Astronomical spectroscopyLecture 1: Hydrogen and the Early Universe

Jonathan TennysonDepartment of Physics and Astronomy Helsinki

University College London December 2006

Astronomical Spectroscopy

Lecture 1: Hydrogen and the Early Universe

Lecture 2: Molecules in harsh environments

Lecture 3: The molecular opacity problem

Layers in a star: the Sun

Spectrum of a hot star: black body-like

Infra red spectrum of an M-dwarf star

Cool stellar atmospheres: dominated by molecular absorption

BrownDwarf

M-dwarf

The molecular opacity problem

(m)

Cool stars: T = 2000 – 4000 KThermodynamics equilibrium, 3-body chemistryC and O combine rapidly to form CO.

M-Dwarfs: Oxygen rich, n(O) > n(C)H2, H2O, TiO, ZrO, etc also grains at lower T

C-stars: Carbon rich, n(C) > n(O) H2, CH4, HCN, C3, HCCH, CS, etc

S-Dwarfs: n(O) = n(C) Rare. H2, FeH, MgH, no polyatomics

Also (primordeal) ‘metal-free’ starsH, H2, He, H, H3

+ only at low T

Also sub-stellar objects:CO less important

Brown Dwarfs: T ~ 1500 KH2, H2O, CH4

T-Dwarfs: T ~ 1000K‘methane stars’

How common are these?Deuterium burning test using HDO?

Burn D only

No nuclear synthesis

Modeling the spectra of cool stars

• Spectra very dense – cannot get T from black-body fit.• Synthetic spectra require huge databases > 106 vibration-rotation transitions per triatomic molecule• Sophisticated opacity sampling techniques.• Partition functions also important

Data distributed by R L Kururz (Harvard), seekurucz.harvard.edu

Physics of molecular opacities:Closed Shell diatomics

CO, H2, CS, etc

Vibration-rotation transitions.

Sparse: ~10,000 transitions

Generally well characterized by lab data and/or theory

(H2 transitions quadrupole only)

HeH+

Physics of molecular opacities:Open Shell diatomics

TiO, ZrO, FeH, etc

Low-lying excited states.

Electronic-vibration-rotation transitions

Dense: ~10,000,000 transitions (?)

TiO now well understood using mixture of

lab data and theory

Physics of molecular opacities:Polyatomic molecules

H2O, HCN, H3+, C3, CH4, HCCH, NH3, etc

Vibration-rotation transitions

Very dense: 10,000,000 – 100,000,000

Impossible to characterize in the lab

Detailed theoretical calculations

Computed opacities exist for: H2O, HCN, H3+

Ab initio calculationof rotation-vibrationspectra

The DVR3D program suite: triatomic vibration-rotation spectraPotential energy

Surface,V(r1,r2,)

Dipole function (r1,r2,)

J Tennyson, MA Kostin, P Barletta, GJ Harris

OL Polyansky, J Ramanlal & NF Zobov

Computer Phys. Comm. 163, 85 (2004).

www.tampa.phys.ucl.ac.uk/ftp/vr/cpc03

Potentials: Ab initio or Spectroscopically determined

H3+

H2O (HDO)H2S

HCN/HNC HeH+

Molecule considered at high accuracy

Partition functions are important

Model of cool, metal-free magnetic white dwarf WD1247+550 by Pierre Bergeron (Montreal)

Is the partition function of H3+ correct?

Partition functions are important

Model of WD1247+550 using ab initio H3+ partition function

of Neale & Tennyson (1996)

HCN opacity, Greg Harris

High accuracy ab initio potential and dipole surfaces Simultaneous treatment of HCN and HNC Vibrational levels up to 18 000 cm-1

Rotational levels up to J=60 Calculations used SG Origin 2000 machine 200,000,000 lines computed Took 16 months

Partition function estimates suggest 93% recovery of opacity at 3000 K

2006 edition uses observed energy levels

Ab initio vs. laboratory

HNC bend fundamental (462.7 cm-1).

•Q and R branches visible.

•Slight displacement of vibrational band centre (2.5 cm-1).

•Good agreement between rotational spacing.

•Good agreement in Intensity distribution.

Q branches of hot bands visible.Burkholder et al., J. Mol. Spectrosc. 126, 72 (1987)

GJ Harris, YV Pavlenko, HRA Jones & J Tennyson, MNRAS, 344, 1107 (2003).

Importance of water spectra

Other• Models of the Earth’s atmosphere• Major combustion product (remote detection of forest fires,

gas turbine engines)

• Rocket exhaust gases: H2 + ½ O2 H2O (hot) • Lab laser and maser spectra

Astrophysics• Third most abundant molecule in the Universe (after H2 & CO)

• Atmospheres of cool stars• Sunspots• Water masers• Ortho-para interchange timescales

Sunspots Image from SOHO : 29 March 2001

Molecules on the Sun

T=5760KDiatomicsH2, CO, CH, OH,CN, etc

SunspotsT=3200KH2, H2O,CO, SiO

Sunspot

lab

Sunspot: N-band spectrum

L Wallace, P Bernath et al, Science, 268, 1155 (1995)

Assigning a spectrum with 50 lines per cm-1

1. Make ‘trivial’ assignments (ones for which both upper and lower level known experimentally)

2. Unzip spectrum by intensity 6 – 8 % absorption strong lines 4 – 6 % absorption medium 2 – 4 % absorption weak < 2 % absorption grass (but not noise)

3. Variational calculations using ab initio potential Partridge & Schwenke, J. Chem. Phys., 106, 4618 (1997) + adiabatic & non-adiabatic corrections for Born-Oppenheimer approximation

4. Follow branches using ab initio predictions branches are similar transitions defined by

J – Ka = na or J – Kc = nc, n constant

Only strong/medium lines assigned so far

OL Polyansky, NF Zobov, S Viti, J Tennyson, PF Bernath & L Wallace, Science, 277, 346 (1997).

Sunspot

lab

Assignm

entsSunspot: N-band spectrum

L-band, K-band & H-band spectra also assignedZobov et al, Astrophys. J., 489, L205 (1998); 520, 994 (2000); 577, 496 (2002).

Assignments using branches

Ab initio potentialLess accurate but extrapolate well

J

Err

or /

cm-1

Determined potentialSpectroscopically

Variational calculations:

Accurate but extrapolate poorly

Spectroscopically determined water potentials

Reference Year vib/cm-1 Nvib Emax /cm-1

Hoy, Mills & Strey 1972 214 25 13000

Carter & Handy 1987 2.42 25 13000

Halonen & Carrington 1988 5.35 54 18000

Jensen 1989 3.22 55 18000

Polyansky et al (PJT1) 1994 0.6 40 18000

Polyansky et al (PJT2) 1996 0.94 63 25000

Partridge & Schwenke 1997 0.33 42 18000

Shirin et al 2003 0.10 106 25000

mportant to treat vibrations and rotations

Viti & Tennyson computed VT2 linelist:Partridge & Schwenke (PS), NASA AmesNew study by Barber & Tennyson (BT2)

Computed Water opacity• Variational nuclear motion calculations

• High accuracy potential energy surface

• Ab initio dipole surface

• 50,000 processor hours.

• Wavefunctions > 0.8 terabites

• 221,100 energy levels (all to J=50, E = 30,000 cm) 14,889 experimentally known

• 506 million transitions (PS list has 308m) >100,000 experimentally known with intensities

Partition function 99.9915% of Vidler & Tennyson’s value at 3,000K

New BT2 linelistBarber et al, Mon. Not. R. astr. Soc. 368, 1087 (2006).

http://www.tampa.phys.ucl.ac.uk/ftp/astrodata/water/BT2/

Comparison with Experimental Levels

      BT2 AMES  

  Agreement: % %  

  Within 0.10 cm-1 48.7 59.2  

  Within 0.33 cm-1 91.4 85.6  

  Within 1 cm-1 99.2 92.6  

  Within 3 cm-1 99.9 96.5  

  Within 5 cm-1 100.0 97.0  

  Within 10 cm-1 100.0 98.1  

Number of Experimental Levels: 14,889

1 7 1 54 7 0 33 9003.892 7003.799 2000.092 4.01E-03 2.78E-22 3.89E-04 6.71E-01

1 3 0 38 3 1 17 9098.530 7098.116 2000.415 1.56E-03 1.01E-22 1.41E-04 5.59E-01

1 7 0 84 6 0 47 10486.138 8485.481 2000.657 4.69E-02 1.12E-21 1.56E-03 7.84E+00

1 6 0 77 6 1 45 10939.532 8938.685 2000.848 4.83E-03 8.33E-23 1.16E-04 9.34E-01

1 6 1 11 5 1 5 4407.221 2406.299 2000.922 2.77E-02 5.25E-20 7.34E-02 5.35E+00

0 6 0 16 5 0 5 4407.355 2406.297 2001.058 3.26E-02 2.06E-20 2.88E-02 6.30E+00

1 4 1 60 4 0 46 11384.245 9383.183 2001.062 6.66E-03 8.35E-23 1.17E-04 1.86E+00

1 6 0 78 7 0 60 10955.914 8954.726 2001.188 1.69E-02 2.88E-22 4.03E-04 3.27E+00

0 7 1 19 7 0 9 6034.992 4033.695 2001.297 7.29E-04 1.43E-22 2.00E-04 1.22E-01

1 5 1 104 5 0 75 12912.871 10911.526 2001.344 3.36E-02 1.40E-22 1.96E-04 7.68E+00

Raw spectra from DVR3D program suite

A B C D E F G H I J K

43432 11 1 50 8730.136998 0 2 1 11 3 8

43433 11 1 51 8819.773962 0 4 0 11 6 6

43434 11 1 52 8918.536215 0 0 2 11 2 10

43435 11 1 53 8965.496130 0 2 1 11 5 6

43436 11 1 54 8975.145175 2 0 0 11 4 8

43437 11 1 55 9007.868894 1 0 1 11 3 8

43438 11 1 56 9082.413891 1 2 0 11 6 6

43439 11 1 57 9170.343871 1 0 1 11 5 6

43440 11 1 58 9223.444158 0 0 2 11 4 8

43441 11 1 59 9264.489815 2 0 0 11 6 6

43442 11 1 60 9267.088316 0 5 0 11 2 10

43443 11 1 61 9369.887722 0 2 1 11 7 4

43444 11 1 62 9434.002547 0 4 0 11 8 4

43445 11 1 63 9457.272655 1 0 1 11 7 4

43446 11 1 64 9498.012728 0 0 2 11 6 6

43447 11 1 65 9565.890023 1 2 0 11 8 4

Energy file: N J sym n E/cm-1 v1 v2 v3 J Ka Kc

144848 146183 3.46E-04

115309 108520 7.42E-04

196018 198413 1.95E-04

7031 7703 1.13E-02

149176 150123 1.69E-04

81528 78734 2.30E-01

80829 78237 8.83E-04

209672 210876 2.51E-01

207026 203241 2.72E-04

188972 184971 1.25E-01

152471 153399 1.12E-02

39749 37479 1.46E-07

10579 15882 6.90E-05

34458 35617 1.15E-03

Transitions file: Nf Ni Aif

12.8 GbDivided into 16 files by frequencyFor downloading

S.A. Tashkun, HiRus conference (2006)

Astronomical Spectroscopy

Lecture 1: Hydrogen and the Early Universe

Lecture 2: Molecules in harsh environments

Lecture 3: The molecular opacity problem

Merry Christmas

Master file strategy:Inclusion of Experimental (+ other theoretical) data

Added to record. Data classified:

Property of level Energy File• Experimental levels (already included)• Alternative quantum numbers (local modes)

Property of transition Transition File• Measured intensities or A coefficients • Line profile parameters

Line mixing as a third file? Location of partition sums?

Spectrum obtained with the Infrared Space Observatory toward the massive young stellar object AFGL 4176 in a dense molecular cloud. The strong, broad absorption at 4.27m is due to solid CO2, whereas the structure at 4.4-4.9 m indicates the presence of warm, gaseous CO along the line of sight.

van Dishoeck et al. 1996.

Photon dominated region (PDR)

Photon dominated regions (PDRs)

• Photoionisation important• Molecular ions • Hot (T ~ 1000 K) but • Not thermodynamic equilibrium• Electron collisions• Optical pumping

Planetary nebula NGC3132

Cernicharo, Liu et al, Astrophys. J., 483, L65 (1997).

Rotational excitation of molecular ions:Astrophysical importance

Photon dominated regions (PDRs)Electron density, ne ~ 104 n(H2)

Rotational excitation cross sectionelectron > 105 molecule

Radiative lifetime < mean time between collisionsTherefore:

Observed emissions proportional toelectron x column density

Similar arguments hold for vibrational excitation

Rotational excitation of molecular ions:Theoretical models

Standard modelDipole Coulomb-Born approximationOnly considers (long-range) dipole interactionsOnly J = 1 excitations possibleOnly J = 1 emissions should be observed

No experimental data available forelectron impact rotational excitation of molecular ions

Tests of this model performed with R-matrix calculationswhich explicitly include short-range electron-molecular ion interactions

Have considered HeH+, CH+, NO+, CO+, H2

+, HCO+

A. Faure and J. Tennyson, Mon. Not. R. astr. Soc., 325, 443 (2001)

Working on H3+ and H3O+

Find J=2-1 emissions should be observablefor HeH+ and others

Rotational excitation of molecular ions

Summary of resultsJ = 1

c Coulomb-Born model satisfactoryc Short range interactions important

Find c ~ 2 Debye

J = 2Dominated by short range interactions

Always important, can be bigger than J = 1

J > 2Determined by short-range interactions

Usually small, but J = 3 can be significant

For light molecules (H containing diatomics),cross-sections need to energy modified near threshold

http://www.estec.esa.nl/spdwww/iso/pics/iso_h2o.jpg

CometsDirty snowballs which link our solar system with theISM

Comet Hale-Bopp

Molecules identified in comet Hale-Bopp

Simple speciesH2O HDO CO CO2 H2S SO SO2 OCS CS NH3

Molecular ionsH2O+ H3O+ HCO+ CO+

Organic and similarHCN DCN CH3CN HNC HC3N HNCO C2H2 CH3OCHOC2H6 CH4 NH2CHO CH3OH H2CO HCOOH H2CS

RadicalsOH CN NH2 NH C3 C2