what is the standard electrode potential for the reduction of HClO?
`HClO(aq)+H^+(aq+2e^(-)toCl^(-)(aq)+H_2O(l)`
Given: `Cr^2(aq)toCr^(3+)(aq)+e^(-),E^(@)=0.41V`
`HClO(aq)+H^+(aq)+2Cr^(2+)(aq)to2Cr^(3+)(aq)+H_2O(l),E^(@)=1.80`

Given the listed standard electrode potentials, what is E^(@) for the cell: 4BiO^+(aq)+3N_2H_5^+(aq)to4Bi(s)3N_2(g)+4H_2O)l)+7H^+(aq) N_2(g)+5H^+(aq)+4e^(-)toN_2H_5^+(aq),E^(@)=-0.23V BiO^+(aq)+2H^+(aq)+3e^(-)toBi(s)+H_2O(l),E^(@)=+0.32V

In the reaction 2Al(s)+6HCl(aq)to6Cl^(-)(aq)+3H_2

Electrode potential of the half Pt(s)|Hg(l)| Hg_(2)Cl_(2)(s) | Cl^(-)(aq) can be incresed by :

Use the following standard electrode potentials, calculate DeltaG^(@) in kJ // mol for the indicated reaction : 5Ce^(4+)(aq)+Mn^(2+)(aq)+4H_(2)O(l)to5Ce^(3+)(aq)+ MnO_(4)^(-)(aq)+8H^(+)(aq) MnO_(4)^(-)(aq)+8H^(+)(aq)+5e^(-)toMn^(2+)(aq)+4H_(2)O(l), E^(@)=+1.51 V Ce^(4+)(aq)+e^(=)toCe^(3+)(aq)" "E^(@)=+1.61 V

Given the folowing standerd electrode potentials, the K_(sp) for PbBr_(2) is : PbBr_(2)(s)+2e^(-)toPb(s)+2Br^(-)(aq), E^(@)=-0.248 V Pb^(2+)(aq)+2e^(-)toPb(s), E^(@)=-0.126 V

Complete the reaction : Cu^(2+) (aq) + NH_3 (aq.) rarr

Using the standard electrode potentials given in Table 3.1 predict if the reaction between the following is feasible: Br_2 (aq) and Fe^(2+) (aq) .

Using the standerd half-cell potential listed, calculate the equilibrium constant for the reaction : Co(s)+2H^(+)(aq)toCo^(2+)(aq)+H_(2)(g)" at 298 K" Co^(2+)(aq)+2e^(-)toCo(s) E^(@)=-0.277 V

calculate the value of equilibrium constant (K_f) for the reaction: Zn^(2+)(aq)+4OH^(-)(aq)iffZn(OH)_4^(2-)(aq) Given: Zn^(2+)(aq)+2e^(-)toZn(s0,E^(@)=-0.76 V Zn(OH)_4^(2-)(aq)+2e^(-)toZn(s)+4OH^(-)(aq),E^(@)=-1.36 V 2.303(RT)/F=0.06

Balance the following equation : Al(s) +HCl(aq) rarr AlCl_2(aq)+H_2(g)