Using listed informations, calculate `Delta_(r)G^(@)` (in kJ/mol) at `27^(@)C` `Co_(3)O_(4)(s)+4CO(g)rarr3Co(s)+4CO_(2)(g)` Given : At 300 K `DeltaH_(f)^(@)(kJ//mol)-891,-110.5,0.0,-393.5` `S^(@)(J//K-mol)102.5, 197.7, 30.0, 213.7`
Calculate Delta_(r) H^(@) for Fe_(2) O_(3) (s) + 3 CO(g) to 2 Fe (s) + 3 CO_(2) (g) Given : Delta_(f) H^(@) (Fe_(2) O_(3) , s) = -822.2 kJ/mol Delta_(f) H^(@) (CO , g) = -110.5 kJ//mol , Delta_(f) H^(@) (CO_(2) , g) = -393.5 kJ/mol
Calculate the standard enthalpy of reaction ZnO(s)+CO(g)rarrZn(s)+CO_(2)(g) Given, Delta H_(f)(ZnO,s)=-350KJ//"mole",DeltaH_(f)^(@)(CO_(2),g)= -390KJ//"mole", DeltaH_(f)^(@)(CO,g)=-110KJ//"mole"
Determine the enthalpy of formation of B_(2)H_(6) (g) in kJ/mol of the following reaction : B_(2)H_(6)(g)+3O_(2)(g)rarrB_(2)O_(3)(s)+3H_(2)O(g) , Given : Delta_(r )H^(@)=-1941 " kJ"//"mol", " "DeltaH_(f)^(@)(B_(2)O_(3),s)=-1273" kJ"//"mol," DeltaH_(f)^(@)(H_(2)O,g)=-241.8 " kJ"//"mol"
Calculate Delta_(f)H^(@) for the reaction, CO_(2)(g) + H_(2)(g) to CO(g) + H_(2)O(g) Given that Delta_(f)H^(@) for CO_(2)(g) , CO(g) and H_(2)O(g) are -393.5, -111.3 and -241.8 kJ mol^(-1) respectively.
Calculate Delta_(f)H^(@) (in kJ/mol) for Cr_(2)O_(3) from the Delta_(r)G^(@) and the S^(@) values provided at 27^(@) 4Cr(s)+3O_(2)(g)rarr2Cr_(2)O_(3)(s)," "Delta_(r)G^(@)=-2093.4kJ//mol S^(@)("J//K mol") : S^(@)(Cr,s)=24," "S^(@)(O_(2),g)=205," "S^(@)(Cr_(2)O_(3),s)=81
Compute the standard free energy of the reaction at 27^(@)C for the combustion of methane using the given data. CH_(4)(g)+2O_(2)(g)to CO_(2)(g)+2H_(2)O(l) {:("Species",CH_(4),O_(2),CO_(2),H_(2)O),(Delta_(f)H^(@)//(kJ mol^(-1)),-74.8,-,-393.5,-285.8),(S^(@)//(JK^(-1)mol^(-1)),186,205,214,70):}
DeltaH for CaCO_(3)(s)rarrCaO(s)+CO_(2)(g) is 176 kJ mol^(-1) at 1240 K . The DeltaE for the change is equal to
NARENDRA AWASTHI-THERMODYNAMICS-Level 3 - Match The Column
