`Zn|Zn_((C_(1)))^(2+)||Zn_((C_(2)))^(2+)| Zn(s)`. Then `DeltaG` is -ve if

Zn | Zn^(2+)(C_(1) || Zn^(2+)(C_(2)| Zn . For this cell DeltaG is negative if:

Zn | Zn^(2+)(C_(1) || Zn^(2+)(C_(2)| Zn . For this cell DeltaG is negative if:

Zn|Zn^(2+)(c_1M)||Zn^(2+)(c_2M)|Zn . For this cell, DeltaG would be negative , if :

Calculate the emf and DeltaG^(0) for the cell reaction at 25^(@)C : Zn(s) underset((0.1M))(|Zn_((aq))^(2+)|) underset((0.01M))( |Cd_((aq))^(2+)|) Cd_((s)) Given E_(Zn^(2+)//Zn)^(0)= -0.763 and E_(Cd^(2+)//Cd)^(0)= -0.403V

If [Zn^(2+)] is maintained at 1.0 M (i) What is the minimum (Cu^(2+)) for which the reaction Zn_((s))+Cu_((aq))^(2+) to Cu_((s))+Zn_((aq))^(2+) is still spontaneous in forward direction. (ii) Does the displacement of Cu_((aq))^(2+)" by "Zn_((s)) go to completion? E_(Zn^(2+)//Zn)^(0)=-0.76V E_(Cu^(2+)//Cu)=0.34V

At 1000^(@)C , Zn_((s)) +(1)/(2)O_(2(g)) to ZnO_((s)), DeltaG^(@)=-360 KJ "mol"^(-1) C_((s)) + (1)/(2)O_(2(g)) to CO_((g)),DeltaG^(@) =-460 KJ "mol"^(-1) The correct statement is

In the following electrochemical cell : Zn|Zn^(2+)||H^(o+)|(H_(2))Pt E_(cell)=E^(c-)._(cell). This will be when 1) [Zn^(2+)]=[H^(o+)]=1M and p_(H_(2))1 atm 2) [Zn^(2+)]=0.01 M,[H^(o+)]=0.1M, and p_(H_(2))=1atm 3) [Zn^(2+)]=1m,[H^(o+)]=0.1M, and p_(H_(2))=0.01atm 4) [Zn^(2+)]=[H^(o+)]=0.1M and p_(H_(2))=0.1 atm

For the galvanic cell Mg(s)|Mg^(2+)(aq)||Zn^(2+)(aq)|Zn(s) ,the standard free energy change is ( Given:E_((mg^(2+))/(mg))^@= -2.36 V,E_((Zn^(2+))/(Zn))^@= -0.76 V)

In the following electrochemical cell : Zn|Zn^(2+)||H^(o+)|(H_(2))Pt E_(cell)=E^(c-)._(cell). This will be when

Consider the following concentration cell : Zn(s)|Zn^(2+)(0.024M)||Zn^(2+)(0.480M)|Zn(s) which of the following statements is // are correct?