Answer:
Enthalpy change is 6007 J
Entropy change is [tex]20.15\,JK^{-1}[/tex]
Gibb's free energy change is 0 J.
Explanation:
From the given,
The enthalpy change for the melting of ice = [tex]60007\,J\,mol^{-1}[/tex]
Temperature = [tex]25^{0}C[/tex]
Let's convert the temperature centigrade into Kelvin.
[tex]=25^{0}C \,+273.15\,=298.15K[/tex]
Number of moles of ice = 1.00 mol
Enthalpy change of 1.00 mol [tex]25^{0}C[/tex] temperature
[tex]\bigtriangleup H=(1\,mol)(\frac{6007\,J}{mol})[/tex]
Therefore, Enthalpy change ([tex]\bigtriangleup H[/tex]) for the melting of 1.00 mole of ice at [tex]25^{0}C[/tex] temperature is 6007 J.
Entropy change for the melting of 1.00 mole of ice at [tex]25^{0}C[/tex] :
[tex]\Delta S_{sys}\,=\frac{\Delta H}{T}[/tex]
[tex]=\,\frac{6007\,J}{298.15\,K}\,=20.15\,JK^{-1}[/tex]
Therefore, Entropy change([tex]\Delta S_{sys}[/tex]) for the melting of 1.00 mole of ice at [tex]25^{0}C[/tex] temperature is [tex]20.15\,JK^{-1}[/tex].
The Gibb's free energy change is expressed by the following formula.
[tex]\Delta G^{o}\,=\Delta H^{o}-T\bigtriangleup S[/tex]
[tex]=\,6007\,J-(298.15\,K)(20.15\,J\,K^{-1})[/tex]
[tex]=6007\,J-6007\,J=\,0J[/tex]
Therefore, Gibb's free enrgy change ([tex]\Delta G^{o} [/tex]) for the melting of 1.00 mole of ice at [tex]25^{0}C[/tex] temperature is [tex]0J[/tex]
