Introduction to Chemical Engineering Processes/Why use mole balances?

Up until now, all of the balances we have done on systems have been in terms of mass. However, mass is inconvenient for a reacting system because it does not allow us to take advantage of the stoichiometry of the reaction in relating the relative amounts of reactants and of products.

Stoichiometry is the relationship between reactants and products in a balanced reaction as given by the ratio of their coefficients. For example, in the reaction:

${\displaystyle C_2{H}_2+2H_2\to C_2{H}_6}$

the reaction stoichiometry would dictate that for every one molecule of ${\displaystyle C_2{H}_2}$ (acetylene) that reacts, two molecules of ${\displaystyle H_2}$ (hydrogen) are consumed and one molecule of ${\displaystyle C_2{H}_6}$ are formed. However, this does not hold for grams of products and reactants.

Even though the number of molecules in single substance is proportional to the mass of that substance, the constant of proportionality (the molecular mass) is not the same for every molecule. Hence, it is necessary to use the molecular weight of each molecule to convert from grams to moles in order to use the reaction's coefficients.

We can write balances on moles like we can on anything else. We'll start with our ubiquitous general balance equation:

${\displaystyle Input-Output=Accumulation-Generation}$

As usual we assume that accumulation = 0 in this book so that:

${\displaystyle Input-Output+Generation=0}$

Let us denote molar flow rates by ${\displaystyle \dot{n}}$ to distinguish them from mass flow rates. We then have a similar equation to the mass balance equation:

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The same equation can be written in terms of each individual species.

There are a couple of important things to note about this type of balance as opposed to a mass balance:

1. Just like with the mass balance, in a mole balance, a non-reactive system has ${\displaystyle n_{gen}=0}$ for all species.
2. Unlike the mass balance, the TOTAL generation of moles isn't necessarily 0 even for the overall mole balance! To see this, consider how the total number of moles changes in the above reaction; the final number of moles will not equal the initial number because 3 total moles of molecules are reacting to form 1 mole of products.

Why would we use it if the generation isn't necessarily 0? We use the molecular mole balance because if we know how much of any one substance is consumed or created in the reaction, we can find all of the others from the reaction stoichiometry. This is a very powerful tool because each reaction only creates one new unknown if you use this method! The following section is merely a formalization of this concept, which can be used to solve problems involving reactors.

In order to formalize the previous analysis of reactions in terms of a single variable, let us consider the generic reaction:

${\displaystyle aA+bB\to cC+dD}$

The Molar Extent of Reaction X is defined as:

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Since all of these are equivalent, it is possible to find the change in moles of any species in a given reaction if the extent of reaction X is known.

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The following example illustrates the use of the extent of reaction.

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The mole balance written above can be written in terms of extent of reaction if we notice that the ${\displaystyle \mathrm{\Delta }n(A)}$ term defined above is exactly the number of moles of a generated or consumed by the reaction.

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Therefore we can write that:

${\displaystyle n_{A,gen}=\mathrm{\Delta }n(A)=-X*a}$

where X is the molar extent of reaction and a is the stoichiometric coefficient of A. Plugging this into the mole balance derived earlier, we arrive at the molecular mole balance equation:

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