What is the normal boiling point of mercury?
Given : `DeltaH _(f)^(@)(Hg,l)=0,S^(@)(Hg,l)=77.4 J//K-"mol"`
`DeltaH _(f)^(@)(Hg,g)= 60.8 kJ//"mol", S^(@)(Hg, g)=174.4 J//K-"mol"`

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)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 :

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 :

What is the melting point of benzene if Delta H_("fusion") = 9.95 kJ//mol and Delta S_("fusion") = 35.7 J//K- mol ?

Consider the following data: Delta_(f) H^(2) (N_(2)H_(4), l) =50kJ//mol,, Delta_(f) H^(@) (NH_(3), g)=-46 kJ//mol , B.E. (N-H)= 393kJ//mol and B.E. (H-H)= 436 kJ/mol, also Delta_("vap") H (N_(2)H_(4),l)= 18kJ//mol . The N-N bond energy in N_(2)H_(4) is

Calculate the enthalpy change for the process "CC"l_(4)(g)toC(g)+4CI(g) and calculate bond enthalpy of C-Cl in C Cl_(4)(g). Delta_("vap")H^(theta)("C C"l_(4))=30.5 kJ mol^(-1) . Delta_(f)H^(theta)(CCl_(4))=-135.5 kJ mol^(-1) . Delta_(0)H^(theta)(C)=715.0 kJ mol^(-1) , where Delta_(a)H^(theta) is enthalpy of atomisation. Delta_(a)H^(theta)(Cl_(2))=242 kJ mol^(-1) .

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

Calculate Delta_(r)G^(0) for (NH_(4)Cl, s) at 310K. Given: Dleta _(f)H^(0) for (NH_(4)Cl, s) = - 314.5 KJ/mol, Delta_(r ) C_(P) = 0 S_(N_(2)(g))^(0) = 192JK^(-1) mol^(-1), S_(H_(2) (g))^(0) = 130.5 JK^(-1) mol^(-1), S_(Cl_(2)(g))^(0) = 233JK^(-1) mol^(-1), S_(NH_(4)Cl(s))^(0) = 99.5 JK^(-1) mol^(-1) . All given data at 300K