Answer:
a. Oβ is limiting reactant
b. 5.68g PβOββ are produced
c. 5.83g PβOβ are left in the reaction container
Explanation:
Based in the first reaction,
Pβ + 3Oβ β PβOβ
1 mole of Pβ reacts with 3 moles of oxygen
Initial moles of Pβ and Oβ are:
Moles Pβ (Molar mass: 124g/mol):
5.77g Pβ * (1mol / 124g) = 0.0465 moles Pβ
Moles Oβ (32g/mol):
5.77g Oβ * (1mol / 32g) = 0.180 moles Oβ
For a complete reaction of 0.0465 moles Pβ are required:
0.0465 moles Pβ * (3 moles Oβ / 1 mol Pβ) = 0.140 moles of Oβ
That means will remain 0.040 moles of Oβ and there are produced 0.0465 moles of PβOβ
For the second reaction:
PβOβ + 2Oβ β PβOββ
2 moles of oxygen reacts per mole of PβOβ
For a complete reaction of PβOβ are required:
0.0465 moles PβOβ * (2 moles Oβ / 1mol PβOβ) = 0.093 moles of Oβ. As there are just 0.040 moles of Oβ,
a. Oβ is limiting reactant
b. There are produced:
0.040 moles Oβ * (1 mole PβOββ / 2 moles Oβ) = 0.020 moles PβOββ
In mass (Molar mass: 284g/mol):
0.020 moles * (284g / mol) =
5.68g PβOββ are produced
c. Also, 0.020 moles PβOβ are reacting and will remain:
0.0465 mol - 0.020 mol = 0.0265 moles PβOβ
In mass (Molar mass: 220g/mol):
0.0265 moles PβOβ * (220g / mol) =
5.83g PβOβ is left in the reaction container
