The ratio of speed of sound in organ to that in water vapours at any temperature is. (When molecular weight of organ is 40 gm/mol and for water vapours is 18 gm/mol) (A) 0.75 (B) 0.73 (C) 0.68 (D) None of these 3 100 3x4

The ratio of speed of sound in monomatomic gas to that in water vapours at any temperature is. (when molecular weight of gas is 40 gm//mol and for water vapours is 18 gm//mol )

The ratio of speed of sound in monomatomic gas to that in water vapours at any temperature is. (when molecular weight of gas is 40 gm//mol and for water vapours is 18 gm//mol )

The ratio of speed of sound in neon to that in water vapours at any temperature (when molecular weight of neon is 2.02xx10^(-2)kg mol^(-1)

The ratio of speed of sound in neon to that in water vapours at any temperature (when molecular weight of neon is 2.02xx10^(-2)kg mol^(-1)

Calculate the ration of speed of sound in neon to that in water vapours at any temperature. Molecular weight on neon =2.02xx10^(-2)kg//mol e and for water vapours, molecular weight is 1.8xx10^(-2)kg//mol e .

(a) Speed of sound in air 332 m/s at NTP. What will the speed of sound in hydrogen at NTP if the density of hydrogen at NTP is (1/16) that of air. (b) Calculate the ratio of the speed of sound in neon to that in water vapour any temperature. [Molecular weight if neon = 2,02 xx 10^(-2) kg//mol and for water vapours = 1.8 xx 10^(-2) kg//mol ]

(a) Speed of sound in air 332 m/s at NTP. What will the speed of sound in hydrogen at NTP if the density of hydrogen at NTP is (1/16) that of air. (b) Calculate the ratio of the speed of sound in neon to that in water vapour any temperature. [Molecular weight if neon = 2,02 xx 10^(-2) kg//mol and for water vapours = 1.8 xx 10^(-2) kg//mol ]