USING ENGLISH TO PREDICT RENDEMENT OF A REACTION (resume 7)

RENDEMENT OF A REACTION

The chemical rendement, the rendement of the reaction, or rendement refers to the amount of reaction product produced in the chemical reaction. Absolute rendement can be written as weight in grams or in moles (molar yield). The relative yield used as a calculation of the effectiveness of the procedure is calculated by dividing the amount of product obtained in moles by the theoretical yield in moles: 
Fractional yield = actual rendement divided by theoretical rendement 

To obtain a percentage yield, multiply the fractional yield by 100%.One or more reactants in chemical reactions are often used redundantly. The theoretical rendement is calculated based on the number of moles of the limiting reagent. For this calculation, it is usually assumed there is only one reaction involved. The ideal chemical yield value (theoretical rendement) is 100%, a value highly unlikely to be achieved in its practice. Calculate the percent of rendemen that is by using the following equations percent rendemen = weight yield / weight of yield divided by the sample weight multiplied by 100%

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In stoichiometry there is a special note on
Theoretical results, tangible results, and percent of results

• Theoretical results are the amounts calculated from the balanced chemical equations or how many products   are derived based on stoichiometric calculations.
• The real or actual result is the number of results actually generated in a chemical reaction or how many products are obtained after the reaction is complete.
• Efficiency of chemical reaction can be determined through percentage of result or percentage of rendemen that is: Percent of result: (result of real / theoretical result) x 100%

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The efficiency of a chemical reaction can be determined by calculating the percentage of results. Almost in all reactions, we will get fewer results than expected. This happens because most of the reactions are equilibrium reactions (see: Chemical Equilibrium) or because of some reaction conditions that cause the reaction not to run perfectly. Chemists can obtain reaction efficiency by calculating the following percentage of results:Percentage of results = (actual results / theoretical results) x 100% 
The real result is how many products are obtained after the reaction is complete. The theoretical result is how many products are obtained based on stoichiometric calculations. The comparison of these two results provides an explanation of how efficient the reaction is. In the previous example, the theoretical result of ferrous metals was 699.47 grams. While the real result is 525 grams. Therefore, the percentage of the results is: 
% Yield = (525 grams / 699.47 grams) x 100% = 75.05% 

The 75% yield percentage is not a too bad result. Chemical chemists and chemical engineers, however, prefer to earn more than 90%. One industry that uses the Haber Process has a yield percentage greater than 99%.  In some chemical reactions, the reactants provided do not always correspond to their 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 NH3 (g) + 5 O2 (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 the mole to the smallest coefficient is a limiting reagent. 
Mol NH3 = 100 gram / 17,024 gram.mol-1 = 5,874 mol 
Mol NH3 / NH3 coefficient = 5,874 / 4 = 1,468 
Mol O2 = 100 gram / 32.00 gram.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: Mole NO = 5: 4 
Mol NO = 4/5 x Mol O2 = 4/5 x 3.125 mol = 2.5 mol NO
Mass NO = mole NO x Ar NO = 2.5 mole NO x 30.00 gram NO / mol NO = 75.00 gram NO 

The value of 75.00 grams of NO is the theoretical result. If the actual result is 70.00 grams, the percentage of the reaction product is (70.00 gram / 75.00 gram) 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 NH3 stoichiometric ratio to O2 is 4: 5 
Mol O2: Mol NH3 = reaction coefficient O2: The 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 of NH3 
Mass NH3 = mol NH3 x Ar NH3 = 2.5 mol NH3 x 17.024 grams NH3 / mol NH3 = 42.56 grams NH3Thus, the amount of ammonia gas remaining (not used) is as much as 100 grams - 42.56 grams = 57.44 grams.

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Problems example:
If 204 grams of bauxite (Mr. Al2O3 = 102) is perfectly reduced yields 54 grams of aluminum metal (Ar Al = 27). The percentage of Al2O3 in the trailer is ...

Answer:
In this case we are asked to calculate the percentage of Al2O3 in the trailer. This means the trailer is not pure containing 100% bauxite. So, our task in solving this problem is to seek the purity of the bauxite footage. To do this we must also compare FACT with THEORY

FACT : Al periods produced from 204 grams of Al2O3 compounds
THEORY :  mass Al in Al2O3 = (2x27) : 102 = 108 grams

                   % Al2O3 = (fact : theory) x 100% = (54 : 108) x 100% = 50% 

so, result or percentage of rendemen  of Al2O3 is 50%