Activation barriers for series of exothermic homologous reactions. I. Metal atom reactions with N2O

Futerko, Peter M.; Fontijn, Arthur

doi:10.1063/1.461287

Cited by 65 publications

(70 citation statements)

References 22 publications

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“…This coincides with [27]. In this model, activation barriers are calculated by taking into account the ionization potential and sp promotion energy of the metal, the electron affinity of N 2 O and the bond energy of the metal oxide product.…”

Section: Discussionsupporting

confidence: 65%

Depletion kinetics of low-lying states of tungsten in the presence of NO, N2O, and SO2

Harter

Campbell

McClean

1997

Int. J. Chem. Kinet.

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The gas-phase reactivities of W(a 5 D J , a 7 S 3 ) with N 2 O, SO 2 , and NO in the temperature range of 295 -573 K are reported. Tungsten atoms were produced by the photodissociation of W(CO) 6 . The tungsten atoms were detected by a laser-induced fluorescence technique. The removal rate constants for the 6s 2 5d 4 a 5 D J states were found to be J dependent for all of the reactants. Removal rate constants for the 6s 1 5d 5 a 7 S 3 state were found to be fast compared to the a 5 D J states and often approached the gas kinetic rate constant. The reaction rates for all the states were found to be pressure independent with respect to the total pressure. Results are discussed in terms of the different electronic configurations of the states of tungsten.

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Section: Discussionsupporting

confidence: 65%

Depletion kinetics of low-lying states of tungsten in the presence of NO, N2O, and SO2

Harter

Campbell

McClean

1997

Int. J. Chem. Kinet.

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“…3 Clearly, the resonance interaction model does not accurately predict the barrier for this reaction. It is not surprising that this model does not accurately predict the kinetic behavior of transition metals due to the neglect of both the TM's d electrons and the product metal oxide's electronic structure.…”

Section: Discussionmentioning

confidence: 99%

“…Arguments were presented which predicted significant barriers should also be present for the production of ground state MnO, although no quantitative results were presented. Recently, Fontijn and co-workers have advanced a resonance interaction model [3][4][5][6] to predict Arrhenius parameters and rate constants for metal atoms reacting with N 2 O. In this model, the activation barriers are calculated by taking into account the ionization potential and sp promotion energy of the metal, the electron affinity of N 2 O, and the bond energy of the metal oxide product.…”

Section: Introductionmentioning

confidence: 99%

Kinetic study of the reaction of Mn(a6S5/2) with N2O from 448 to 620 K

Campbell

1996

The Journal of Chemical Physics

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Kinetic oscillations and hysteresis phenomena in the NO+H2 reaction on Rh(111) and Rh(533): Experiments and mathematical modelingSingle pulse shock tube studies on the reactions of hydrogen atoms with unsaturated compounds AIP Conf.The gas phase reactivity of Mn(a 6 S 5/2 ) with N 2 O in the temperature range 448-620 K is reported. Manganese atoms were produced by the photodissociation of 2-methylcyclopentadienyl manganese tricarbonyl and detected by laser-induced fluorescence. The reaction rate of the a 6 S 5/2 state is very slow and temperature dependent. The rate constants are independent of total pressure indicating a bimolecular reaction. The rate constants are described in Arrhenius form by ͑2.05Ϯ0.45͒ϫ10 Ϫ10 exp͑Ϫ44.7Ϯ1.0 kJ/mol/RT͒ cm 3 s Ϫ1 .

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“…70 They used a high-temperature fast flow reactor with photochemical techniques for the measurement of reaction rates in the 300-1,900 K temperature range. Futerko and Fontijn [71][72][73] have reported activation energies for a series of exothermic homologous reactions for Ca and Cr species. Vijh 74,75 examined the relationship of the activation energy to the heat of formation for metal-oxygen reactions for Mn, Co, Ni, and Pb species.…”

Section: Transformation Of Metallic Speciesmentioning

confidence: 99%

Control of Toxic Metal Emissions from Combustors Using Sorbents: A Review

Biswas

1998

Journal of the Air & Waste Management Association

170

123

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This paper constitutes a review of the control of toxic metal emissions using sorbents. The objective of sorbent-injection methods is to effectively capture the metal species (preferably transform it to an environmentally benign form) and to suppress the fraction in the submicrometer mode. The design of an effective sorbent-injection methodology thus requires an understanding of the fate of the metallic species and its transformation pathways (transfer to the gas phase, subsequent chemistry at high temperatures, and aerosol formation and growth dynamics) in the combustor. Several different sorbent methodologies used for metals capture are discussed, and a mechanistic description is provided. The need for further experimentation and pilot scale testing is also emphasized.

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Activation barriers for series of exothermic homologous reactions. I. Metal atom reactions with N2O

Cited by 65 publications

References 22 publications

Depletion kinetics of low-lying states of tungsten in the presence of NO, N2O, and SO2

Depletion kinetics of low-lying states of tungsten in the presence of NO, N2O, and SO2

Kinetic study of the reaction of Mn(a6S5/2) with N2O from 448 to 620 K

Control of Toxic Metal Emissions from Combustors Using Sorbents: A Review

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