Answer: [tex]2 \cdot CH_{4} O (l)+3 \cdot O_{2}(g) \rightharpoonup 2 \cdot CO_{2}(g) + 4 \cdot H_{2}O(l)[/tex]
Explanation:
Let consider that one mole of diatomic oxygen is used. So, the stoichometric can be modelled by using three variables:
[tex]x \cdot CH_{4} O (l)+O_{2}(g) \rightharpoonup y \cdot CO_{2}(g) + z \cdot H_{2}O(l)[/tex]
Where [tex]x,y,z[/tex] are the required variables.
Now, three equations are constructed from the number of elements involved (Carbon, Hydrogen and Oxygen):
Carbon
[tex]x=y[/tex]
Oxygen
[tex]x+2=2\cdot y + z[/tex]
Hydrogen
[tex]4\cdot x = 2 \cdot z[/tex]
The coefficients can be found by solving the abovementioned 3 x 3 Linear System:
[tex]x = \frac{2}{3}, y = \frac{2}{3}, z = \frac{4}{3}[/tex]
The whole-number coefficients are determined by multiplying every coefficient by 3, then:
[tex]2 \cdot CH_{4} O (l)+3 \cdot O_{2}(g) \rightharpoonup 2 \cdot CO_{2}(g) + 4 \cdot H_{2}O(l)[/tex]
