Diazenylium

Last updated
Diazenylium.png

Diazenylium is the chemical N2H+, an inorganic cation that was one of the first ions to be observed in interstellar clouds. Since then, it has been observed for in several different types of interstellar environments, observations that have several different scientific uses. It gives astronomers information about the fractional ionization of gas clouds, the chemistry that happens within those clouds, and it is often used as a tracer for molecules that are not as easily detected (such as N2). [1] Its 1–0 rotational transition occurs at 93.174 GHz, a region of the spectrum where Earth's atmosphere is transparent [2] and it has a significant optical depth in both cold and warm clouds [3] so it is relatively easy to observe with ground-based observatories. The results of N2H+ observations can be used not only for determining the chemistry of interstellar clouds, but also for mapping the density and velocity profiles of these clouds. [4]

Contents

Astronomical detections

N2H+ was first observed in 1974 by B.E. Turner. He observed a previously unidentified triplet at 93.174 GHz using the NRAO 11 m telescope. [5] Immediately after this initial observation, Green et al. identified the triplet as the 1–0 rotational transition of N2H+. This was done using a combination of ab initio molecular calculations and comparison of similar molecules, such as N2, CO, HCN, HNC, and HCO+, which are all isoelectronic to N2H+. Based on these calculations, the observed rotational transition would be expected to have seven hyperfine components, but only three of these were observed, since the telescope's resolution was insufficient to distinguish the peaks caused by the hyperfine splitting of the inner Nitrogen atom. [6] Just a year later, Thaddeus and Turner observed the same transition in the Orion molecular cloud 2 (OMC-2) using the same telescope, but this time they integrated for 26 hours, which resulted in a resolution that was good enough to distinguish the smaller hyperfine components. [7]

Over the past three decades, N2H+ has been observed quite frequently, and the 1–0 rotational band is almost exclusively the one that astronomers look for. In 1995, the hyperfine structure of this septuplet was observed with an absolute precision of ~7 kHz, which was good enough to determine its molecular constants with an order of magnitude better precision than was possible in the laboratory. [8] This observation was done toward L1512 using the 37 m NEROC Haystack Telescope. In the same year, Sage et al. observed the 1–0 transition of N2H+ in seven out of the nine nearby galaxies that they observed with the NRAO 12 m telescope at Kitt Peak. [9] N2H+ was one of the first few molecular ions to be observed in other galaxies, and its observation helped to show that the chemistry in other galaxies is quite similar to that which we see in our own galaxy.

N2H+ is most often observed in dense molecular clouds, where it has proven useful as one of the last molecules to freeze out onto dust grains as the density of the cloud increases toward the center. In 2002, Bergin et al. did a spatial survey of dense cores to see just how far toward the center N2H+ could be observed and found that its abundance drops by at least two orders of magnitude when one moves from the outer edge of the core to the center. This showed that even N2H+ is not an ideal tracer for the chemistry of dense pre-stellar cores, and concluded that H2D+ may be the only good molecular probe of the innermost regions of pre-stellar cores. [10]

Laboratory detections

N2H Energy Levels N2H+ Energy Levels.png
N2H Energy Levels

Although N2H+ is most often observed by astronomers because of its ease of detection, there have been some laboratory experiments that have observed it in a more controlled environment. The first laboratory spectrum of N2H+ was of the 1–0 rotational band in the ground vibrational level, the same microwave transition that astronomers had recently discovered in space. [11]

Ten years later, Owrutsky et al. performed vibrational spectroscopy of N2H+ by observing the plasma created by a discharge of a mixture nitrogen, hydrogen, and argon gas using a color center laser. During the pulsed discharge, the poles were reversed on alternating pulses, so the ions were pulled back and forth through the discharge cell. This caused the absorption features of the ions, but not the neutral molecules, to be shifted back and forth in frequency space, so a lock-in amplifier could be used to observe the spectra of just the ions in the discharge. The lock-in combined with the velocity modulation gave >99.9% discrimination between ions and neutrals. The feed gas was optimized for N2H+ production, and transitions up to J = 41 were observed for both the fundamental N–H stretching band and the bending hot band. [12]

Later, Kabbadj et al. observed even more hot bands associated with the fundamental vibrational band using a difference frequency laser to observe a discharge of a mixture of nitrogen, hydrogen, and helium gases. They used velocity modulation in the same way that Owrutsky et al. had, in order to discriminate ions from neutrals. They combined this with a counterpropogating beam technique to aid in noise subtraction, and this greatly increased their sensitivity. They had enough sensitivity to observe OH+, H2O+, and H3O+ that were formed from the minute O2 and H2O impurities in their helium tank. [13]

Simulated N2H Rotational Spectrum N2H+ Spectrum MHz.png
Simulated N2H Rotational Spectrum

By fitting all observed bands, the rotational constants for N2H+ were determined to be Be = 1.561928 cm−1 and De = 2.746×10−6 cm−1, which are the only constants needed to determine the rotational spectrum of this linear molecule in the ground vibrational state, with the exception of determining hyperfine splitting. Given the selection rule ΔJ = ±1, the calculated rotational energy levels, along with their percent population at 30  kelvins, can be plotted. The frequencies of the peaks predicted by this method differ from those observed in the laboratory by at most 700 kHz.

Chemistry

N2H+ is found mostly in dense molecular clouds, where its presence is closely related to that of many other nitrogen-containing compounds. [14] It is particularly closely tied to the chemistry of N2, which is more difficult to detect (since it lacks a dipole moment). This is why N2H+ is commonly used to indirectly determine the abundance of N2 in molecular clouds.

The rates of the dominant formation and destruction reactions can be determined from known rate constants and fractional abundances (relative to H2) in a typical dense molecular cloud. [15] The calculated rates here were for early time (316,000 years) and a temperature of 20 kelvins, which are typical conditions for a relatively young molecular cloud.

Production of diazenylium
Reaction Rate constant Rate/[H2]2Relative rate
H2 + N+
2 → N2H+ + H		2.0×10−91.7×10−231.0
H+
3 + N2 → N2H+ + H2		1.8×10−91.5×10−229.1
Destruction of diazenylium
Reaction Rate constant Rate/[H2]2Relative rate
N2H+ + O → N2 + OH+1.4×10−101.6×10−231.0
N2H+ + CO → N2 + HCO+1.4×10−105.0×10−233.2
N2H+ + e → N2 + H2.0×10−64.4×10−232.8
N2H+ + e → NHN2.6×10−65.7×10−233.7

There are dozens more reactions possible, but these are the only ones that are fast enough to affect the abundance of N2H+ in dense molecular clouds. Diazenylium thus plays a critical role in the chemistry of many nitrogen-containing molecules. [14] Although the actual electron density in so-called "dense clouds" is quite low, the destruction of N2H+ is governed mostly by dissociative recombination.

Related Research Articles

Diatomic molecule Molecule composed of any two atoms

Diatomic molecules are molecules composed of only two atoms, of the same or different chemical elements. If a diatomic molecule consists of two atoms of the same element, such as hydrogen or oxygen, then it is said to be homonuclear. Otherwise, if a diatomic molecule consists of two different atoms, such as carbon monoxide or nitric oxide, the molecule is said to be heteronuclear. The bond in a homonuclear diatomic molecule is non-polar.

In chemistry, hydronium (hydroxonium in traditional British English) is the common name for the aqueous cation H3O+, the type of oxonium ion produced by protonation of water. It is often viewed as the positive ion present when an Arrhenius acid is dissolved in water, as Arrhenius acid molecules in solution give up a proton (a positive hydrogen ion, H+) to the surrounding water molecules (H2O). In fact, acids must be surrounded by more than a single water molecule in order to ionize, yielding aqueous H+ and conjugate base. Three main structures for the aqueous proton have garnered experimental support: The Eigen cation, which is a tetrahydrate, H3O+(H2O)3; the Zundel cation, which is a symmetric dihydrate, H+(H2O)2; and the Stoyanov cation, an expanded Zundel cation, which is a hexahydrate: H+(H2O)2(H2O)4. Spectroscopic evidence from well-defined IR spectra overwhelmingly supports the Stoyanov cation as the predominant form. For this reason, it has been suggested that wherever possible, the symbol H+(aq) should be used instead of the hydronium ion.

Hyperfine structure Small shifts and splittings in the energy levels of atoms, molecules and ions

In atomic physics, hyperfine structure is defined by small shifts in otherwise degenerate energy levels and the resulting splittings in those energy levels of atoms, molecules, and ions, due to electromagnetic multipole interaction between the nucleus and electron clouds.

Rotational spectroscopy Spectroscopy of quantized rotational states of gases

Rotational spectroscopy is concerned with the measurement of the energies of transitions between quantized rotational states of molecules in the gas phase. The spectra of polar molecules can be measured in absorption or emission by microwave spectroscopy or by far infrared spectroscopy. The rotational spectra of non-polar molecules cannot be observed by those methods, but can be observed and measured by Raman spectroscopy. Rotational spectroscopy is sometimes referred to as pure rotational spectroscopy to distinguish it from rotational-vibrational spectroscopy where changes in rotational energy occur together with changes in vibrational energy, and also from ro-vibronic spectroscopy where rotational, vibrational and electronic energy changes occur simultaneously.

Trihydrogen cation Ion

The trihydrogen cation or protonated molecular hydrogen is a cation with formula H+
3, consisting of three hydrogen nuclei (protons) sharing two electrons.

Ethynyl radical Chemical compound

The ethynyl radical is an organic compound with the chemical formula C≡CH. It is a simple molecule that does not occur naturally on Earth but is abundant in the interstellar medium. It was first observed by electron spin resonance isolated in a solid argon matrix at liquid helium temperatures in 1963 by Cochran and coworkers at the Johns Hopkins Applied Physics Laboratory. It was first observed in the gas phase by Tucker and coworkers in November 1973 toward the Orion Nebula, using the NRAO 11-meter radio telescope. It has since been detected in a large variety of interstellar environments, including dense molecular clouds, bok globules, star forming regions, the shells around carbon-rich evolved stars, and even in other galaxies.

The hexatriynyl radical, C6H, is an organic radical molecule consisting of a chain of six carbon atoms terminated by a hydrogen.

Hydrogen isocyanide is a chemical with the molecular formula HNC. It is a minor tautomer of hydrogen cyanide (HCN). Its importance in the field of astrochemistry is linked to its ubiquity in the interstellar medium.

Propynylidyne is a chemical compound that has been identified in interstellar space.

Protonated hydrogen cyanide Chemical compound

HCNH+, also known as protonated hydrogen cyanide, is a molecular ion of astrophysical interest. It also exists in the condensed state when formed by superacids.

Cyclopropenylidene Chemical compound

Cyclopropenylidene, or c-C3H2, is a partially aromatic molecule belonging to a highly reactive class of organic molecules known as carbenes. On Earth, cyclopropenylidene is only seen in the laboratory due to its reactivity. However, cyclopropenylidene is found in significant concentrations in the interstellar medium (ISM) and on Saturn's moon Titan. Its C2v symmetric isomer, propadienylidene (CCCH2) is also found in the ISM, but with abundances about an order of magnitude lower. A third C2 symmetric isomer, propargylene (HCCCH), has not yet been detected in the ISM, most likely due to its low dipole moment.

Cyano radical Chemical compound

The cyano radical (or cyanido radical) is a radical with molecular formula CN, sometimes written CN. The cyano radical was one of the first detected molecules in the interstellar medium, in 1938. Its detection and analysis was influential in astrochemistry. The discovery was confirmed with a coudé spectrograph, which was made famous and credible due to this detection. ·CN has been observed in both diffuse clouds and dense clouds. Usually, CN is detected in regions with hydrogen cyanide, hydrogen isocyanide, and HCNH+, since it is involved in the creation and destruction of these species (see also Cyanogen).

William Klemperer American chemist

William A. Klemperer (October 6, 1927 – November 5, 2017) was an American chemist who was one of the most influential chemical physicists and molecular spectroscopists in the second half of the 20th century. Klemperer is most widely known for introducing molecular beam methods into chemical physics research, greatly increasing the understanding of nonbonding interactions between atoms and molecules through development of the microwave spectroscopy of van der Waals molecules formed in supersonic expansions, pioneering astrochemistry, including developing the first gas phase chemical models of cold molecular clouds that predicted an abundance of the molecular HCO+ ion that was later confirmed by radio astronomy.

Triatomic hydrogen or H3 is an unstable triatomic molecule containing only hydrogen. Since this molecule contains only three atoms of hydrogen it is the simplest triatomic molecule and it is relatively simple to numerically solve the quantum mechanics description of the particles. Being unstable the molecule breaks up in under a millionth of a second. Its fleeting lifetime makes it rare, but it is quite commonly formed and destroyed in the universe thanks to the commonness of the trihydrogen cation. The infrared spectrum of H3 due to vibration and rotation is very similar to that of the ion, H+
3. In the early universe this ability to emit infrared light allowed the primordial hydrogen and helium gas to cool down so as to form stars.

Cyanopolyynes are a group of chemicals with the chemical formula HC
nN (n = 3,5,7,...). Structurally, they are polyynes with a cyano group covalently bonded to one of the terminal acetylene units. A rarely seen group of molecules both due to the difficulty in production and the unstable nature of the paired groups, the cyanopolyynes have been observed as a major organic component in interstellar clouds. This is believed to be due to the hydrogen scarcity of some of these clouds. Interference with hydrogen is one of the reason for the molecule's instability due to the energetically favorable dissociation back into hydrogen cyanide and acetylene.

Imidogen Inorganic radical with the chemical formula NH

Imidogen is an inorganic compound with the chemical formula NH. Like other simple radicals, it is highly reactive and consequently short-lived except as a dilute gas. Its behavior depends on its spin multiplicity, i.e. the triplet versus singlet ground state.

Magnesium monohydride Chemical compound

Magnesium monohydride is a molecular gas with formula MgH that exists at high temperatures, such as the atmospheres of the Sun and stars. It was originally known as magnesium hydride, although that name is now more commonly used when referring to the similar chemical magnesium dihydride.

Argonium Chemical compound

Argonium (also called the argon hydride cation, the hydridoargon(1+) ion, or protonated argon; chemical formula ArH+) is a cation combining a proton and an argon atom. It can be made in an electric discharge, and was the first noble gas molecular ion to be found in interstellar space.

Phosphorus monoxide Chemical compound

Phosphorus monoxide is an unstable radical inorganic compound with molecular formula PO.

References

  1. "P. Caselli, P.C. Myers, and P. Thaddeus, ApJL, 455: L77 (1995)". Archived from the original on 2014-07-06. Retrieved 2008-10-30.
  2. "CSO Atmospheric Transmission Interactive Plotter". Archived from the original on 2008-09-18. Retrieved 2008-10-30.
  3. L. Pirogov, I. Zinchenko, P. Caselli, L.E.B. Johansson and P. C. Myers, A&A, 405: 639-654 (2003)
  4. Caselli, Paola; Benson, Priscilla J.; Myers, Philip C.; Tafalla, Mario (2002). "Dense Cores in Dark Clouds. XIV. N2H+ (1–0) Maps of Dense Cloud Cores". The Astrophysical Journal . 572 (1): 238–63. arXiv: astro-ph/0202173 . Bibcode:2002ApJ...572..238C. doi:10.1086/340195. ISSN   0004-637X.
  5. B. Turner, ApJ, 193: L83 (1974)
  6. S. Green, J. Montgomery, and P. Thaddeus, ApJ, 193: L89 (1974)
  7. P. Thaddeus and B.E. Turner, ApJ, 201: L25-L26 (1975)
  8. "P. Caselli, P. Myers, and P. Thaddeus, ApJL, 455: L77 (1995)". Archived from the original on 2014-07-06. Retrieved 2008-10-30.
  9. L. Sage and L. Ziurys, ApJ, 447: 625 (1995)
  10. Bergin, Edwin A.; Alves, João; Huard, Tracy; Lada, Charles J. (2002). "N2H+ and C18O Depletion in a Cold Dark Cloud". The Astrophysical Journal Letters . 570 (2): L101–L104. arXiv: astro-ph/0204016 . Bibcode:2002ApJ...570L.101B. doi:10.1086/340950. ISSN   1538-4357.
  11. R. Saykally, T. Dixon, T. Anderson, P. Szanto, and R. Woods, ApJ, 205: L101 (1976)
  12. J. Owrutsky, C. Gudeman, C. Martner, L. Tack, N. Rosenbaum, and R. Saykally, JCP, 84: 605 (1986) [ dead link ]
  13. Kabbadj, Y; Huet, T.R; Rehfuss, B.D; Gabrys, C.M; Oka, T (1994), "Infrared Spectroscopy of Highly Excited Vibrational Levels of Protonated Nitrogen, HN+2", Journal of Molecular Spectroscopy, 163 (1): 180–205, Bibcode:1994JMoSp.163..180K, doi:10.1006/jmsp.1994.1016
  14. 1 2 "S. Prasad and W. Huntress, ApJS, 43: 1-35 (1980)". Archived from the original on 2014-07-06. Retrieved 2008-12-16.
  15. T. Millar, P. Farquhar, and K. Willacy, A\&A Supp, 121: 139 (1997)
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.