Connect with a community that values knowledge and expertise on IDNLearn.com. Our experts provide prompt and accurate answers to help you make informed decisions on any topic.

From the following balanced equation,

[tex]\[ 4 NH_3(g) + 5 O_2(g) \longrightarrow 4 NO(g) + 6 H_2O(g) \][/tex]

how many grams of [tex]\[ H_2O \][/tex] can be formed when [tex]\[ 6.12 \, \text{g} \, NH_3 \][/tex] reacts with [tex]\[ 3.78 \, \text{g} \, O_2 \][/tex]?

Select the correct answer below:

A. 9.71 g
B. 3.78 g
C. 6.12 g
D. 2.55 g


Sagot :

To solve the problem of how many grams of [tex]\( H_2O \)[/tex] can be formed when [tex]\( 6.12 \)[/tex] g of [tex]\( NH_3 \)[/tex] reacts with [tex]\( 3.78 \)[/tex] g of [tex]\( O_2 \)[/tex], follow these steps:

1. Calculate the molar masses:
- Molar mass of [tex]\( NH_3 \)[/tex] (Ammonia): [tex]\( 14.01 (\text{N}) + 3 \times 1.01 (\text{H}) = 17.03 \)[/tex] g/mol
- Molar mass of [tex]\( O_2 \)[/tex] (Oxygen): [tex]\( 2 \times 16.00 (\text{O}) = 32.00 \)[/tex] g/mol
- Molar mass of [tex]\( H_2O \)[/tex] (Water): [tex]\( 2 \times 1.01 (\text{H}) + 16.00 (\text{O}) = 18.02 \)[/tex] g/mol

2. Convert given masses to moles:
- Moles of [tex]\( NH_3 \)[/tex]: [tex]\( \frac{6.12 \, \text{g}}{17.03 \, \text{g/mol}} \approx 0.359 \, \text{mol} \)[/tex]
- Moles of [tex]\( O_2 \)[/tex]: [tex]\( \frac{3.78 \, \text{g}}{32.00 \, \text{g/mol}} \approx 0.118 \, \text{mol} \)[/tex]

3. Determine the stoichiometric ratios from the balanced equation:
[tex]\[ 4 \, NH_3 + 5 \, O_2 \rightarrow 4 \, NO + 6 \, H_2O \][/tex]
- According to the equation, 4 moles of [tex]\( NH_3 \)[/tex] produce 6 moles of [tex]\( H_2O \)[/tex].
- According to the equation, 5 moles of [tex]\( O_2 \)[/tex] produce 6 moles of [tex]\( H_2O \)[/tex].

4. Calculate the moles of [tex]\( H_2O \)[/tex] produced by each reactant:
- From [tex]\( NH_3 \)[/tex]: [tex]\( 0.359 \, \text{mol} \, NH_3 \times \frac{6 \, \text{mol} \, H_2O}{4 \, \text{mol} \, NH_3} \approx 0.539 \, \text{mol} \, H_2O \)[/tex]
- From [tex]\( O_2 \)[/tex]: [tex]\( 0.118 \, \text{mol} \, O_2 \times \frac{6 \, \text{mol} \, H_2O}{5 \, \text{mol} \, O_2} \approx 0.141 \, \text{mol} \, H_2O \)[/tex]

5. Identify the limiting reactant:
- The limiting reactant is [tex]\( O_2 \)[/tex] because it produces fewer moles of [tex]\( H_2O \)[/tex].

6. Calculate the mass of [tex]\( H_2O \)[/tex] formed:
- Moles of [tex]\( H_2O \)[/tex] from the limiting reactant: [tex]\( 0.141 \, \text{mol} \)[/tex]
- Mass of [tex]\( H_2O \)[/tex]: [tex]\( 0.141 \, \text{mol} \times 18.02 \, \text{g/mol} \approx 2.55 \, \text{g} \)[/tex]

So, the correct answer is:

[tex]\[ \boxed{2.55 \, \text{g}} \][/tex]