Interstellar dust is responsible, through surface reactions, for the creation of molecular hydrogen, the main component of the interstellar clouds in which new stars form. Intermediate between small, gas-phase molecules and dust are the polycyclic aromatic hydrocarbons (PAHs). Such molecules could account for 2-30% of the carbon in the Galaxy, and may provide nucleation sites for the formation of carbonaceous dust. Although PAHs have been proposed as the sources of the unidentified infrared emission bands that are observed in the spectra of a variety of interstellar sources, the emission characteristics of such molecules are still poorly understood. Here we report laboratory emission spectra of several representative PAHs, obtained in conditions approximating those of the interstellar medium, and measured over the entire spectral region spanned by the unidentified infrared bands. We find that neutral PAHs of small and moderate size can at best make only a minor contribution to these emission bands. Cations of these molecules, as well as much larger PAHs and their cations, remain viable candidates for the sources of these bands.
Single-photon infrared emission spectroscopy (SPIRES) has been used to measure emission spectra from polycyclic aromatic hydrocarbons (PAHs). A supersonic free-jet expansion has been used to provide emission spectra of rotationally cold and vibrationally excited naphthalene and benzene. Under these conditions, the observed width of the 3.3-micrometers (C-H stretch) band resembles the bandwidths observed in experiments in which emission is observed from naphthalene with higher rotational energy. To obtain complete coverage of IR wavelengths relevant to the unidentified infrared bands (UIRs), UV laser-induced desorption was used to generate gas-phase highly excited PAHs. Lorentzian band shapes were convoluted with the monochromator-slit function in order to determine the widths of PAH emission bands under astrophysically relevant conditions. Bandwidths were also extracted from bands consisting of multiple normal modes blended together. These parameters are grouped according to the functional groups mostly involved in the vibration, and mean bandwidths are obtained. These bandwidths are larger than the widths of the corresponding UIR bands. However, when the comparison is limited to the largest PAHs studied, the bandwidths are slightly smaller than the corresponding UIR bands. These parameters can be used to model emission spectra from PAH cations and cations of larger PAHs, which are better candidate carriers of the UIRs.
This report describes studies of photoionization and subsequent dissociation of all saturated paraffins from C2 to C6, plus n-heptane and n-octane, as a function of photon energy. The studies include data on all processes which occur below a photon energy of 11.9 ev. The instrument used was a mass spectrometer, combined with a Seya-Namioka monochromator. The direct experimental data are presented as parent, fragment, and metastable ionization efficiency curves. For each molecule the family of curves obtained by dividing the derivatives of each normalized ionization efficiency curve by the derivative of the total ionization are presented. These derived curves facilitate the test of theories of dissociation kinetics. From a study of the total ionization curves, it is concluded that the adiabatic ionization transition is not accessible within the Franck-Condon region and that it is therefore not possible to determine the ionization potentials of these molecules by ordinary impact experiments. The influence of stored thermal energy was studied by determining the ionization efficiency curves (except for metastables) at two temperatures, 300° and 415°K, and comparing the shifts in the curves with the differences in average stored energy. An analysis of transit times in the mass spectrometer was made which (in addition to providing information necessary to the understanding of the curve shapes and metastable intensities) suggests the existence of ``missing metastables,'' i.e., ions which dissociate in the regions of acceleration (fast metastables) or deflection (slow metastables) and hence are spread out in the mass spectrum so that they do not contribute appreciably to a mass peak. The experimental results confirm the existence of these missing metastables, although the intensity attributed to them is statistically rather uncertain. Changing the ion drawing-out potential in the ionization chamber permitted variation of the extraction time by a factor of 3.3 and the effect of this variation upon several fragment ionization efficiency curves was determined. The experimental results have been compared with the predictions of the statistical theory of dissociation kinetics, a theory which has been widely used in the interpretation of mass spectra. This theory in simplified form involves three parameters, the threshold energy for dissociation E0, a frequency ν, and the number of oscillators n. The results of the comparison may be summarized as follows. (1) The effects of temperature cannot be reconciled with the theory unless n is made a free parameter which takes on a variety of values less than or equal to the total number of oscillators. (2) The statistical theory requires, as an energy randomization mechanism, the presence of many closely spaced electronic states. The experimental evidence is that these states do not exist. (3) The statistical theory predicts the energy excess needed to give a rate constant such that dissociation will occur within the ionization chamber. Comparison with experimental results shows that this excess energy, calculated with reasonable values for E0 and ν and with n equal to the total number of oscillators, is much too large. Reducing n removes the difficulty. (4) The shapes of the fragment and metastable curves, and the metastable intensity, may be calculated from the theory. The tails of the predicted curves are much too large, as is the predicted metastable intensity. Agreement may be obtained by using physically implausible values for E0 and/or ν, or by using reasonable values for E0 and ν, and reduced values of n. The reduced values of n do not agree with those obtained in (1). (5) The shifts in fragment curves resulting from changing the extraction time require either unreasonable values for E0 and/or ν, or a reduced n. The reduced n which is required does not agree with that determined from (1) or (4). (6) The intensity of the missing metastables, though statistically rather uncertain, apparently cannot be reconciled with the statistical theory regardless of what values are taken for E0, ν, and n. (7) In many cases, the dissociation processes leading to different fragments compete (i.e., maintain approximately a constant intensity ratio) over a range of photon energy. Again, one cannot obtain this behavior from the statistical theory with any choice of E0, ν, and n which are consistent with the other data. Individually, these comparisons perhaps are not conclusive, but it is believed that collectively they constitute a definite failure of the statistical theory in its simple form. The lack of a quantitative understanding of the excess energies demanded in the kinetics of dissociation prevents the use of the data for determination of reliable bond dissociation energies. Nevertheless, tentative values have been determined, and these are tabulated and discussed.
Determination of three-dimensional orientations of ferroelectric single crystals by an improved rotating orientation x-ray diffraction method Rev. Sci. Instrum. 80, 085106 (2009); 10.1063/1.3204781 X-ray diffraction imaging of strain fields in a domain-inverted LiTaO 3 crystal J. Appl. Phys.
Extended x-ray absorption fine structure measurements performed at In-K edge have resolved the outstanding issue of bond-length strain in semiconductor-alloy heterostructures. We determine the In-As bond length to be 2.581 6 0.004 Å in a buried, 213 Å thick Ga 0.78 In 0.22 As layer grown coherently on GaAs(001). This bond length corresponds to a strain-induced contraction of 0.015 6 0.004 Å relative to the In-As bond length in bulk Ga 12x In x As of the same composition; it is consistent with a simple model which assumes a uniform bond-length distortion in the epilayer despite the inequivalent In-As and Ga-As bond lengths. [S0031-9007(97)04857-6]
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
customersupport@researchsolutions.com
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
This site is protected by reCAPTCHA and the Google Privacy Policy and Terms of Service apply.
Copyright © 2025 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
