Nernst equation is `E = E^(@)-(RT)/(nF)lnQ`. If `Q = K_(C)`, then which one is one correct,

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

If f(x) = e^(absx) , then which one of the following is correct ?

If E and F are events with P(E) 0 then which one is not correct?

The driving force DeltaG diminishes to zero on the way to equilibrium, just as in any other spontaneous process. Both DeltaG and the corresponding cell potential (E=-(DeltaG)/(nF)) are zero when the redox reaction comes to equilibrium. The Nernst equation for the redox process of the cell may be given as : E=E^(@)-0.059/n log Q The key to the relationship is the standard cell potential E^(@) , derived from the standard free energy changes as : E^(@)=-(DeltaG^(@))/(nF) At equilibrium, the Nernst equation is given as : E^(@)=0.059/n log K The equilibrium constant K_(c) for the reaction : Cu(s)+2Ag^(+) (aq.)+2Ag(s)" "(E_(cell)^(@)=0.46 V) will be :

The name associated with equation E=E^(@)+(RT)/(nF)In([M^(n+)])/([M]) is

In Arrhenius equation k = Ae^(-E_(a)//RT)) , A is the value of the rate constant

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 ]

Arrhenius equation k=Ae^(-E_(a)//RT) If the activation energy of the reaction is found to be equal to RT then,