Calcium monohydride

Calcium monohydride
Names
IUPAC name
Calcium monohydride
Other names
Calcium(I) hydride
Identifiers
14452-75-6 N
3D model (Jmol) Interactive image
ChemSpider 26667671 N
PubChem 5462806
Properties
CaH
Molar mass 41.085899 g/mol
Appearance glowing red gas
reacts violently
Related compounds
Other cations
Beryllium monohydride,
Magnesium monohydride,
Strontium monohydride,
Barium monohydride,
Potassium hydride
Calcium hydride
Except where otherwise noted, data are given for materials in their standard state (at 25 °C [77 °F], 100 kPa).
Infobox references

Calcium monohydride is a molecule composed of calcium and hydrogen with formula CaH. It can be found in stars as a gas formed when calcium atoms are present with hydrogen atoms.

Discovery

Calcium monohydride was first discovered when its spectrum was observed in Alpha Herculis and ο Ceti by Alfred Fowler in 1907.[1][2] It was observed in sunspots the following year by C. M. Olmsted.[3][4] Next, it was made in a laboratory in 1909 by A. Eagle,[3] and with early research by Hulthèn,[5] and Watson and Weber in 1935.[6] It was further observed in M dwarfs by Y. Öhman in 1934. Öhman proposed its use as a proxy for stellar luminosity, similar to magnesium monohydride (MgH), in being more apparent in the spectra of compact, cool, high surface gravity stars such as M dwarfs than in cool, low surface gravity stars such as M giants of non-negligible, or even comparable, metallicity.[7]

Calcium monohydride is the first molecular gas that was cooled by a cold buffer gas and then trapped by a magnetic field. This extends the study of trapped cold atoms such as rubidium to molecules.[8]

Formation

Calcium monohydride can be formed by exposing metallic calcium to an electric discharge in a hydrogen atmosphere above 750 °C. Below this temperature the hydrogen is absorbed to form calcium hydride.[3]

Calcium monohydride can be formed by laser ablation of calcium dihydride in a helium atmosphere.[9]

Gaseous calcium reacts with formaldehyde at temperatures around 1200 K to make CaH as well as some CaOH and CaO. This reaction glows orange-red.

Properties

The dipole moment of the CaH molecule is 2.94 debye.[10][11] Spectrographic constants have been measured as bond length Re=2.0025 Å dissociation energy De=1.837 eV and harmonic vibrational frequency ωe=1298.34 cm−1.[10] Ionisation potential is 5.8 eV.[10] Electron affinity is 0.9 eV.[10]

The ground state is X2Σ+.[10]

The electronic states are:[12]

Spectrum

B2Σ, with ν'=0 ← X2Σ with ν"=0 634 nm (or is it 690 nm?)[14] CaH fluoresces with 634 nm light giving 690 nm emissions.[9]

B2Σ+ ← X2Σ+ 585.8 nm to 590.2 nm.[15]

A+2Π ← X2Σ+ 686.2 to 697.8 nm[15]

R12 branch[15]

J' J" N" ν nm THz
3/2 1/2 0 14408.94 694.0135 431.9691
5/2 3/2 1 14421.12 693.4274 432.3343
7/2 5/2 2 14432.92 692.8605 432.6881
9/2 7/2 3 14444.54 692.3031 433.0364
11/2 9/2 4 14455.76 691.7658 433.3728
13/2 11/2 5 14467.20 691.2188 433.71574

R2 branch[15]

J' J" N" ν nm THz
3/2 1/2 0 14480.93 690.5633 434.1274
5/2 3/2 1 14495.08 689.8893 434.5516
7/2 5/2 2 14510.09 689.1756 435.0015
9/2 7/2 3 14525.53 688.4430 435.4644
11/2 9/2 4 14541.43 687.6903 435.9411
13/2 11/2 5 14557.98 686.9085 436.4373

C2Σ+ →X2Σ+ transition is in near ultraviolet.[3]

Microwave spectrum

The energy required to spin the CaH molecule from its lowest level to the first quantum level corresponds to a microwave frequency, so there is an absorption around 253 GHz. However, the spin of the molecule is also affected by the spin of an unpaired electron on the calcium, and the spin of the proton in the hydrogen. The electron spin leads to splitting of the line by about 1911.7 MHz, and the spin relative to the proton spin results in hyperfine splitting of the line by about 157.3 MHz.[16]

molecule spin
quantum number
electron spin
quantum number
proton spin
quantum number
frequency
N N' J J' F F' kHz
0 1 1/2 1/2 1 1 252163082
0 1 1/2 1/2 1 0 252216347
0 1 1/2 1/2 0 1 252320467
0 1 1/2 3/2 1 1 254074834
0 1 1/2 3/2 1 2 254176415
0 1 1/2 3/2 0 1 254232179

Reactions

CaH reacts with Lithium as a cold gas releasing 0.9eV of energy and forming LiH molecules and calcium atoms.[17]

See also

References

  1. Barbuy, B.; Schiavon, R. P.; Gregorio-Hetem, J.; Singh, P. D.; Batalha, C. (October 1993). "Intensity of CaH Lines in Cool Dwarfs". Astronomy and Astrophysics Supplement Series. 101 (2): 409. Bibcode:1993A&AS..101..409B.
  2. Fowler, A. (1907). "The fluted spectrum of titanium oxide". Proceedings of the Royal Society A. 79 (533): 509–18. Bibcode:1907RSPSA..79..509F. doi:10.1098/rspa.1907.0059.
  3. 1 2 3 4 Frum, C.I.; H.M. Pickett (1993). "High-Resolution Infrared Fourier Transform Emission Spectroscopy of Metal Hydrides: X2Σ+ state of CaH". Journal of Molecular Spectroscopy. 159 (2): 329–336. Bibcode:1993JMoSp.159..329F. doi:10.1006/jmsp.1993.1130.
  4. Olmsted, Charles M. (1908). "Sun-spot bands which appear in the spectrum of a calcium arc burning in the presence of hydrogen.". Contributions from the Solar Observatory of the Carnegie Institution of Washington. 21: 1–4. Bibcode:1908CMWCI..21....1O.
  5. Hulthèn, E. (1 January 1927). "On The Band Spectrum of Calcium Hydride". Physical Review. 29 (1): 97–111. Bibcode:1927PhRv...29...97H. doi:10.1103/PhysRev.29.97.
  6. Watson, William; Weber, Robert (1 November 1935). "The E Band System of Calcium Hydride". Physical Review. 48 (9): 732–734. Bibcode:1935PhRv...48..732W. doi:10.1103/PhysRev.48.732.
  7. Öhman, Yngve (October 1934). "Spectrographic Studies in the Red". Astrophysical Journal. 80: 171. Bibcode:1934ApJ....80..171O. doi:10.1086/143595.
  8. Friedrich, Bretislav; John M. Doyle (2009). "Why are Cold Molecules so Hot?". ChemPhysChem. 10 (4): 604–623. doi:10.1002/cphc.200800577. PMID 19229896.
  9. 1 2 Doyle, John M.; Jonathan D. Weinstein; Robert deCarvalho; Thierry Guillet; Bretislav Friedrich (1998). "Magnetic trapping of calcium monohydride molecules at millikelvin temperatures". Nature. 395 (6698): 148–150. Bibcode:1998Natur.395..148W. doi:10.1038/25949.
  10. 1 2 3 4 5 Holka, Filip; Miroslav Urban (2006). "The dipole moment and molecular properties of CaH: A theoretical study". Chemical Physics Letters. 426 (4–6): 252–256. Bibcode:2006CPL...426..252H. doi:10.1016/j.cplett.2006.05.108.
  11. Steimle, T. C.; Jinhai Chen; Jamie Gengler (2004-07-08). "The permanent electric dipole moments of calcium monohydride, CaH". The Journal of Chemical Physics. 121 (2): 829–834. Bibcode:2004JChPh.121..829S. doi:10.1063/1.1759314. PMID 15260612.
  12. Ram, R.S.; Tereszchuk, K.; Gordon, I.E.; Walker, K.A.; Bernath, P.F. (2011). "Fourier transform emission spectroscopy of the E2Π–X2Σ+ transition of CaH and CaD". Journal of Molecular Spectroscopy. 266 (2): 86–91. Bibcode:2011JMoSp.266...86R. doi:10.1016/j.jms.2011.03.009.
  13. Gordon, I.; Ram, R. S.; Tereszchuk, K.; Walker, K. A.; Bernath, P. F. (1 April 2011). "Fourier Transform Emission Spectroscopy of the E2Π–X2Σ+ System of CaH and CaD". Retrieved 6 August 2014.
  14. Berg, L-E; L Klynning (1974). "Rotational Analysis of the A-X and B-X Band Systems of CaH". Physica Scripta. 10 (6): 331–336. Bibcode:1974PhyS...10..331B. doi:10.1088/0031-8949/10/6/009.
  15. 1 2 3 4 Pereira, R.; S. Skowronek; A. González Ureña; A. Pardo; J.M.L. Poyato; A.H. Pardo (2002). "Rotationally Resolved REMPI Spectra of CaH in a Molecular Beam". Journal of Molecular Spectroscopy. 212 (1): 17–21. Bibcode:2002JMoSp.212...17P. doi:10.1006/jmsp.2002.8531.
  16. Barclay, W. L., Jr.; Anderson, M. A.; Ziurys, L. M. (1993). "The millimeter-wave spectrum of CaH (X 2Σ+)". Astrophysical Journal Letters. 408 (1): L65–L67. Bibcode:1993ApJ...408L..65B. doi:10.1086/186832.
  17. Singh, Vijay; Kyle S. Hardman; Naima Tariq; Mei-Ju Lu; Aja Ellis; Muir J. Morrison; Jonathan D. Weinstein (2012). "Chemical Reactions of Atomic Lithium and Molecular Calcium Monohydride at 1 K". Physical Review Letters. 108 (20): 203201. Bibcode:2012PhRvL.108t3201S. doi:10.1103/PhysRevLett.108.203201. PMID 23003146.
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