The equilibrium constant for the reaction:
`CH_(3)COOH(l) +C_(2)H_(5)OH(l) hArr CH_(3)COOC_(2)H_(5)(l)+H_(2)O(l)`
has been found to be equal to `4` at `25^(@)C`. Calculate the free energy change for the reaction.

The equilibrium constant for the reaction CH_(3)COOH+C_(2)H_(5)OH hArr CH_(3)COOC_(2)H_(5)+H_(2)O is 4.0 at 25^(@)C . Calculate the weight of ethyl acetate that will be obtained when 120g of acetic acid are reacted with 92 g of alcohol.

For the reaction CH_3COOH(l)+C_2H_5(l)hArrCH_3COOC_2H_5(l)+H_2O(l) the value of equilibrium constant (K) is 4 at 298 K. The standard free energy change (DeltaG^@) is equal to

For the reaction C_2H_(5)OH(l) + 3 O_(2)(g) rightarrow 2CO_(2)(g) + 3 H_(2)O(l) , which one is true ?

Write the equilibrium constant expressions for the following reactions. CH_3 COOH(aq) +H_2O(l) hArr CH_3 COO^(-) (aq) + H_3O^(+) (aq)

The ester , ethyl acetate is formed by the reaction of ethanol and acetic acid and the equilibrium is represented as : CH_(3) COOH(l) +C_(2)H_(5)OH(l)hArr CH_(3)COOC_(2)H_(5)(l) +H_(2)O(l) (i) Write the concentration ratio (concentration quotient) Q for this reaction. Note that water is not in excess and is not a solvent in this reaction. (ii) At 293 K, if one starts with 1.000 mol of acetic acid 0.180 mol of ethanol, there is 0.171 mol of ethyl acetate in the final equilibrium mixture . Calculate the equilibrium constant. (iii) Starting with 0.50 mol of ethanol and 1.000 mol of acetic acid and maintaining it at 293 K, 0.214 mol of ethyl acetate is found after some time. Has equilibrium been reached?

sort out the homogeneous and netrogeneous equilibrium from the following CH_3COOH (l) + C_2H_5(l) hArr CH_3COOC_2H_5 (l)+ H_2O(l)

Write the equilibrium constant expression for the following reactions : HCl( aq) +H_2O(l) hArr H_3O^(+) +Cl^(-) (aq)