Boyle's temperature `T_(b)` is equal to

At Boyle temperature

Boyle's temperature (T_(B)) : It is the temperature at which a real gas exhibits ideal behavior in low pressure range. Different gases have different value of T_(B) , which is related to the van der Wall's constant a and ab as follows: T_(B) = (a)/(Rb) The compressiblity factor for a real gas is given as Z = 1 + 0.35 P - (168)/(T)P . Where P is in bar and T is in Kelvin. What is the Boyle's temperature of the gas?

The van der Waals' constantes for a gas are a=3.6 atmL^(2)mol^(-2),b=0.6Lmol^(-1) .If R=0.08LatmK^(-1)mol^(-1) and the Boyle's temperature (K) is T_(B) of this gas, then what is the value of (T_(B))/(15) ?

Sketch shows the plot of Z v/s P for a hypothetical gas for one mole at three distint temperature. Boyle's temperature is the temperature at which gas shows ideal behaviour over a pressure range in the low pressure region.Boyle's temperature (T_b)=a/(Rb) .If a plot is obtained at temperature well below Boyle's temperature then the curve will show negative deviation, in low pressure region and positive deviation in the high pressure region. Near critical temperature the curve is more likely as CO_2 and the temperature well above critical temperature curve is more like H_2 at 0^@C as shown above.At high pressure suppose all the constant temperature curve varies linearly with pressure according to the following equation : Z=1+(Pb)/(RT) ( R=2 cal "mol"^(-1) K^(-1) ) Which of the following is correct :

Sketch shows the plot of Z v/s P for a hypothetical gas for one mole at three distint temperature. Boyle's temperature is the temperature at which gas shows ideal behaviour over a pressure range in the low pressure region.Boyle's temperature (T_b)=a/(Rb) .If a plot is obtained at temperature well below Boyle's temperature then the curve will show negative deviation, in low pressure region and positive deviation in the high pressure region. Near critical temperature the curve is more likely as CO_2 and the temperature well above critical temperature curve is more like H_2 at 0^@C as shown above.At high pressure suppose all the constant temperature curve varies linearly with pressure according to the following equation : Z=1+(Pb)/(RT) ( R=2 cal "mol"^(-1) K^(-1) ) For 500 K plot value of Z changes from 2 to 2.2 if pressure is varied from 1000 atm to 1200 atm (high pressure ) then the value of b/(RT) will be

Internal energy of n moles of helium at temperature T_1 K is equal to the internal energy of 2n moles of oxygen gas at temperature T_2 K then the value of T_1 /T_2 will be

Sketch shows the plot of Z v/s P for a hypothetical gas for one mole at three distint temperature. Boyle's temperature is the temperature at which gas shows ideal behaviour over a pressure range in the low pressure region.Boyle's temperature (T_b)=a/(Rb) .If a plot is obtained at temperature well below Boyle's temperature then the curve will show negative deviation, in low pressure region and positive deviation in the high pressure region. Near critical temperature the curve is more likely as CO_2 and the temperature well above critical temperature curve is more like H_2 at 0^@C as shown above.At high pressure suppose all the constant temperature curve varies linearly with pressure according to the following equation : Z=1+(Pb)/(RT) ( R=2 cal "mol"^(-1) K^(-1) ) In very high pressure region if Z v/s P is plotted at 1200 K for the above gas then it will have greatest slope.

The correct order of temperature of a real gas is : (I) Boyle's temperature (II) Critical temperature (III) Inversion temperature

Sketch shows the plot of Z vs P for 1 mol of a hypothetical gas at three distinct temperature. Boyle’s temperature is the temperature at which a gas shows ideal behaviour over a pressure range in the low pressure region. Boyle’s temperature (T_(b)) = (a)/(Rb) . If a plot is obtained at temperatures well below Boyle’s temperature then the curve will show negative deviation, in low pressure region and positive deviation in the high pressure region. Near critical temperature the curve is more like CO_(2) and the temperature well above critical temperature curve is more like H_(2) as shown above. At high pressure suppose all the constant temperature curve varies linearly with pressure according to the following equation: Z =1 + (Pb)/(RT) (R = 2 cal mol^(-1) K^(-1)) For 500 K plot the value of Z changes from 2 to 2.2 if pressure is varied from 1000 atm to 1200 atm (high pressure) then the value of (b)/(RT) will be :

What is Boyle's temperature?