The reaction is endergonic.
First, we need to determine the Gibbs free energy function ([tex]\Delta G_{o}[/tex]), in kilojoules, of the entire reaction by this formula:
[tex]\Delta G_{o} = \Sigma\limits_{j=1}^{m} n_{j}\cdot g_{o, j} - \Sigma\limits_{i=1}^{p}n_{i}\cdot g_{o,i}[/tex] (1)
Where:
From thermochemical tables we have the following information:
Reactives
[tex]g_{glu} = -2871596\,\frac{kJ}{kmol}[/tex], [tex]g_{O_{2}} = 0\,\frac{kJ}{kmol}[/tex]
[tex]n_{glu} = 1\,kmol[/tex], [tex]n_{O_{2}} = 6\,kmol[/tex]
Products
[tex]g_{CO_{2}} = -137150\,\frac{kJ}{kmol}[/tex], [tex]g_{H_{2}O} = -237180\,\frac{kJ}{kmol}[/tex]
[tex]n_{CO_{2}} = 6\,kmol[/tex], [tex]n_{H_{2}O} = 6\,kmol[/tex]
Now we proceed to determine the Gibbs free energy function and later determine the nature of the thermochemical reaction:
[tex]\Delta G_{o} = (6\,kmol)\cdot \left(-137150\,\frac{kJ}{kmol} \right) + (6\,kmol)\cdot \left(-237180\,\frac{kJ}{kmol} \right)-(1\,kmol)\cdot \left(-2871596\,\frac{kJ}{kmol} \right) - (6\,kmol)\cdot \left(0\,\frac{kJ}{kmol} \right)[/tex]
[tex]\Delta G_{o} = 625616\,kJ[/tex]
The Gibbs free energy function of the entire reaction is 625616 kilojoules.
The Gibbs free energy function has a positive sign, which means that this reaction is endergonic.
To learn more on Gibbs free energy, we kindly invite to check this verified question: https://brainly.com/question/9552459
