The lattice energy of solid NaCl is 180K. Call per mol. The dissolution of the solid in water in the form of ions is endothermic to the extent of 1K, Cal per mol. If the solvation energies of `Na^(+) and Cl^(-)` ions are in ratio `6:5`, what is the enthalpy of hydration of sodium ion?

Define "lattice energy" of crystals. Calculate the number of sodium ions and chloride ions per unit cell of NaCl.

The heat of formation of crystalline sodium chloride is -410 kJ mol^(-1) . The heat of sublimation of sodium metal is 180.8 kJ mol^(-1) . The heat of dissociation of chlorine gas into atoms is 242.7 kJ mol^(-1) . The ionisation energy of Na and electron affinity of Cl are 493.7 kJ and -368.2 kJ respectively. Calculate the lattice energy of NaCl.

Calculate the number of calories of energy released when 1 L of HCI is formed at 1 atm and 25^(@)C . The dissociation energies of gaseous H_(2),Cl_(2) and HCl are respectively 104, 58 and 103 K cal mol^(-1) .

Calculate heat of solution of NaCl from the following data Hydration energy of Na^(+) = -389kJ mol^(-1) Hydration energy of Cl^(-) = -382kJ mol^(-1) Lattice energy of NaCl = +776 kJ mol^(-)

The magniutudes of lattice and hydration energies of salt AB are found to be 764 and 755 kJ respectively. If entropy of dissolution of AB in water is 40 JK^(-1) mol^(-1) at 298 K. Gibb's energy change for the dissolution of AB will be

Lattice dissociation energy and hydration energy of sodium chloride are respectively 788 kJ mol^(-1) and 784 kJ mol^(-1) . Then enthalpy of solution of sodium chloride in water is

Sodium chloride crystallises into F.C.C lattice with Na occupying corner of a cube and the centre of each face, whereas Cl^(-) is occupies the centre of each edge and centre of the cube. The r_c //r_a value for NaCl is 0.53 and coordination number is 6. If all the face centred ions along one of the axis are removed, the stoichiometry of the resulting solid is

On the basis of the postulates of kinetic theory of gases, it is possible to derive the mathematical expression, commonly known as kinetic gas equation. PV = 1/3 m n u^3? where, P= Pressure of the gas, V a volume of the gas, m=Mass of a molecule, n = Number of molecules present in the given amount of a gas and u = root mean square speed For one mole of gas, PV = RT and n=N_A 1/3 m N_a u^2 = RT or 2/3 .1/2m N_A u^2 = N_A [1/2mN_Au^2 = KE "per mole"] ,2/3K.E. = RT implies K.E. 3/2RT Average kinetic energy per mol does not depend on the nature of the gas but depends only on temperature. This, when two gases are mixed at the same temperature, there will be no rise or decrease in temperature unless both react chemically. Average kinetic energy per molecule = ("Average K.E. per mole")/N = 3/2(RT)/(N) implies 3/2kT where k is the Boltzmann constant Which of the following expressions correctly represents the relationship between the average molar kinetic energies of CO and N_2 molecules at the same temperature ?