Calculate the equilibrium constant `K_(c)` for the rections.
`3Sn^(4) + 2 cr to 3Sn^(2+) + 2Cr^(3+)`
Given `E^(o) = 0.885 V`.

Calculate the equilibrium constant for the reaction: 3Sn(s) +2Cr_(2)O_(7)^(2-) +28 H^(+) rarr 3Sn^(+4) +4Cr^(3+) +14H_(2)O E^(@) for Sn//Sn^(+2) = 0.136 V E^(@) for4 Sn^(2+)//Sn^(4+) =- 0.154V E^(@) for Cr_(2)O_(7)^(2-)//Cr^(3+) = 1.33V

Determine the equilibrium constant of the reaction at 298 K, 2Fe^(3+) +Sn^(2+) hArr 2Fe^(2+) +Sn^(4+) From the obtained value of the equilibrium constant, predict whether Sn^(2+) ions can reduce Fe^(3+) to Fe^(2+) quantitatively or not. Given: E_(Fe^(3+),Fe^(2+)//Pt)=0.771V.E_(Sn^(4+)//Sn^(2+)//Pt)^(Theta)=0.150V . [R=8.314JK^(-1)"mol"^(-1)]

Find the equilibrium constant of the following reaction Cu^(2+) (aq) +Sn^(2+) (aq) hArr Cu(s) +Sn^(4+) (aq) at 25^(@)C, E_(Cu^(2+)//Cu)^(Theta)=0.34V, E_(Sn^(4+)//Sn^(2+))^(Theta)=0.155V

The e.m.f E_("cell")^(Theta) of the cell reaction 3Sn^(4+) +2Cr to 3Sn^(4+) +2Cr^(3+) is 0.89 V. Calculate Delta_(r )G^(Theta) for the reaction (F=96500"C mol"^(-1)) .

Under standered condition Delta G^(@) for the reaction 2Cr(s)= 3Cd^(2+)(aq) rarr 2Cr_((a a))^(3+) +3Cd(s) is (E_(Cr^(3+)//Cr)^(@) = - 0.74 V, E_(Cd^(2+)//Cd)^(@) = - 0.4 V)

Consider the following E^@ values . E_(Fe^(3+)//Fe^(2+)^@ = + 0.77 V , E_(Sn^(2+)//Sn)^@=- 0.14 V The E_(cell)^@ for the reaction , Sn (s) + 2Fe^(3+)(aq) rarr 2 Fe^(2+)(aq)+ Sn^(2+)(aq) is ? (a) -0.58 V (b) -0.30 V (c) +0.30V (d) +0.58 V

Calculate EMF of the following cells at 25^(@)C (i) Fe|Fe^(2+) (a=0.6 M) || Sn^(2+). (a=0.2M)|Sn . E_(Fe^(2+), Fe)^(0) =-0.44 V and E_(Sn^(2+),Sn)^(0)=0.14V (ii) Pt, H_(2) (3"atm") |HCl |H_(2) ("15 atm"), Pt, E_(H^(+)//1/2 H_(2))^(0)=0V

Predict whether the following reaction can occur under standard conditions or not. Sn^(2+) (aq) +Br_(2)(l) rarr Sn^(4+) (aq) +2Br^(-)(aq) Given: E_(Sn^(4+)//Sn^(2+))^(@) = + 0.15, E_(Br^(2)//Br^(-))^(@) = 1.06V .

Calculate the emf of the cell Cr∣ Cr^(3+)(0.1 M)∣∣Fe^(2+) (0.01M)∣Fe (Given: E^(@)Cr^(3+) /Cr =−0.75 volt; E^(@)Fe^(2+) /Fe =−0.45 volt).

The Gibbs energy change (in J) for the given reaction at [Cu^(2+) ] = [Sn^(2+) ] = 1 M and 298 K is : Cu (s) + Sn^(2+) (aq) to Cu^(2+) (aq.) + Sn(s), (E_(Sn^(2+) // Sn)^(0) = -0.16 V E_(Cu^(2+) |Cu)^(0) = 0.34 V , Take F = 96500 C mol^(-1) )