The relation between pressure exerted by an ideal gas `(p_("ideal"))` and observed pressure `(p_("real"))` is given by the equation,
`p_("ideal")=p_("real")+ (an^(2))/V^(2)`
(i) If pressure is taken in `NM^(-2)`, number of moles in mol and volume in `m^(3)`, calculate the unit of 'a'.
(ii) What will be the unit of 'a' when pressure is in atmosphere and volume in `dm^(3)`?

The relation between pressure exerted by an ideal gas (p_("ideal")) and observed pressure (p_("real")) is given by the equation " " p_("ideal")=p_("real")+(an^(2))/(V^(2)) If pressure is taken in N m^(-2) , number of moles in mol and volume in m^(3) , calculate the unit of 'a'. What will be the unit of 'a' when pressure is in atmosphere is in atmosphere and volume in dm^(3) ?

The relation between pressure exerted by an ideal gas (pideal) and observed pressure (preal) is given by the equation, p_("ideal") = p_("real") + (an^(2))/(V^(2)) If pressure is taken in Nm^(-2) , number of moles in mol and volume in m_(3) , calculate the unit of ' a '.

The relation between pressure exerted by an ideal gas (pideal) and observed pressure (preal) is given by the equation, p_("ideal") = p_("real") + (an^(2))/(V^(2)) What will be the unit of ' a ' when pressure is in atmosphere and volume in dm_(3) ?

The pressure p and volume V of an ideal gas both increase in a process.

The pressure p and volume V of an ideal gas both increase in a process.

The pressure p and volume V of an ideal gas both increase in a process.