Using English to Predict Rendement of Product a Reaction

In chemistry, it is often important to know how efficient a reaction is. This is because when a reaction is carried out, the reactants may not always be present in the proportions written in the balanced equation. As a result, some of the reactants will be used, and some will be left over when the reaction is completed.

Theoretical, Actual, and Percents Yields

A reaction should theoretically produce as much of the product as the stoichiometric ratio of product to the limiting reagent suggests. This number can be calculated and is called the theoretical yield. However, the amount of product actually produced by the reaction will usually be less than the theoretical yield and is referred to as the actual yield. This is because often reactions have "side reactions" that compete for reactants and produce undesired products.

To evaluate the efficiency of the reaction, chemists compare the theoretical and actual yields by calculating the percent yield of a reaction:

Percent yield = (actual yield/theoretical yield) ×100

To calculate percent yield using this equation, it is not necessary to use a particular unit of measurement (moles, mL, g etc.), but it is important that the two values being compared are consistent in units. The theoretical yield of a reaction is 100 percent, but this value becomes nearly impossible to achieve due to limitations.

To accurately calculate the yield, the equation needs to be balanced. Next, identify the limiting reagent. Then the theoretical yield of the product can be determined and, finally, compared to the actual yield. Then, percent yield can be calculated.

Example: In some chemical reactions, the provided reactant does not always correspond to its stoichiometric ratio. This means, we will run out of one of the reactants and still leave another reactant. The former reactant is known as a limiting reagent. The limiting reagent determines the amount of product to be produced by a chemical reaction. Here we will discuss how to determine the limiting reagents through the following example:

4 NH_3(g) +  5 O_2(g) →  4 NO_(g) +  6 H₂O_(l)

We start with 100 grams of ammonia gas which is reacted with 100 grams of oxygen gas. Which reactants are limiting reagents? How many grams of nitrogen monoxide (NO) gas can be produced?

To determine which reactants are limiting reagents, we can use a ratio (mole ratio) to the reaction coefficient. We calculate the number of moles each and then divide by their respective reaction coefficients based on equations of equalizing chemical reactions. The ratio of moles to the smallest coefficients is a limiting reagent.

Mol NH₃ = 100 gram/17,024 gram.mol^-1 = 5,874 mol

Mol NH₃/coefficient NH₃ = 5,874/4 = 1,468

Mol O₂ = 100 grams/32,00 grams.mol^-1 = 3,125 mol

Mol O₂/ coefficient O₂ = 3,125/5 = 0,625

The ammonia gas has a ratio of mole to the coefficient of 1.468. Meanwhile, oxygen gas has a value of ratio of 0.625. Thus, oxygen gas is a limiting reagent. The calculation of the product to be produced depends on the oxygen gas mole.

The stoichiometric ratio of NO to O₂ is 4: 5

Mol O₂ :  Mol NO  =  Reaction coefficient O₂ :  Reaction coefficient NO

3,125 : Mol NO = 5 : 4

Mol NO = 4/5 x Mol O₂ = 4/5 x 3,125 mol = 2,5 mol NO

Mass NO = mol NO x Ar NO = 2,5 mol NO x 30,00 grams NO/mol NO = 75,00 grams NO

Value 75,00 grams NO is a theoretical result. If the real result is 70.00 grams, the percentage of the reaction product is equal to (70,00 grams/75,00 grams) x 100 % = 93,33%.

We can also calculate how much ammonia gas is left. The mole gas calculations of ammonia used in the reaction depend on the mole of oxygen gas as a limiting reagent.

The stoichiometric ratio of NH₃ to O_{2 is} 4 : 5

Mol O₂ :  Mol NH₃ =  Reaction coefficient O₂ :  Reaction coefficient NH₃

3,125 : Mol NH₃= 5 : 4

Mol NH₃ = 4/5 x Mol O₂ = 4/5 x 3,125 mol = 2,5 mol NH₃

Mass NH₃ = mol NH₃ x Ar NH₃ = 2,5 mol NH₃ x 17,024 grams NH₃/mol NH₃ = 42,56 grams NH₃

Thus, the amount of ammonia gas remaining (not used) is as much as 100 grams - 42.56 grams = 57.44 grams.