For the following cell reaction,
`Ag | Ag^(+) | AgCl | Cl^(-) | Cl_(2) , Pt`
`Delta G_(f)^(0) (AgCl) =-109 kJ//mol`
`Delta G_(f)^(0) (Cl ) = -129kJ//mol`
`Delta G_(f)^(0) (Ag^(+)) = 78 kJ//mol`
`E^@` of the cell is

Calculate the pH at which the following conversion (reacton ) will be at equilibrium in basic medium I_(2(s)) hArr I_((aq))^(-) + IO_(3(aq))^(-) . When the equilibrium concentrations at 300 K are [I^(-)] = 0.10 and [IO_(3)^(-)] = 0.10M Given that Delta G_(f)^(0) (I^(-)aq) = -50 kJ/mole, Delta G_(f)^(0) (IO_(3)^(-), aq) = -123.5 kJ//"mole", Delta G_(f)^(0) (H_(2)O, l) = - 233 kJ/mole, DeltaG_(f)^(0) (OH^(-), aq) = - 150 kJ/mole, Ideal gas constant = R = (25)/(3)J "mole"^(-1) K^(-1) , log e = 2.3,

Consider the following reaction : CO_((g)) + 2H_(2(g)) hArr CH_(3)OH_((g)) Given : Delta_(r) H^(@) (CH_(3)OOH, g) = -201 kJ/mol, Delta_(r) H^(@) (CO, g) = -114 kJ/mol S^(@) (CH_(3)OOH, g) = 240 J/K-mol , S^(@) (H_(2), g) = 29 JK^(-1)mol^(-1) S^(@) (CO, g) = 198 J/mol-K , C^(@)_(p,m) (H_(2)) = 28.8 J/mol-K C^(@)_(p,m) (CO) = 29.4 J/mol-K , C^(@)_(p,m) (CH_(3)OH) = 44 J/mol-K and ln ((320)/(300)) = 0.06 , all data at 300 K Delta_(r) S^(@) at 300 K for the reaction is :

Consider the following reaction : CO_((g)) + 2H_(2(g)) hArr CH_(3)OH_((g)) Given : Delta_(r) H^(@) (CH_(3)OOH, g) = -201 kJ/mol, Delta_(r) H^(@) (CO, g) = -114 kJ/mol S^(@) (CH_(3)OOH, g) = 240 J/K-mol , S^(@) (H_(2), g) = 29 JK^(-1)mol^(-1) S^(@) (CO, g) = 198 J/mol-K , C^(@)_(p,m) (H_(2)) = 28.8 J/mol-K C^(@)_(p,m) (CO) = 29.4 J/mol-K , C^(@)_(p,m) (CH_(3)OH) = 44 J/mol-K and ln ((320)/(300)) = 0.06 , all data at 300 K Delta_(r) H^(@) at 300 K for the reaction is :

Consider the following reaction : CO_((g)) + 2H_(2(g)) hArr CH_(3)OH_((g)) Given : Delta_(r) H^(@) (CH_(3)OH, g) = -201 kJ/mol, Delta_(r) H^(@) (CO, g) = -114 kJ/mol S^(@) (CH_(3)OOH, g) = 240 J/K-mol , S^(@) (H_(2), g) = 29 JK^(-1)mol^(-1) S^(@) (CO, g) = 198 J/mol-K , C^(@)_(p,m) (H_(2)) = 28.8 J/mol-K C^(@)_(p,m) (CO) = 29.4 J/mol-K , C^(@)_(p,m) (CH_(3)OH) = 44 J/mol-K and ln ((320)/(300)) = 0.06 , all data at 300 K Delta_(r) S^(@) at 320 K is :

For a Ag -Zn button cell , net reaction is : Zn_((s) + Ag_2 O_((s)) to ZnO_((s)) + 2Ag_((s)) , DeltaG^(0)f (Ag_2O) = -11 . 21 kJ mol^(-1) DeltaG^(0)F (ZnO) = -318 . 3 kJ mol^(-1) Hence E_("cell")^(0) of the button cell is :

The bond dissociation energy depends upon the nature of the bond and nature of the molecule. If any molecule more than 1 bonds of similar nature are present then the bond energy reported is the average bond energy. Determine C-C and C-H bond enthalpy (in kJ/mol). Given: Delta_(f)H^(0) (C_(2)H_(6),g)= -85kJ//mol, Delta_(f) H^(0) (C_(3)H_(8), g)= -104kJ//mole, Delta_("sub")H^(0) (C,s)= 718kJ//mol , B.E. (H-H)= 436 kJ/mol,

Calculate a) DeltaG^(@) and b) the equilibrium constant for the formation of NO_(2) from NO and O_(2) at 298K NO(g)+1//2O_(2)(g)hArrNO_(2)(g) where Delta_(f)G^(oplus)(NO_(2))=52.0kJ//mol Delta_(f)G^(oplus)(NO)=87.0kJ//mol Delta_(f)G^(oplus)(O_(2))=0kJ//mol

The formation of the oxide ion O _((g)) ^(2-) from oxygen atom requires first an exothermic and then an endothermic step as shown below : O _((g)) + e ^(-) to O _((g )) ^(-) ,Delta _(f) H^(0) =-141 kJ mol ^(-1) O _((g)) ^(-) +e ^(-) to O _((g)) ^(-2) ,Delta _(f) H^(0) =+ 780 kJ mol ^(-1) Thus, process of formation of O^(2-) in gas phase is unfavourable even thrugh O ^(2-) is isoelectronic with neon. It is due to the fact that (2015)