Which of these is the vibrational rate equation?

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

( frac {de_{vib}}{dt} = frac {1}{ } )(e (_{vib}^{eq} ) evib)

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

( frac {de_{vib}}{dt} ) = ( frac {1}{ } )(e (_{vib}^{eq} ) evib)

What is the master equation for vibrational relaxation?

( frac {dN_i}{dt} ) = ZNi + 1 + ZNi 1 ZNi, i 1 ZNi

( frac {dN_i}{dt} ) = ki + 1, i ZNi + 1 + ki 1, i ZNi 1 ki, i + 1 ZNi ki, i 1 ZNi

( frac {dN_i}{dt} ) = ki + 1, i Ni + 1 + ki 1, i Ni 1 ki, i + 1Ni ki, i 1 Ni

( frac {dN_i}{dt} ) = ZNi + 1 + ZNi 1 ZNi, i 1 ZNi

( frac {dN_i}{dt} ) = Pi + 1, i ZNi + 1 + Pi 1, i ZNi 1

What is the formula to compute net rate change of the population of the ith level?

( frac {dN_i}{dt} ) = Pi + 1, i ZNi + 1 + Pi 1, i ZNi 1 + Pi, i + 1 ZNi + Pi, i 1 ZNi

( frac {dN_i}{dt} ) = Pi + 1, i ZNi + 1 + Pi 1, i ZNi 1 Pi, i + 1 ZNi Pi, i 1 ZNi

( frac {dN_i}{dt} ) = Pi + 1, i ZNi + 1 + Pi 1, i ZNi 1 + Pi, i + 1 ZNi + Pi, i 1 ZNi

( frac {dN_i}{dt} ) = Pi + 1, i ZNi + 1 Pi, i + 1 ZNi

( frac {dN_i}{dt} ) = + Pi 1, i ZNi 1 Pi, i 1 ZNi

What does the product of collision frequency and transition probability yield?

Number of collisions per second

Number of transitions per particle per second

Number of collisions per second

Number of collisions per second per particle

Explore topic-wise MCQs in Aerodynamics.

This section includes 6 Mcqs, each offering curated multiple-choice questions to sharpen your Aerodynamics knowledge and support exam preparation. Choose a topic below to get started.

1.	In case of translation-vibration transfers, there can be an increase or decrease in kinetic energy.
A.	True
B.	False
Answer» B. False

Discussion

2.	Which of these is the vibrational rate equation?
A.	( frac {de_{vib}}{dt} = frac {1}{ } )(e (_{vib}^{eq} ) e<sub>vib</sub>)
B.	= ( frac {1}{k_{1, 0} (1 e^{- hv/kT} )} )
C.	e<sub>vib</sub> = (e (_{vib}^{eq} ) e<sub>vib</sub>)
D.	( frac {de_{vib}}{dt} ) = ( frac {1}{ } )(e (_{vib}^{eq} ) e<sub>vib</sub>)
Answer» B. = ( frac {1}{k_{1, 0} (1 e^{- hv/kT} )} )

Discussion

3.	What is the master equation for vibrational relaxation?
A.	( frac {dN_i}{dt} ) = k<sub>i + 1, i</sub> ZN<sub>i + 1</sub> + k<sub>i 1, i</sub> ZN<sub>i 1</sub> k<sub>i, i + 1</sub> ZN<sub>i</sub> k<sub>i, i 1</sub> ZN<sub>i</sub>
B.	( frac {dN_i}{dt} ) = k<sub>i + 1, i</sub> N<sub>i + 1</sub> + k<sub>i 1, i</sub> N<sub>i 1</sub> k<sub>i, i + 1</sub>N<sub>i</sub> k<sub>i, i 1</sub> N<sub>i</sub>
C.	( frac {dN_i}{dt} ) = ZN<sub>i + 1</sub> + ZN<sub>i 1</sub> ZN<sub>i, i 1</sub> ZN<sub>i</sub>
D.	( frac {dN_i}{dt} ) = P<sub>i + 1, i</sub> ZN<sub>i + 1</sub> + P<sub>i 1, i</sub> ZN<sub>i 1</sub>
Answer» C. ( frac {dN_i}{dt} ) = ZN<sub>i + 1</sub> + ZN<sub>i 1</sub> ZN<sub>i, i 1</sub> ZN<sub>i</sub>

Discussion

4.	What is the formula to compute net rate change of the population of the i^th level?
A.	( frac {dN_i}{dt} ) = P<sub>i + 1, i</sub> ZN<sub>i + 1</sub> + P<sub>i 1, i</sub> ZN<sub>i 1</sub> P<sub>i, i + 1</sub> ZN<sub>i</sub> P<sub>i, i 1</sub> ZN<sub>i</sub>
B.	( frac {dN_i}{dt} ) = P<sub>i + 1, i</sub> ZN<sub>i + 1</sub> + P<sub>i 1, i</sub> ZN<sub>i 1</sub> + P<sub>i, i + 1</sub> ZN<sub>i</sub> + P<sub>i, i 1</sub> ZN<sub>i</sub>
C.	( frac {dN_i}{dt} ) = P<sub>i + 1, i</sub> ZN<sub>i + 1</sub> P<sub>i, i + 1</sub> ZN<sub>i</sub>
D.	( frac {dN_i}{dt} ) = + P<sub>i 1, i</sub> ZN<sub>i 1</sub> P<sub>i, i 1</sub> ZN<sub>i</sub>
Answer» B. ( frac {dN_i}{dt} ) = P<sub>i + 1, i</sub> ZN<sub>i + 1</sub> + P<sub>i 1, i</sub> ZN<sub>i 1</sub> + P<sub>i, i + 1</sub> ZN<sub>i</sub> + P<sub>i, i 1</sub> ZN<sub>i</sub>

Discussion

5.	What does the product of collision frequency and transition probability yield?
A.	Number of transitions per particle per second
B.	Number of collisions per second
C.	Number of collisions per second per particle
D.	Transitions per collision
Answer» B. Number of collisions per second

Discussion

6.	What is the value of transition probability?
A.	0
B.	More than 1
C.	Less than 1
D.	1
Answer» D. 1

Discussion

Explore topic-wise MCQs in Aerodynamics.

In case of translation-vibration transfers, there can be an increase or decrease in kinetic energy.

Which of these is the vibrational rate equation?

What is the master equation for vibrational relaxation?

What is the formula to compute net rate change of the population of the ith level?

What does the product of collision frequency and transition probability yield?

What is the value of transition probability?

What is the formula to compute net rate change of the population of the i^th level?