The Nernst equation E=`E^(@)`-RT/nF in Q indicates that the Q will be equal to equilibrium constant `K_c` when:

The equation E=hv indicates that

How Nernst equation can be applied in the calculation of equilibrium constant of any cell reaction ?

Assertion:- The reaction quotient Q, has the same presentation form as the equilibrium constant K and Q is evaluated using any given concentrations of the species involved in the reaction, and not necesssarily equilibrium concenetrations. Reason:- If the numerical value of Q is not the same as the value of equilibrium constant, that time reaction will never proceed.

When A_2 and B_2 are allowed to react, the equilibrium constant of the reaction at 27^@C is K_C = 4 What will be the equilibrium concentration of AB?

For the reaction, A hArr B ,deltaH for the reaction is -33.0 kJ/mol. Calculate (i) Equilibrium constant K_c for the reaction at 300 K (ii) If E_a (f) and E_a(r ) in the ratio 20:31 , calculate E_a(f) at 300 K . Assuming pre-exponential factor same for forward and reverse reaction.

for the reaction P+Q rArr R + 2S , initially the concentration of P is equal to that of Q (1 molar) but at equilibrium the concentration of R will be twice of that of P, then the equilibrium constant of the reaction is

In Arrhenius equation , K=Ae^(-E_a//RT) . The A is

K_(p) and K_(c) are inter related as K_(p)=K_(c)(RT)^(Deltan) Answer the following questions: The unit of equilibrium constant for H_(2)(g)+I_(2)(g) hArr 2HI(g)

Consider the following reaction. The reaction is first order in each direction, with an equilibrium constant of 10^(4) . For the conversion of chair form to boat form, e^(-Ea//RT)=4.35xx10^(-8) at 298 K with pre-exponential factor of 10^(12)s^(-1) . Apparent rate constant (k_(A)) at 298 K is :

Arrhenius equation k=Ae^(-E_(a)//RT) If the activation energy of the reaction is found to be equal to RT, then [given : (1)/(e )=0.3679 ]