1 Answer

Allyraza · Answer 1 · 2020-03-03T15:25:33+0000

Step-by-step explanation:

The given data is as follows.

T = 298 K,
$\Delta H^(o)$ = -5645 kJ/mol

$\Delta G^(o)$ = -5798 kJ/mol

Relation between
$\Delta H$ and
$\Delta G$ are as follows.

$\Delta G^(o)$ =
$\Delta H^(o) - T \Delta S^(o)$

-5798 kJ/mol = -5645 kJ/mol -
$298 * \Delta S^(o)$

-153 kJ/mol = -
$298 * \Delta S^(o)$

$\Delta S^(o)$ = 0.513 kJ/mol K

Now, temperature is
37^(o)C = (37 + 273) K = 310 K

Since,
$\Delta G$ =
$\Delta H^(o) - T \Delta S^(o)$

=
-5645 kJ/mol - 310 K * 0.513 kJ/mol K

= (-5645 kJ/mol - 159.03 kJ/mol)

= -5804.03 kJ/mol

As, change in Gibb's free energy = maximum non-expansion work

$\Delta G = \Delta G_(310 K) - \Delta G_(298 K)$

= -5804.03 kJ/mol - (-5798 kJ/mol)

= -6.03 kJ/mol

Therefore, we can conclude that the additional non-expansion work is -6.03 kJ/mol.

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