How to calculate yield chemistry
Yield is an essential concept in the field of chemistry, particularly during chemical reactions. It is the measurement of how much product was successfully produced from a specific chemical reaction compared to the theoretical amount expected. Yield calculations are crucial for understanding chemical reactions’ effectiveness and efficiency, as well as determining the ideal balance of reactants.
In this article, we will explore the different types of yield, the factors affecting yield, and how to calculate yield in chemistry.
Types of Yield
1. Theoretical Yield: This is the maximum amount of product expected in a chemical reaction, assuming complete conversion of reactants into product. It is usually calculated using stoichiometry.
2. Actual Yield: This is the amount of product obtained from a real-life chemical reaction after accounting for factors such as impurities, incomplete reactions, and side reactions.
3. Percentage Yield: This is the ratio between actual yield and theoretical yield. It represents how efficiently a reaction produces its desired product.
Factors Affecting Yield
Several factors affect yield in chemical reactions:
1. Impurities in reactants or contaminants present in experimental setups
2. Reaction conditions such as temperature, pressure, pH level, or concentration
3. The presence of side reactions or other competing processes
4. Experimental set-up and measurement errors
Calculating Yield
To calculate percentage yield, you need to perform three main steps:
1. Determine the balanced chemical equation for your reaction
2. Calculate the theoretical yield using stoichiometry
3. Compare your actual yield with your theoretical yield to determine percentage yield
Step 1: Determine the balanced chemical equation for your reaction
Understanding the balanced chemical equation helps you identify each reactant’s mole ratio to the products formed.
Example:
N2(g) + 3H2(g) → 2NH3(g)
Step 2: Calculate theoretical yield using stoichiometry
Use your balanced chemical equation to determine the limiting reactant and calculate how much product is theoretically produced.
Example:
– You have 50g of N2 and 15g of H2
– Convert these amounts to moles
Moles of N2 = 50g/(28.02 g/mol) = 1.79 mol
Moles of H2 = 15g/(2.02 g/mol) = 7.43 mol
– Determine the limiting reactant by dividing each reactant’s moles by their mole ratio and identifying the lowest value
N2: 1.79 mol / 1 = 1.79
H2: 7.43 mol / 3 = 2.48
Since the N2 value (1.79) is lower than the H2 value (2.48), N2 is the limiting reactant.
– Calculate theoretical yield using the limiting reactant’s moles and the mole ratio
Theoretical yield of NH3: (1.79 mol N2) x (2 mol NH3/1 mol N2) = 3.58 mol NH3
Step 3: Compare actual yield with theoretical yield to determine percentage yield
Now that you have calculated your theoretical yield in moles, compare it with your actual yield.
Example:
– Convert your experimental (actual) yield to moles
Actual Yield of NH3 = ___g /(17.04 g/mol)
– Calculate percentage yield
Percentage Yield = (Actual Yield/Theoretical Yield) × 100%
By following these three steps, you can calculate the various yields and assess a chemical reaction’s efficiency, crucial in both academic settings and industrial applications. Understanding how to calculate yield in chemistry will help you make more informed decisions in developing experiments.