography availablility of instruments availablility of instruments Bibliography Aller & Keyes, et al. “A Spectroscopic Survey of 51 Planetary Nebulae.” 19871. Arnold, Jacob. “Planetary Nebulae. AY 230, Fall 2008. Canright, Shelley. “Stellar Evolution - The Birth, Life, and Death of a Star.” NASA. 10 April 2009. Canright, Shelley. “Stellar Evolution - The Birth, Life, and Death of a Star.” NASA. 10 April 2009. Ciardullo, Robin. “The Planetary Nebula Luminosity Function.” Astrophysical Journal. 14 July 2004. Covington, Michael A. “Processing DSLR Raw Images with MaxDSLR and MaxIm DL.” 25 December 2006. http://www.covingtoninnovations.com/dslr/MaxDSLR/index.html#top Guerrero, Martin A. “Physical Structure of Planetary Nebulae. II. NGC 7662.” The Astronomical Journal, American Astronomical Society. October 2004. The Astronomical Journal, American Astronomical Society. October 2004. Flower, D.R. “The Ionization Structure of Planetary Nebulae-VII:The Heavy Elements.” Royal Astronomical Society, Vol. 146, pg. 171. 24 July 1969. Herrmann, Kimberly A. “Planetary Nebulae in Face-On Spiral Galaxies. II. Planetary Nebula Spectroscopy.” Astrophysical Journal. 4 August 2009. Jacoby, George et al. “A Library of Stellar Spectra.” Astrophysical Journal. October 1984. Kelusa, Craig. “What is Spectroscopy?” University of Arizona. 14 Feb 1997. <http://loke.as.arizona.edu/~ckulesa/camp/spectroscopy_intro.html> Kwitter, Karen B. “Gallery of Planetary Nebulae Spectra.” Williams College. 2006. Lee, Kevin. “Spectral Classification of Stars.” 2005. Lee, Kevin. “Spectral Classification of Stars.” 2005. Lestition, Kathy. “Stellar Evolution.” Chandra X-Ray Observatory. NASA. 24 September 2008. 2008. National Optical Astronomy Observatory. “Spectral Analysis for the RV Tau Star R Sct.”RBSE. 2008. Ransom, R. R. et al. “Probing the Magnetized Interstellar Medium Surrounding the Planetary Nebula SH 2-216.” Astrophysical Journal. 9 June 2008. Santa Barbara Instrument Group. “DSS-7: Deep Space Spectrograph.” 20 March 2006. Santa Barbara Instrument Group. “DSS-7: Deep Space Spectrograph.” 20 March 2006. Szyszka C. et al. “Detection of the Central Star of the Planetary Nebula NGC 6302.” Astrophysical Journal. 21 October 2009. Seeds, Michael A. Foundations of Astronomy. Brooks/Cole. 2005. Sloan Digital Sky Survey. “The Hertzsprung-Russell Diagram.” 2007. / Webster, Louise B. “The Masses and Galactic Distribution of Southern Planetary Nebulae.” Royal Astronomical Society. 11 April 1968. Bibliography Aller & Keyes, et al. “A Spectroscopic Survey of 51 Planetary Nebulae.” 19871. Arnold, Jacob. “Planetary Nebulae. AY 230, Fall 2008. Canright, Shelley. “Stellar Evolution - The Birth, Life, and Death of a Star.” NASA. 10 April 2009. Canright, Shelley. “Stellar Evolution - The Birth, Life, and Death of a Star.” NASA. 10 April 2009. Ciardullo, Robin. “The Planetary Nebula Luminosity Function.” Astrophysical Journal. 14 July 2004. Covington, Michael A. “Processing DSLR Raw Images with MaxDSLR and MaxIm DL.” 25 December 2006. http://www.covingtoninnovations.com/dslr/MaxDSLR/index.html#top Guerrero, Martin A. “Physical Structure of Planetary Nebulae. II. NGC 7662.” The Astronomical Journal, American Astronomical Society. October 2004. The Astronomical Journal, American Astronomical Society. October 2004. Flower, D.R. “The Ionization Structure of Planetary Nebulae-VII:The Heavy Elements.” Royal Astronomical Society, Vol. 146, pg. 171. 24 July 1969. Herrmann, Kimberly A. “Planetary Nebulae in Face-On Spiral Galaxies. II. Planetary Nebula Spectroscopy.” Astrophysical Journal. 4 August 2009. Jacoby, George et al. “A Library of Stellar Spectra.” Astrophysical Journal. October 1984. Kelusa, Craig. “What is Spectroscopy?” University of Arizona. 14 Feb 1997. <http://loke.as.arizona.edu/~ckulesa/camp/spectroscopy_intro.html> Kwitter, Karen B. “Gallery of Planetary Nebulae Spectra.” Williams College. 2006. Lee, Kevin. “Spectral Classification of Stars.” 2005. Lee, Kevin. “Spectral Classification of Stars.” 2005. Lestition, Kathy. “Stellar Evolution.” Chandra X-Ray Observatory. NASA. 24 September 2008. 2008. National Optical Astronomy Observatory. “Spectral Analysis for the RV Tau Star R Sct.”RBSE. 2008. Ransom, R. R. et al. “Probing the Magnetized Interstellar Medium Surrounding the Planetary Nebula SH 2-216.” Astrophysical Journal. 9 June 2008. Santa Barbara Instrument Group. “DSS-7: Deep Space Spectrograph.” 20 March 2006. Santa Barbara Instrument Group. “DSS-7: Deep Space Spectrograph.” 20 March 2006. Szyszka C. et al. “Detection of the Central Star of the Planetary Nebula NGC 6302.” Astrophysical Journal. 21 October 2009. Seeds, Michael A. Foundations of Astronomy. Brooks/Cole. 2005. Sloan Digital Sky Survey. “The Hertzsprung-Russell Diagram.” 2007. / Webster, Louise B. “The Masses and Galactic Distribution of Southern Planetary Nebulae.” Royal Astronomical Society. 11 April 1968.

Download ppt "+ Criteria for Candidates Altitude > 40°; Apparent Magnitude > 14; Available Distance and Angular Radius; Available Spectra Criteria for Candidates Altitude."

Similar presentations

Stellar Evolution: The Deaths of Stars Chapter Twenty-Two.

Stellar Evolution: The Deaths of Stars Chapter Twenty-Two.
Introduction to Astrophysics Lecture 11: The life and death of stars Eta Carinae.

Introduction to Astrophysics Lecture 11: The life and death of stars Eta Carinae.
Introduction to Astrophysics Ronald L. Westra Department Mathematics Maastricht University.

Introduction to Astrophysics Ronald L. Westra Department Mathematics Maastricht University.
Astronomy 1 – Fall 2014 Lecture11; November 13, 2014.

Astronomy 1 – Fall 2014 Lecture11; November 13, 2014.
Review for Quiz 2. Outline of Part 2 Properties of Stars  Distances, luminosities, spectral types, temperatures, sizes  Binary stars, methods of estimating.

Review for Quiz 2. Outline of Part 2 Properties of Stars  Distances, luminosities, spectral types, temperatures, sizes  Binary stars, methods of estimating.
The Nature and Origin of Molecular Knots in Planetary Nebulae Sarah Eyermann – U. of Missouri Angela Speck – U. of Missouri Margaret Meixner – STScI Peter.

The Nature and Origin of Molecular Knots in Planetary Nebulae Sarah Eyermann – U. of Missouri Angela Speck – U. of Missouri Margaret Meixner – STScI Peter.
6. Stars evolve and eventually ‘die’

6. Stars evolve and eventually ‘die’
Stars and the HR Diagram Dr. Matt Penn National Solar Observatory

Stars and the HR Diagram Dr. Matt Penn National Solar Observatory
Astronomy Picture of the Day. Recall: Luminosity - Intrinsic property of a star. Apparent Brightness – the brightness we perceive a star to be from Earth.

Astronomy Picture of the Day. Recall: Luminosity - Intrinsic property of a star. Apparent Brightness – the brightness we perceive a star to be from Earth.
Planetary Nebulae and HII as probes of the evolution of Local Group galaxies A.Y. Kniazev (SAAO), S.A. Pustilnik (SAO), E.K. Grebel (ARI) and many others...

Planetary Nebulae and HII as probes of the evolution of Local Group galaxies A.Y. Kniazev (SAAO), S.A. Pustilnik (SAO), E.K. Grebel (ARI) and many others...
Astronomy 1 – Winter 2011 Lecture 21; February 28 2011.

Astronomy 1 – Winter 2011 Lecture 21; February
Exam 2 Review Astronomy 101 Jeopardy The Interstellar Medium Measurement Techniques The Lives of Stars The Deaths of Stars The H-R Diagram 10 20 30 40.

Exam 2 Review Astronomy 101 Jeopardy The Interstellar Medium Measurement Techniques The Lives of Stars The Deaths of Stars The H-R Diagram
CHARACTERISTICS OF STARS. A star is a ball of gas that gives off a tremendous amount of electromagnetic radiation. The energy comes from a process called.

CHARACTERISTICS OF STARS. A star is a ball of gas that gives off a tremendous amount of electromagnetic radiation. The energy comes from a process called.
Outline  Introduction  The Life Cycles of Stars  The Creation of Elements  A History of the Milky Way  Nucleosynthesis since the Beginning of Time.

Outline  Introduction  The Life Cycles of Stars  The Creation of Elements  A History of the Milky Way  Nucleosynthesis since the Beginning of Time.
Stellar Evolution: from star birth to star death and back again Prof. David Cohen Dept. of Physics and Astronomy.

Stellar Evolution: from star birth to star death and back again Prof. David Cohen Dept. of Physics and Astronomy.
The Universe Chapter 20.

The Universe Chapter 20.
8. Solar System Origins Chemical composition of the galaxy

8. Solar System Origins Chemical composition of the galaxy
Star Stuff. Hot solid, liquid, dense gas: no lines, continuous spectrum Hot object through cooler gas: dark lines in spectrum Cloud of thin gas: bright.

Star Stuff. Hot solid, liquid, dense gas: no lines, continuous spectrum Hot object through cooler gas: dark lines in spectrum Cloud of thin gas: bright.
The Foundations of Astronomy Ashley Peter. Redshift The Universe.

The Foundations of Astronomy Ashley Peter. Redshift The Universe.
Stellar Classification. How we know We learn about stars by looking at them through spectroscopes. All stars produce a spectra that tells us about their.

Stellar Classification. How we know We learn about stars by looking at them through spectroscopes. All stars produce a spectra that tells us about their.

Similar presentations

Ads by Google