The value of Henry's constant `K_(H)`…….

The value of Henry's law constant for some gases at 293 K is given below. Arrange the gases in the increasing order of their solubility . He:144.97 kbar, H_2 :69.16 kbar, N_2 :76.48 kbar, O_2 : 34.86 kbar

(i) Gas A is more soluble in water than Gas (B) at the same temperature. Which one of the two gases will have the higher value of K_(H) (Henry's constant) and why? (ii) In non-ideal solution, what type of deviation shows the formation of maximum boiling azeotropes ?

What is the significance of Hanry's law constant K_(H) ?

If the value of equilibrium constant K_(c) for the reaction, N_(2)+3H_(2)hArr2NH_(3) is 7. The equilibrium constant for the reaction 2N_(2)+6H_(2)hArr4NH_(3) will be

Acid rain takes place dur to combination of acidic oxides with water and it is an environmental concern all over the world. Assuming rain water is uncontaminated with HNO_(3) or H_(2)SO_(4) and is in equilibrium with 1.25 xx 10^(-4) atm CO_(2) . The Henry's law constant (K_(H)) is 1.25 xx 10^(6) "torr". K_(a_(1)) of H_(2)CO_(3) = 4.3 xx 10^(-7) What is the pH of neutral rain water ?

For metals the value of dielectric constant (K) is

Acid rain takes place dur to combination of acidic oxides with water and it is an envirronmental concern all over the world. Assuming rain water is uncontaminated with HNO_(3) or H_(2)SO_(4) and is in equilibrium with 1.25 xx 10^(-4) atm CO_(2) . The Henry's law constant (K_(H)) is 1.25 xx 10^(6) "torr". K_(a_(1)) of H_(2)CO_(3) = 4.3 xx 10^(-7) Given : K_(f)CuCI^(Theta) = 1.0 (K_(f) is formation constant of CuCI^(o+)) If SO_(2) content is the atomsphere is 0.64 "ppm" by volume, pH of rain water is (assume 100% ionisation of acid rain as monobasic acid).

For the reaction H_(2)(g) + I_(2)(g)hArr2HI(g) at 721 K the value of equilibrium constant (K_(c)) is 50. When the equilibrium concentration of both is 0.5 M, the value of K_(p) under the same condtions will be

Determine the values of equilibrium constant (K_C) and DeltaG^o for the following reaction :

If 0.5 mole H_(2) is reacted with 0.5 mole I_(2) in a ten - litre container at 444^(@)C and at same temperature value of equilibrium constant K_(C) is 49, the ratio of [Hl] and [l_(2)] will be :