Molecular Beams in Space:  Sources of OH(A→X) Emission in the Space Shuttle Environment

Bernstein, Lawrence S.; Chiu, Yu‐Hui; Gardner, James A.; Broadfoot, A. L.; Lester, Marsha I.; Tsiouris, Maria; Dressler, Rainer A.; Murad, Edmond

doi:10.1021/jp035143x

Cited by 17 publications

(16 citation statements)

References 54 publications

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“…which has been observed in space-based 11 and laboratory molecular beam measurements. 10 The electronically excited OH is apparently formed through high-lying conical intersections in the potential energy surfaces of the four-atom complex.…”

Section: π)mentioning

confidence: 56%

“…Collisions of O( 3 P) with H 2 O(X, 1 A 1 ) give rise to spectral radiation observed from the long wave infrared (~20-10 µ) [1][2][3] , through the infrared (10-1 µ) [1][2][3][4][5][6][7][8][9] and up to the vacuum ultraviolet (~0.25 µ), [10][11][12] depending on the relative collision energy. These emissions are important to characterize because they can be a significant background noise source for telescopes mounted on spacecraft in low-Earth-orbit or LEO.…”

Section: Introductionmentioning

confidence: 99%

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Potential Surfaces and Dynamics of the O(3P) + H2O(X1A1) yields OH(X2Pi) + OH(X2Pi) Reaction

Braunstein¹,

Panfili²,

Shroll³

et al. 2004

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We present global potential energy surfaces for the three lowest triplet states in O( 3 P Π) reaction using these surfaces. The surfaces are spline-based fits of ~20,000 fixed geometry ab-initio calculations at the CASSCF+MP2 level with a O(4s3p2d1f)/H(3s2p) one electron basis set. Computed rate constants compare well to measurements in the 1,000-2,500 K range using these surfaces. We also compute the total, rovibrationally resolved, and differential angular cross sections at fixed collision velocities from near threshold at ~4 km s -1 (16.9 kcal mol -1 collision energy) to 11 km s -1 (122.5 kcal mol -1 collision energy), and we compare these computed cross sections to available space-based and laboratory data. A major finding of the present work is that above ~40 kcal mol -1 collision energy ro-vibrationally excited OH(X 2 Π) products are a significant and perhaps dominant contributor to the observed 1-5 µ spectral emission from O( 3 P) + H 2 O(X 1 A 1 ) collisions. Another important result is that OH(X 2 Π) products are formed in two distinct ro-vibrational distributions.)The 'active' OH products are formed with the reagent O-atom, and their ro-vibrational distributions are extremely hot. The remaining 'spectator' OH is relatively ro-vibrationally cold.For the active OH, rotational energy is dominant at all collision velocities, but the opposite holds for the spectator OH. Summed over both OH products, below ~50 kcal mol -1 collision energy, vibration dominates the OH internal energy, and above ~50 kcal mol -1 rotation is greater than vibrational energy. As the collision energy increases, energy is diverted from vibration to mostly translational energy. We note that the present fitted surfaces can also be used to investigate direct We present global potential energy surfaces for the three lowest triplet states in O(3P) + H2O(X1A1) collisions and present results of classical dynamics calculations on the O(3P) + H2O(X1A1) OH(X2) + OH(X2) reaction using these surfaces. The surfaces are spline-based fits of 20,000 fixed geometry ab-initio calculations at the CASSCF+MP2 level with a O(4s3p2d1f)/H(3s2p) one electron basis set. Computed rate constants compare well to measurements in the 1,000-2,500 K range using these surfaces. We also compute the total, ro-vibrationally resolved, and differential angular cross sections at fixed collision velocities from near threshold at ~4 km s-1 (16.9 kcal mol-1 collision energy) to 11 km s-1 (122.5 kcal mol-1 collision energy), and we compare these computed cross sections to available space-based and laboratory data. A major finding of the present work is that above ~40 kcal mol-1 collision energy ro-vibrationally excited OH(X2) products are a significant and perhaps dominant contributor to the observed 1-5  spectral emission from O(3P) + H2O(X1A1) collisions. Another important result is that OH(X2) products are formed in two distinct ro-vibrational distributions. The 'active' OH products are formed with the reagent O-ato...

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Section: π)mentioning

confidence: 56%

Section: Introductionmentioning

confidence: 99%

Potential Surfaces and Dynamics of the O(3P) + H2O(X1A1) yields OH(X2Pi) + OH(X2Pi) Reaction

Braunstein¹,

Panfili²,

Shroll³

et al. 2004

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“…The GLO-2 mission on STS-63 that flew in February 1995 obtained spectral data on PRCS engine firings during daytime conditions at similarly low thermospheric densities at an orbital altitude of nearly 400 km [5]. Figure 7 shows spectra recorded during a 3 s PRCS burn and approximately 3 s after the burn.…”

Section: Resultsmentioning

confidence: 99%

“…Figure 7 shows spectra recorded during a 3 s PRCS burn and approximately 3 s after the burn. The spectrograph line of sight was nearly parallel to the thrust centerline, and the spectral acquisition times were 2 s. The spectral features in the bottom spectrum, which is on an expanded vertical scale in comparison with the top spectrum, are due to OH, NO, and NH exhaust species (see [5] for an assignment of the bands). The top spectrum exhibits a broad background with increasing intensity with wavelength.…”

Section: Resultsmentioning

confidence: 99%

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Analysis of Space Shuttle Primary Reaction-Control Engine-Exhaust Transients

Hester¹,

Chiu²,

Winick³

et al. 2009

Journal of Spacecraft and Rockets

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A series of 22 primary reaction-control-system engine attitude-control firings were observed from the Maui Space Surveillance Site during the space shuttle STS-115 mission. The firings occurred during a pass over Maui on 19 September 2006 during which the orbiter was in sunlight and the observatory was in darkness. The observed attitude maneuvers maintained the orbiter in an orientation in which its long axis was aligned with the line of sight from the observatory. This ensured that the thrust vectors of all the observed engine firings were perpendicular to the line of sight, providing an optimal side-on observation of the exhaust. The firings ranged between 80 and 320 ms in duration and involved 2 or 3 engines for pitch, roll, and yaw adjustments. A 0.328 deg field-of-view acquisition scope of the 3.6 m telescope of the Advanced Electro-Optical System provided unfiltered imagery in the near-ultraviolet visible spectral region. The most interesting white-light features were transients, one observed at engine start up and two at shutdown. The analysis of the transient speeds reveals that the startup transient consists of either unburned propellant droplets or higher-pressure gas evaporated from droplets and that the shutdown transients are attributable to a slightly staggered release of unburned oxidizer and fuel, respectively. The first (oxidizer) shutdown transient is the brightest feature, for which an intensity evolution analysis is conducted. The analysis of the groundbased data is fully consistent with spectral features attributable to primary reaction-control-system engine transients observed in previous measurements from the space shuttle bay using an imager spectrograph. Nomenclature A= Brook scaling parameter for density, cm 1 A = Brook scaling parameter for flux, g A 0 = Lorentzian scaling parameter for density, cm 1 deg 2 A 0 = Lorentzian scaling parameter for flux, g deg 2 B= Brook angular distribution parameter, unitless C p = specific heat at constant pressure, J g 1 K 1 D = particle diameter, m D 0 = initial particle diameter, m d = horizontal video-image frame width at range, R, km F = exhaust particle flux, cm 2 s 1 F S = solar spectral flux, W cm 2 g = spectral atmospheric transmission and sensitivity factor, unitless IR e ; x = radiant intensity along image coordinate x perpendicular to the thrust axis at nozzle distance R e , W cm 2 IR e ; y = volume emission rate at nozzle distance R e , where y is the radial distance with respect to the thrust axis, W cm 3 I = angular volume emission-rate distribution, W cm 3 I' = scattered intensity as a function of the solar scattering angle, W sr 1 m = particle mass, g N = number density, particles cm 3 P; T = Planck radiation function, W sr 1 cm 2 Hz 1 P vap = vapor pressure, torr _ Q = heat gain rate, W _ Q Earth = Earthshine heating rate, W _ Q rad = radiative cooling rate, W _ Q sub = heat of sublimation cooling rate, W _ Q sun = solar radiation heating rate, W R = range, km R = range vector, km R e = axial distance to the nozzle exit, m r = particle ...

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A detailed kinetic submechanism for OH∗ chemiluminescence in hydrogen combustion revisited. Part 2

Sharipov,

Loukhovitski,

Pelevkin

et al. 2024

Combustion and Flame

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Molecular Beams in Space: Sources of OH(A→X) Emission in the Space Shuttle Environment

Cited by 17 publications

References 54 publications

Potential Surfaces and Dynamics of the O(3P) + H2O(X1A1) yields OH(X2Pi) + OH(X2Pi) Reaction

Potential Surfaces and Dynamics of the O(3P) + H2O(X1A1) yields OH(X2Pi) + OH(X2Pi) Reaction

Analysis of Space Shuttle Primary Reaction-Control Engine-Exhaust Transients

A detailed kinetic submechanism for OH∗ chemiluminescence in hydrogen combustion revisited. Part 2

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