C₅H₅⁺ + e^-

Gaz phase reaction (type: Electronic recombination and attachment)

Datasheet T(K) = 10-800

Show/Hide those values

Channels	T(K)	Branching ratio	Formula	Δ_rH (kJ.mol-1)	Date	Channels
C₅H₅⁺ + e^- → H + H₂ + C₅H₂	10-800	0 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → H + H₂ + C₅H₂ T(K): 10-800 Branching ratio: 0 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03
C₅H₅⁺ + e^- → H + CH₃C₄H	10-800	25 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → H + CH₃C₄H T(K): 10-800 Branching ratio: 25 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03
C₅H₅⁺ + e^- → CH + CH₂CHC₂H	10-800	0 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → CH + CH₂CHC₂H T(K): 10-800 Branching ratio: 0 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03
C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH	10-800	50 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH T(K): 10-800 Branching ratio: 50 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03
C₅H₅⁺ + e^- → CCH + CH₃CCH	10-800	0 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → CCH + CH₃CCH T(K): 10-800 Branching ratio: 0 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03
C₅H₅⁺ + e^- → CH₃ + C₄H₂	10-800	25 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-12-03	C₅H₅⁺ + e^- → CH₃ + C₄H₂ T(K): 10-800 Branching ratio: 25 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-12-03

Show details See/hide publications

Channel	T(K)	k( ) cm³s^-1	α	β	γ	F₀	g	Type uncert	Details
C₅H₅⁺ + e^- → H + H₂ + C₅H₂	10-800	0.00e+0	0.00E+0	0.00E+0	0.00E+0	0	0	lognormal	C₅H₅⁺ + e^- → H + H₂ + C₅H₂ T(K) = 10-800 α = 0.00E+0 β = 0.00E+0 γ = 0.00E+0 F ₀ = 0 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989).
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989).
C₅H₅⁺ + e^- → H + CH₃C₄H	10-800	1.39e-6	5.00E-7	-3.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → H + CH₃C₄H T(K) = 10-800 α = 5.00E-7 β = -3.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
C₅H₅⁺ + e^- → CH + CH₂CHC₂H	10-800	0.00e+0	0.00E+0	0.00E+0	0.00E+0	0	0	lognormal	C₅H₅⁺ + e^- → CH + CH₂CHC₂H T(K) = 10-800 α = 0.00E+0 β = 0.00E+0 γ = 0.00E+0 F ₀ = 0 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH	10-800	2.77e-6	1.00E-6	-3.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH T(K) = 10-800 α = 1.00E-6 β = -3.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
C₅H₅⁺ + e^- → CCH + CH₃CCH	10-800	0.00e+0	0.00E+0	0.00E+0	0.00E+0	0	0	lognormal	C₅H₅⁺ + e^- → CCH + CH₃CCH T(K) = 10-800 α = 0.00E+0 β = 0.00E+0 γ = 0.00E+0 F ₀ = 0 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
C₅H₅⁺ + e^- → CH₃ + C₄H₂	10-800	1.39e-6	5.00E-7	-3.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → CH₃ + C₄H₂ T(K) = 10-800 α = 5.00E-7 β = -3.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.
	Method: Reviews and Evaluations Description: The choice in branching ratios are described in the datasheet whereas the total rate coefficient has been taken from Herbst and Leung (1989). Uncertainty has been set to a default value.

Origin	Authors	Volume,Page	Year	Journal / Thesis / Book	DOI	Download citation	Reference
Datasheet
Origin: Datasheet Authors: Volume,Page: Year: DOI: - Download citation:

Other database : OSU T(K) = 10-280

Show/Hide those values

Channels	T(K)	Branching ratio	Formula	Δ_rH (kJ.mol-1)	Date	Channels
C₅H₅⁺ + e^- → H + H₂ + C₅H₂	10-280	50 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2009-03-27	C₅H₅⁺ + e^- → H + H₂ + C₅H₂ T(K): 10-280 Branching ratio: 50 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2009-03-27
C₅H₅⁺ + e^- → H + CH₃C₄H	10-280	50 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2009-03-27	C₅H₅⁺ + e^- → H + CH₃C₄H T(K): 10-280 Branching ratio: 50 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2009-03-27

Show details See/hide publications

Channel	T(K)	k( ) cm³s^-1	α	β	γ	F₀	g	Type uncert	Details
C₅H₅⁺ + e^- → H + H₂ + C₅H₂	10-280	2.77e-6	1.00E-6	-3.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → H + H₂ + C₅H₂ T(K) = 10-280 α = 1.00E-6 β = -3.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Calculations
	Method: Calculations
C₅H₅⁺ + e^- → H + CH₃C₄H	10-280	2.77e-6	1.00E-6	-3.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → H + CH₃C₄H T(K) = 10-280 α = 1.00E-6 β = -3.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Calculations
	Method: Calculations

Origin	Authors	Volume,Page	Year	Journal / Thesis / Book	DOI	Download citation	Reference
Other database : OSU	Herbst, E. et al	69,271-300	1989	Astrophysical Journal Supplement Series	DOI	Bibtex RIS
Origin: Other database : OSU Authors: Herbst, E. et al Volume,Page: 69,271-300 Year: 1989 DOI: DOI Download citation: Bibtex RIS

Other database : OSU T(K) = 10-1000

Show/Hide those values

Channels	T(K)	Branching ratio	Formula	Δ_rH (kJ.mol-1)	Date	Channels
C₅H₅⁺ + e^- → CH + CH₂CHC₂H	10-1000	18 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-03-05	C₅H₅⁺ + e^- → CH + CH₂CHC₂H T(K): 10-1000 Branching ratio: 18 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-03-05
C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH	10-1000	41 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-03-05	C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH T(K): 10-1000 Branching ratio: 41 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-03-05
C₅H₅⁺ + e^- → CCH + CH₃CCH	10-1000	41 %	Modified Arrhenius equation	Δ_rH₀ = N/A Δ _rH₂₉₈ = N/A	2014-03-05	C₅H₅⁺ + e^- → CCH + CH₃CCH T(K): 10-1000 Branching ratio: 41 % Formula: Modified Arrhenius equation Δ _rH₀ = N/A Δ _rH₂₉₈ = N/A 2014-03-05

Show details See/hide publications

Channel	T(K)	k( ) cm³s^-1	α	β	γ	F₀	g	Type uncert	Details
C₅H₅⁺ + e^- → CH + CH₂CHC₂H	10-1000	2.46e-7	4.50E-8	-5.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → CH + CH₂CHC₂H T(K) = 10-1000 α = 4.50E-8 β = -5.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST
	Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST
C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH	10-1000	5.53e-7	1.01E-7	-5.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → C₂H₂ + CH₂CCH T(K) = 10-1000 α = 1.01E-7 β = -5.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST
	Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST
C₅H₅⁺ + e^- → CCH + CH₃CCH	10-1000	5.53e-7	1.01E-7	-5.00E-1	0.00E+0	2	0	lognormal	C₅H₅⁺ + e^- → CCH + CH₃CCH T(K) = 10-1000 α = 1.01E-7 β = -5.00E-1 γ = 0.00E+0 F ₀ = 2 g = 0 Type uncert: lognormal Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST
	Method: Estimation Description: Reactions used in the high temperature network for ISM applications by Harada et al. (2010). Reaction not listed in the NIST

Origin	Authors	Volume,Page	Year	Journal / Thesis / Book	DOI	Download citation	Reference
Other database : OSU	Harada, N. et al	721,1570-1578	2010	Astrophysical Journal	DOI	Bibtex RIS
Origin: Other database : OSU Authors: Harada, N. et al Volume,Page: 721,1570-1578 Year: 2010 DOI: DOI Download citation: Bibtex RIS