Which of these is the vibrational rate equation?

Question

TuteeHUB · Accepted Answer

τ = $\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}$

TuteeHUB · Answer

$\frac {de_{vib}}{dt} = \frac {1}{τ}$(e$_{vib}^{eq}$ – evib)b) τ = $\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}$ c) evib = τ(e$_{vib}^{eq}$ – evib)d) $\frac {de_{vib}}{dt}$ = $\frac {1}{τ}$(e$_{vib}^{eq}$ – evi

TuteeHUB · Answer

τ = $\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}$

TuteeHUB · Answer

evib = τ(e$_{vib}^{eq}$ – evib)

TuteeHUB · Answer

$\frac {de_{vib}}{dt}$ = $\frac {1}{τ}$(e$_{vib}^{eq}$ – evib)

1.	Which of these is the vibrational rate equation?
A.	\(\frac {de_{vib}}{dt} = \frac {1}{τ}\)(e\(_{vib}^{eq}\) – evib)b) τ = \(\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}\) c) evib = τ(e\(_{vib}^{eq}\) – evib)d) \(\frac {de_{vib}}{dt}\) = \(\frac {1}{τ}\)(e\(_{vib}^{eq}\) – evi
B.	τ = \(\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}\)
C.	evib = τ(e\(_{vib}^{eq}\) – evib)
D.	\(\frac {de_{vib}}{dt}\) = \(\frac {1}{τ}\)(e\(_{vib}^{eq}\) – evib)
Answer» B. τ = \(\frac {1}{k_{1, 0} (1 – e^{- hv/kT} )}\)

Which of these is the vibrational rate equation?

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