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

Arrange the gases, H_(2) , N_(2), He, O_(2) in increasing rate of diffusion.

The Henry's law constant for CO_(2) in water at 298 K is 1.67 kbar. Calculate the solubility of CO_(2) at 298 K when the pressure of CO_(2) is one bar.

For real gases the relation between p, V and T is given by c=van der Waal's equation (p+ (an^(2))/V^(2)) (V-nb)=nRT where, 'a' and 'b' are van der Waal's constanrs, 'nb' is approximately equal to the total volume of the molecules of a gas. 'a' is the measure of magnitude of intermolecular attraction. (i) Arrange the following gases in the increasin order of 'b'. give reason. O_(2), CO_(2), H_(2), He (ii) Arrange the following gases in the decreasing order of magnitude of 'a'. Give reason. CH_(4), O_(2), H_(2)

K_(H) value for Ar(g),CO_(2)(g),HCHO(g)and CH_(4)(g) are 40.39,1.67,1.83xx10^(-5)and0.413 respectively. Arrange these gases in the order of their increasing solubility.

Henry’s constant (in kbar) for four gases alpha, beta, gamma and delta in water at 298 K is given below : ("density of water = 103 kg m"^(-3)" at 298 K") This table implies that :

The values of the van der Waals' constant a for some gases are given below. H_2 = 0.245 " atm " L^2 mol^(-2) O_2 = 1.360 " atm " L^2 mol^(-2) CO_2 = 3.590 " atm " L^2 mol^(-2) NH_3 = 4.170 " atm " L^2 mol^(-2) Arrange these gases in the decreasing order of their liquefaction tendencies.

A solution which remains in equilibrium with undissolved solute , in contact , is said to be saturated . The concentration of a saturated solution at a given temperature is a called solubility . The product of concentration of ions in a saturated solution of an electrolyte at a given temperature is called solubility product (K_(sp)) . For the electrolyte A_(x),B_(y) with solubility S. The solubility product (K_(sp)) is given as K_(sp) = x^(x) xx y^(y) xx S^(x-y) . While calculating the solubility of a sparingly . soluable salt in the presence of some strong electrolyte containing a common ion , the common ion concentration is practically equal to that of strong electrolyte containing a common ion . the common ion soncentration is practically equal to that of strong electrolyte . If in a solution , the ionic product of an electroylte exceeds its K_(sp) value at a particular temperature , then precipitation occurs . If two or more electrolyte are presentt in the solution , then by the addition of some suitable reagent , precipitation generally occurs in increasing order of their k_(sp) values . Solubility of some sparingly soluable salts , is sometimes enhanced through complexation . While we are calculating the solubility of some sparingly or pH of an electrolyte , the nature of cation of anion should be checked carefully whether there ion (s) are capable of undergoing hydrolysis or not . If either or both of the ions are capable of undergoing hydrolysis , it should be taken into account in calculating the solubility . While calculating the pH of an amphiprotic species , it should be checked whether or not cation can undergo hydrolysis . Total a_(H^(-)) = sqrt(K_(a_(1)xxK_(a_(2)))) (if cation do not undergo hydrolysis ) a_(H^(+)) = sqrt(K_(a_(1))((K_(w))/(K_(b)) - K_(a_(2)))) (if cation also undergoes hydrolysis ) where symbols have usual meaning . Solubility of solids into liquids is a function of temperature alone but solubility of gases into liquids is a function of temperature as well as pressure . The effect of pressure on solubility of gases into liquids is governed by Henry's law . The solubility of BaSO_(4) in 0.1 M BaCl_(2) solution is (K_(sp) " of " BaSO_(4) = 1.5 xx 10^(-9))

A solution which remains in equilibrium with undissolved solute , in contact , is said to be saturated . The concentration of a saturated solution at a given temperature is a called solubility . The product of concentration of ions in a saturated solution of an electrolyte at a given temperature is called solubility product (K_(sp)) . For the electrolyte A_(x),B_(y) with solubility S. The solubility product (K_(sp)) is given as K_(sp) = x^(x) xx y^(y) xx S^(x-y) . While calculating the solubility of a sparingly . soluable salt in the presence of some strong electrolyte containing a common ion , the common ion concentration is practically equal to that of strong electrolyte containing a common ion . the common ion soncentration is practically equal to that of strong electrolyte . If in a solution , the ionic product of an electroylte exceeds its K_(sp) value at a particular temperature , then precipitation occurs . If two or more electrolyte are presentt in the solution , then by the addition of some suitable reagent , precipitation generally occurs in increasing order of their k_(sp) values . Solubility of some sparingly soluable salts , is sometimes enhanced through complexation . While we are calculating the solubility of some sparingly or pH of an electrolyte , the nature of cation of anion should be checked carefully whether there ion (s) are capable of undergoing hydrolysis or not . If either or both of the ions are capable of undergoing hydrolysis , it should be taken into account in calculating the solubility . While calculating the pH of an amphiprotic species , it should be checked whether or not cation can undergo hydrolysis . Total a_(H^(-)) = sqrt(K_(a_(1)xxK_(a_(2)))) (if cation do not undergo hydrolysis ) a_(H^(+)) = sqrt(K_(a_(1))((K_(w))/(K_(b)) - K_(a_(2)))) (if cation also undergoes hydrolysis ) where symbols have usual meaning . Solubility of solids into liquids is a function of temperature alone but solubility of gases into liquids is a function of temperature as well as pressure . The effect of pressure on solubility of gases into liquids is governed by Henry's law . The solubility of PbSO_(4) in water is 0.0303 g/l at 25^(@)C , its solubility product at that temperature is

I. Arrange the compounds of (a) in the order of decreasing boiling points and (b) in the order of decreasing solubility in water. (A) (1) Ethanol, (2) Propane, (3) Pentanol (B) (1) Butane, (2) 1,2,3-Pentane triol, (3) Butyl alcohol (C) (1) Pentane, (2) Pentanol, (3) Hexanol II. Arrange the following in the decreasing order of their boiling points. (A) (1) C_(3)H_(8) , (2) C_(2)H_(5)OH , (3) (CH_(3))_(2)O , (4) HOH_(2)C----CH_(2)OH (B) (1) 3-pentanol, (2) n-Pentane, (3) 2,2-Dimethyl propanol, (4) n-Pentanol III. Arrange the following alcohols (a) in the decreasing order of their boilling points and (b) in the decreasing order of their solubility in water. (1) n-Butyl alcohol (2) sec-Butyl alcohol and (3) tert-Butyl alcohol IV. Arrange the following compounds in the order of their increasing boiling points. (1) CH_(3)COC1 , (2) (CH_(3)CO)_(2)O , (3) CH_(3)CONH_(2) , (4) CH_(3)COOH

For real gases, van der Waals' equation is written as (P+(an^(2))/(V^(2))) (V-nb)= nRT where a and b are van der Waals' constants. Two sets of gases are: (I) O_(2), CO_(2), H_(2) and He(II) CH_(4), O_(2) and O_(2) and H_(2) The gases given in set I in increasing order of b and gases given in set II in decreasing order of a are arranged below. Select the correct order from the following: