Elemental sulfur occurs as octatomic molecules, \(\mathrm{S}_{8} .\) What mass \((\mathrm{g})\) of fluorine gas is needed to react completely with \(17.8 \mathrm{~g}\) of sulfur to form sulfur hexafluoride?

In chemistry, a balanced chemical equation represents a chemical reaction with equal numbers of each type of atom on both the reactant and product sides. Balancing equations involves adjusting coefficients before compounds to ensure mass conservation.

For the reaction between elemental sulfur and fluorine gas, the balanced chemical equation is:
\[ \mathrm{S}_8 + 24\mathrm{F}_2 \rightarrow 8\mathrm{SF}_6 \]
This equation shows that one molecule of sulfur (\( \mathrm{S}_8 \)) reacts with 24 molecules of fluorine gas (\( \mathrm{F}_2 \)). The result is eight molecules of sulfur hexafluoride (\( \mathrm{SF}_6 \)). Balancing chemical equations ensures that atoms are neither created nor destroyed during the reaction. This step is crucial for accurate stoichiometry calculations.

Molar mass is the mass of one mole of a given substance, typically in grams per mole (g/mol). It is an essential concept in stoichiometry as it allows conversion between mass and moles.

To calculate the molar mass of sulfur (\( \mathrm{S}_8 \)) and fluorine gas (\( \mathrm{F}_2 \)):

• Molar mass of \( \mathrm{S}_8 \): Sulfur has an atomic mass of 32.07 g/mol. One molecule of \( \mathrm{S}_8 \) contains eight sulfur atoms:

\[ 8 \times 32.07 \text{ g/mol} = 256.56 \text{ g/mol} \]
• Molar mass of \( \mathrm{F}_2 \): Fluorine has an atomic mass of 19.00 g/mol. One molecule of \(\mathrm{F}_2\) contains two fluorine atoms:

\[ 2 \times 19.00 \text{ g/mol} = 38.00 \text{ g/mol} \]
Performing these calculations gives the molar mass of the reactants, necessary for converting mass to moles.

Mole-to-mole conversion is used to relate the moles of one substance to the moles of another using the coefficients from the balanced chemical equation.

In this reaction, one mole of \( \mathrm{S}_8 \) requires 24 moles of \( \mathrm{F}_2 \) to react completely.

Based on the balanced equation:
\[ \mathrm{S}_8 + 24\mathrm{F}_2 \rightarrow 8\mathrm{SF}_6 \]
For every mole of sulfur (\( \mathrm{S}_8 \)) reacting, there are 24 moles of fluorine gas (\( \mathrm{F}_2 \)).

If you know the moles of \( \mathrm{S}_8 \) are 0.0694,

• Multiply by the stoichiometric coefficient to find moles of \( \mathrm{F}_2 \):

\[ 0.0694 \text{ moles of } \mathrm{S}_8 \times 24 \text{ moles of } \mathrm{F}_2 \text{ per 1 mole of } \mathrm{S}_8 \approx 1.6656 \text{ moles of } \mathrm{F}_2 \]
This conversion helps us understand the stoichiometric relationship between reactants in the balanced chemical equation.

Mass-to-mole conversion involves calculating the number of moles from a given mass of a substance. This is important for determining reactant or product quantities in chemical reactions.

To find moles of sulfur from the given mass:\( 17.8 \text{ g of } \mathrm{S}_8 \), use the molar mass calculated earlier:

• Molar mass of \( \mathrm{S}_8 \) = 256.56 g/mol

You can find the number of moles by dividing mass by molar mass:
\[ \text{Moles of } \mathrm{S}_8 = \frac{17.8 \text{ g}}{256.56 \text{ g/mol}} \approx 0.0694 \text{ moles} \]
By using this conversion, we can move from a measurable mass to a chemical quantity in moles. From there, we can use mole-to-mole conversion to determine how much fluorine gas is needed for the reaction.