Near-IR Spectroscopy of Simple Organic Molecules in GV Tau N Dr. Erika Gibb June 19, 2014.

Slides:

Advertisements

Similar presentations

Probing the Conditions for Planet Formation in Inner Protoplanetary Disks James Muzerolle.

Advertisements

HD An Evolutionary Link Between Protoplanetary Disks and Debris Disks.

School of Chemistry, University of Nottingham,UK 1 Why Does Star Formation Need Surface Science? Using Laboratory Surface Science to Understand the Astronomical.

Astrochemistry Panel Members: Jacqueline Keane Hideko Nomura Ted Bergin Tatsuhiko Hasegawa Karin Öberg Yi-Jehng Kuan.

R. S. RAM and P. F. BERNATH Department of Chemistry, University of York, Heslington, York YO10 5DD, UK. and Department of Chemistry, University of Arizona,

Nuria Marcelino (NRAO-CV) Molecular Line Surveys of Dark Clouds Discovery of CH 3 O.

Estimate of physical parameters of molecular clouds Observables: T MB (or F ν ), ν, Ω S Unknowns: V, T K, N X, M H 2, n H 2 –V velocity field –T K kinetic.

PRESS RELEASE  WHO? Astronomers at UCLA and IPAC using the Keck Observatory. –Team members are Ian McLean (PI), Adam Burgasser, Davy Kirkpatrick (IPAC),

Dust particles and their spectra. Review Ge/Ay 132 Final report Ivan Grudinin.

Abundance and Distribution of the HNCS/HSCN isomer pair

Chemical evolution from cores to disks

Studying circumstellar envelopes with ALMA

The 69 th International Symposium on Molecular Spectroscopy June 19, 2014 Comparative Chemistry of Planetary Nebulae: Jessica L. Edwards Lucy M. Ziurys.

Hot Molecular Gas Orbiting Young Stars: Planet Forming Disks or Small Stellar Companions? A look at data taken at the 200” Mount Palomar Telescope, and.

Stars science questions Origin of the Elements Mass Loss, Enrichment High Mass Stars Binary Stars.

Millimeter Spectroscopy Joanna Brown. Why millimeter wavelengths? >1000 interstellar & circumstellar molecular lines Useful for objects at all different.

Chemistry and line emission of outer protoplanetary disks Inga Kamp Introduction to protoplanetary disks and their modeling Introduction to protoplanetary.

Light and Telescopes Chapter 5. Radio Interferometry The Very Large Array (VLA): 27 dishes are combined to simulate a large dish of 36 km in diameter.

Habitable Planets Astronomy 315 Professor Lee Carkner Special Topic.

Submillimeter Wave Astronomy Satellite and Star Formation Di Li Smithsonian Astrophysical Observatory, CfA July, 2002.

Identification of Volatiles Toward Young Stellar Objects Kari A. Van Brunt University of MO—St. Louis Advisor: Dr. Erika Gibb.

Infrared spectroscopy of Hale-Bopp comet Rassul Karabalin, Ge/Ay 132 Caltech March 17, 2004.

7/2/2015Richter - UC Davis1 EXES, the echelon-cross-echelle spectrograph for SOFIA Matthew J. Richter (UC Davis) with Mark McKelvey (NASA Ames Research.

Near-Infrared Spectroscopy of Interstellar and Planetary Ice Analogs

Space Between the Stars: Properties of the Interstellar Medium Steven R. Spangler University of Iowa.

V410 TAU T TAURI Pre Main Sequence – young, low mass stars that are contracting as they evolve toward their main sequence stage. Mostly made of Hydrogen,

APOGEE: The Apache Point Observatory Galactic Evolution Experiment l M. P. Ruffoni 1, J. C. Pickering 1, E. Den Hartog 2, G. Nave 3, J. Lawler 2, C. Allende-Prieto.

Chemical Models of High Mass Young Stellar Objects Great Barriers in High Mass Star Formation H. Nomura 1 and T.J. Millar 2 1.Kyoto Univ. Japan, 2. Queen’s.

The chemistry and physics of interstellar ices Klaus Pontoppidan Leiden Observatory Kees Dullemond (MPIA, Heidelberg) Helen Fraser (Leiden) Ewine van Dishoeck.

The Chemistry of Comet Hale-Bopp Wendy Hawley Journal Club April 6, 2006.

1 An emerging field: Molecules in Extrasolar Planets Jean Schneider - Paris Observatory ● Concepts and Methods ● First results ● Future perspectives.

What Can Spectroscopy Tell Us?. Atom or Molecular Fingerprints Every atom or molecule exists in its own unique energy state. This energy state is dependent.

Imaging gaps in disks at mid-IR VLT VISIR image 8.6 PAH 11.3 PAH 19.8  m large grains => gap! Geers et al IRS48 -Gap seen in large grains, but NOT.

Molecular Survival in Planetary Nebulae: Seeding the Chemistry of Diffuse Clouds? Jessica L. Dodd Lindsay Zack Nick Woolf Emily Tenenbaum Lucy M. Ziurys.

A Study of HCO + and CS in Planetary Nebulae Jessica L. Edwards Lucy M. Ziurys Nick J. Woolf The University of Arizona Departments of Chemistry and Astronomy.

A-Ran Lyo KASI (Korea Astronomy and Space Science Institute) Nagayoshi Ohashi, Charlie Qi, David J. Wilner, and Yu-Nung Su Transitional disk system of.

ASTR112 The Galaxy Lecture 7 Prof. John Hearnshaw 11. The galactic nucleus and central bulge 11.1 Infrared observations (cont.) 11.2 Radio observations.

October 27, 2006US SKA, CfA1 The Square Kilometer Array and the “Cradle of Life” David Wilner (CfA)

H 3 + Toward and Within the Galactic Center Tom Geballe, Gemini Observatory With thanks to Takeshi Oka, Ben McCall, Miwa Goto, Tomonori Usuda.

Near-Infrared Spectroscopic Study of AA Tau Logan R. Brown Erika L. Gibb Nathan X. Roth University of Missouri – St. Louis.

A NEW INTERSTELLAR MODEL FOR HIGH-TEMPERATURE TIME-DEPENDENT KINETICS Nanase Harada Eric Herbst The Ohio State University June 24, 2006 International Symposium.

Testing grain-surface chemistry in massive hot-core regions and the laboratory (A&A, 465, 913 and A&A submitted) Suzanne Bisschop Jes Jørgensen, Ewine.

The planet-forming zones of disks around solar- mass stars: a CRIRES evolutionary study VLT Large Program 24 nights.

Astrochemistry University of Helsinki, December 2006 Lecture 3 T J Millar, School of Mathematics and Physics Queen’s University Belfast,Belfast BT7 1NN,

64th International Symposium on Molecular Spectroscopy June 22 – 26, 2009 Millimeter Detection of AlO (X 2 Σ + ): Metal Oxide Chemistry in the Envelope.

Héctor G. Arce Yale University Image Credit: ESO/ALMA/H. Arce/ B. Reipurth Shocks and Molecules in Protostellar Outflows.

70 th International Symposium on Molecular Spectroscopy June 2015 First Scientific Observations with the New ALMA Prototype Antenna of the Arizona Radio.

Walsh, Millar & Nomura, ApJL, 766, L23 (2013)

Ringberg1 The gas temperature in T- Tauri disks in a 1+1-D model Bastiaan Jonkheid Frank Faas Gerd-Jan van Zadelhoff Ewine van Dishoeck Leiden.

Sub-Doppler Jet-Cooled Infrared Spectroscopy of ND 2 H 2 + and ND 3 H + in NH Stretch Fundamental Modes Astronomical Molecular Spectroscopy in the Age.

By: Mike Malatesta Introduction to Open Clusters.

The Comet-Disk Connection: Could Comets have Delivered the Ingredients for Life? Dr. Erika Gibb Dept. of Physics & Astronomy April 9, 2016.

NML Cyg The ARO 1 mm Survey of the Oxygen-rich Envelope of Supergiant Star NML Cygnus Jessica L. Edwards, Lucy M. Ziurys, and Nick J. Woolf The University.

Why is water interesting? Evidence of water in space Water in young disks Water in the terrestrial planet-forming zone Future prospects Water in young.

ERIC HERBST DEPARTMENTS OF PHYSICS AND ASTRONOMY THE OHIO STATE UNIVERSITY Chemistry in Protoplanetary Disks.

Complex Organic Molecules formation on Interstellar Grains Qiang Chang Xinjiang Astronomical Observatory Chinese Academy of Sciences April 22, 2014.

By: Mike Malatesta Introduction to Open Clusters.

Spectroscopy from Space

On the Formation of Molecules on Interstellar Grains

SN 1987A: The Formation & Evolution of Dust in a Supernova Explosion

Young planetary systems

Within a Cometary Nucleus

HCO+ in the Helix Nebula

The Interstellar Detection of HSCN in Sgr B2(N)

Molecules: Probes of the Interstellar Medium

A Study of Accretion Disks Around Young Binary Star Systems

Identifying the Key Factors in the Planet Formation Process

Planet Formation around Binary and Multiple Star Systems

Methanol emission from low mass protostars

The chemistry and stability of the protoplanetary disk surface

Presentation transcript:

Near-IR Spectroscopy of Simple Organic Molecules in GV Tau N Dr. Erika Gibb June 19, 2014

Motivation Understanding how volatiles evolve from dark clouds to disks around young stars to protoplanets –Where/how are volatiles processed? –How are volatiles distributed through disks? –Where did Earth’s water, organics come from? Method –Infrared spectroscopy of clouds, disks and comets –Comparison with chemical models

Keck Observatory 10 meter telescope NIRSPEC: Near-Infrared Spectrometer High resolving power ( /  ~ 25,000) 2-5  m region Simple organic molecules have ro-vibrational transitions

Anatomy of a Disk

Surface layer  emission lines Follow the Volatiles: Disks Spectral features can be used to determine temperature, then combine with disk model to estimate location → non unique solutions

Intermediate layer  rich ion-molecule chemistry, absorption Lahuis et al Follow the Volatiles: Disks

Follow the Volatiles: Disks/Comets? Midplane  cold, volatiles frozen onto grains

GV Tau Low mass binary system Close to edge on Surrounded by circumbinary material Warm HCN & C 2 H 2 absorption toward GV Tau N – Located in warm molecular layer of circumstellar disk (Gibb et al. 2007; Doppman et al. 2008)

GV Tau Recently reported CH 4 … first detection in a disk (Gibb & Horne 2013) Note: Molecules like C 2 H 2 & CH 4 have no pure rotational transitions and cannot be done with ALMA.

GV Tau

CH 4 Toward GV Tau CH 4 in GV Tau N disk –T rot ~750 K

CH 4 Toward GV Tau CH 4 in GV Tau N disk –T rot ~750 K

Where is the gas located? Walsh et al. 2010

Results T rot ~ 750 K Abundances? –If assume gas is co-spatial –HCN/CH 4 ~ 50% –(similar to ratio found in comets) Spectral features are variable –Indicating structure/clumpiness in inner disk?

Mystery left to solve: Why are the 2006 and 2010 spectra so different?

Acknowledgements Students –Logan Brown, Nathan Roth Disks –David Horne (Washington College) Funding –NASA Exobiology, NSF Stellar Astronomy

Disk Processing Surface of disk processed by UV, X-ray, cosmic ray Inner region: ion-molecule chemistry, photochemistry Outer region: grain-surface, ion-molecule, neutral-neutral reaction Bulk motions: turbulence, migration inward  vertical & radial mixing