Three moles of ideal gas A with (C(p))/(...

Three moles of ideal gas A with `(C_(p))/(C_(v))=(4)/(3)` is mixed with two moles of another ideal gas B with `(C _(P))/(C_(v))=(5)/(3)` The `(C_(P))/(C_(v))` of mixture is (Assuming temperature is constant)

Similar Questions

Explore conceptually related problems

Two moles the an ideal gas with C_(v) = (3)/(2)R are mixed with 3 of anthoer ideal gas with C_(v) = (5)/(2) R . The value of the C_(p) for the mixture is :

Two moles on ideal gas with gamma=5/3 is mixed with 3 moles of another ideal non reacting gas with gamma=7/5 .The value of (C_p)/(C_v) for the gasous mixture is closer to :

Find (C_(p))/(C_(v)) for monatomic ideal gas.

(a) Define two specific heats of a gas. Why is C_(p) gt C_(v) ? (b) Shown that for an ideal gas, C_(p) = C_(v) +(R )/(J)

10 moles of an ideal monoatomic gas at 10^(@)C are mixed with 20 moles of another monoatomic gas at 20^(@)C . Then the temp. of the mixture is

For one mole of ideal gas if P=(P_(0))/(1+((V)/(V_(0)))) where P_(0) and V_(0) are constant, then temperature of gas when V=V_(0) is:

For 2 mole of an ideal gas , the relation between C_(p) & C_(v) (non-molar) are:

If one mole of an ideal gas with C_(v) = (3)/(2) R is heated at a constant pressure of 1 atm 25^(@)C to 100^(@)C . Which is correct

For an ideal gas (C_(p,m))/(C_(v,m))=gamma . The molecular mass of the gas is M, its specific heat capacity at constant volume is :

For an ideal gas C_(p) and C_(v) are related as

Three moles of ideal gas A with `(C_(p))/(C_(v))=(4)/(3)` is mixed with two moles of another ideal gas B with `(C _(P))/(C_(v))=(5)/(3)` The `(C_(P))/(C_(v))` of mixture is (Assuming temperature is constant)

Similar Questions

Recommended Questions