(a) Cp-Cv =R/J (b) Cv-Cp =R/J (c) Cp-Cv =J (d) Cv-Cp =J …
(a) 3/2 (b) 5/2 (c) 5/3 …
(a) Same and 3 cal/mole/°C approximately (b) Exactly equal and its value is 4 cal/mole/°C (c) Will be totally different (d) Approximately equal and its value is 5 cal/mole/°C Answer-d (3)
(a) Cp=(5/2)R (b) Cv=(3/2)R (c) Cp-Cv=2R (d) Cp=(7/2)R Answer-d (10)
R/Cv=0.67 . This gas is made up of molecules which are (a) Diatomic (b) Mixture of diatomic and polyatomic molecules (c) Monoatomic (d) Polyatomic Answer-c (5)
The Cp/Cv is (a) 1.67 (b) 1.4 (c) 1.29 (d) 1.33 Answer-d (8)
Cp/Cv is given by (a) (2/f)+1 (b) 1-(2/f) (c) 1+(1+f) …
(a) 2 (b) 3 (c) 5 (d) 1 Answer-a (4)
(a) 3 (b) 4 (c) 5 (d) 6 Answer-c (6)
(a) Three degrees of freedom (b) Four degrees of freedom (c) Five degrees of freedom (d) Six degrees of freedom Answer-a (10)
SO2 (molecular mass 64) is (a) He (molecular mass 4) (b) O2 (molecular mass 32) (c) H2 (molecular mass 2) (d) CH4 (molecular mass 16) Answer-a (4)
O2 and H2 molecules is placed in a large evacuated chamber. The entire system is maintained at constant temperature T. The ratio of Vrms of O2 molecules to that of the Vrms of H2 molecules, found in the chamber outside the …
(a) 800 K (b) 1600 K (c) 1200 K (d) None of these Answer-b (4)
(a) 819°C (b) 719°C (c) 909°C (d) None of these Answer-a (4)
105 Pa and 0°C temperature is 0.5 km sec-1 If the pressure is kept constant but temperature is raised to 819°C, the velocity will become (a) 1.5 kms–1 (b) 2 kms–1 (c) 5 kms–1 …
(a) Collision on walls will be less (b) Number of collisions per unit time will increase (c) Collisions will be in straight lines (d) Collisions will not change Answer-b (6)
(a) Is decreased (b) Is increased (c) Remains unchanged (d) Increases or decreases according to the nature of the gas Answer-b (2)
(a) 120 K (b) 240 K (c) 480 K (d) 1120 K Answer-c (3)
(a) Proportional to T (b) Proportional to T2 (c) Proportional to T3 (d) Independent of T Answer-d (33)
2.6 kg/cm3 (a) 3.6 m/s (b) 8.9×103 m/s (c) Zero …
(a) 2.5√RT/M (b) 1.73√RT/M (c) 2.5√M/RT …
(a) Water freezes (b) Liquid helium freezes (c) Molecular motion stops (d) Liquid hydrogen freezes Answer-c (5)
(a) Temperature (b) Internal Energy (c) Friction (d) Viscosity Answer-a (4)
(a) 1.5 m/s (b) 3.4 m/s (c) 9 m/s (d) 4 m/s Answer-d (3)
(a) 2 times of H-mean value (b) 1/2 times of H-mean value (c) 4 times of H-mean value (d) Same as H-mean value Answer-b (2)
Vrms the most probable speed Vmp and the average speed Vav obey the relationship (a) Vav >Vrms > Vmp (b) Vrms >Vav >Vmp (c) Vmp > Vav >Vrms …
(TA/MA)=4(TB/MB) where is the temperature and M is molecular mass. If CA and CB are the r.m.s. speed, then the ratio CA /CB will be equal to (a) 2 (b) 4 (c) 1 (d) 0.5 Answer-a (8)
(a) 1930√3 m/s (b) 836 m/s (c) 643 m/s (d) 1930/√3 m/s Answer-b (8)
Vrms is the root mean square velocity of the molecules of a gas and the Vs velocity of sound in it, then these are related as [γ =( CP/Cv)] (a) Vrms =Vs (b) Vrms = √(3/γ)Vs (c) Vrms = √(γ/3)Vs …
(a) Increase (b) Decrease (c) Remain same (d) Decrease for some, while increase for others Answer-c (7)
(a) 800 m/s (b) 400√2 m/s (c) 400 m/s (d) 200 m/s Answer-c (2)
927°C to 27°C. The m.s. velocity of the molecules becomes (a) Double the initial value (b) Half of the initial value (c) Four times the initial value (d) Ten times the initial value Answer-b (11)
(a) 1200°C (b) 927°C (c) 600°C (d) 108°C Answer-b (3)
(O2) has root mean square velocity of C ms–1, then root mean square velocity of the hydrogen (H2) will be (a) C m/s (b) 1/C m/s (c) …
(a) √2:1 (b) 1:√2 (c) 1 : 2 (d) 2 : 1 Answer-a (5)
(a) 2.91 (b) 3.52 (c) 4.00 (d) 4.24 Answer-d (4)