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Have you ever baked a cake? You probably followed a recipe. Recipes can be very precise - combine 100g of this with two teaspoons of that, stir three times, and bake for exactly 22 minutes. They walk you through the process of baking, one step at a time. It's not just as simple as throwing everything into a bowl and hoping…
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Jetzt kostenlos anmeldenHave you ever baked a cake?
You probably followed a recipe. Recipes can be very precise - combine 100g of this with two teaspoons of that, stir three times, and bake for exactly 22 minutes. They walk you through the process of baking, one step at a time. It's not just as simple as throwing everything into a bowl and hoping for the best!
Recipes are to baking as reaction mechanisms are to chemistry. All organic reactions have various steps that the overall equation simply doesn't show. However, with reaction mechanisms, we can peel apart a reaction to see its inner workings and go through it step-by-step.
At the start of this article, we introduced you to the idea of reaction mechanisms.
A reaction mechanism is a step-by-step description of the changes involved in a chemical reaction.
You can think of reaction mechanisms as instructions for building a new chemical molecule. It might involve dismantling an old one and putting the pieces back together, or perhaps combining lots of smaller molecules into one larger one, or maybe just simply swapping one functional group for another. However, these aren't instantaneous processes. They all involve lots of smaller steps that aren't normally visible to the eye. Reaction mechanisms break down the process and show you each step along the way.
Reaction mechanisms usually involve diagrams. These show a few things.
Intermediates are highly reactive, short-lived compounds that exist for a fraction of a second in a chemical reaction. Once formed, they quickly react and turn into more stable compounds.
If we go back to our baking analogy, the reactants are like the basic ingredients of the cake: flour, butter, and sugar. The products are, of course, the finished cake. Each step in the reaction is akin to another instruction in the recipe - weigh the flour out, beat the butter and sugar together. At the end of each instruction, you've created something new, something that's different from your starting ingredients, but will change again before it becomes your finished cake. This represents your intermediates. Intermediates are simply species made in the process of the reaction which then change into something else.
We now know what a reaction mechanism is. But how exactly do you show one?
There are a few key ideas that you need to know when it comes to drawing reaction mechanisms. We explore these ideas in much more detail in Drawing of Reaction Mechanisms, but we'll summarise the main points now:
Reaction mechanisms can seem a little tricky. You might wonder how you will ever remember all the different movements of electrons, but in actual fact, reaction mechanisms can be grouped into a few different categories. Once you know the basic mechanism, it is easy to apply it to a specific reaction. These kinds of reactions include:
We'll walk you through an example of each. However, you can always check out Nucleophilic Substitution Reactions, Reactions of Alkenes, and Elimination Reactions respectively, for more detailed explanations of these terms and concepts. We'll then consider the difference between nucleophilic and electrophilic reactions.
Substitution reactions are reactions in which an atom or functional group in a molecule is replaced by a different atom or functional group.
In substitution reactions, a molecule is attacked by a particular species. This species replaces a different atom or functional group on the original molecule. An example of a substitution reaction is the reaction between bromoethane (CH3CH2Br) and a hydroxide ion (OH-). In this case, the hydroxide ion replaces the bromine atom, resulting in a bromide ion and an organic compound with a hydroxyl group. Here's the mechanism.
The hydroxide ion has a lone pair of electrons. This lone pair of electrons attacks bromoethane’s partially positive carbon atom. The electrons are transferred from the hydroxide ion, and used to make a new covalent bond between the carbon atom and the hydroxide ion. Their movement is shown using a curly arrow. At the same time, the C-Br bond breaks and the electron pair is transferred to the bromine atom, forming a bromide anion (Br-). Once again, electron movement is shown using a curly arrow.
Note that the bromide ion also has a lone pair of electrons, represented by two dots.
Addition reactions are reactions in which two molecules combine to form one larger molecule, with no other products. They involve breaking a double or triple bond.
In addition reactions, a double or triple bond breaks and the electron pair is used to form a single covalent bond with another species. An example is reacting an alkene such as ethene (CH2CH2) with hydrogen bromide (HBr). Here's the mechanism.
In the first step, one of the electron pairs involved in ethene's C=C double bond attacks the partially charged hydrogen atom in hydrogen bromide. This forms a C-H single bond and leaves behind both an organic molecule with a positive carbon ion, called a carbocation, and a bromide ion (Br-). In the second step, the bromide ion adds to the carbocation, using its lone pair of electrons to form a single covalent bond. This forms bromoethane (CH3CH2Br).
Elimination reactions are reactions in which two substituents are removed from a larger molecule. The substituents come together to form a smaller molecule.
In elimination reactions, two smaller species are removed from a larger molecule. These species generally react together to form a new product, and a double bond forms in the initial larger molecule. They are the reverse of addition reactions.
We already looked at the reaction between bromoethane and the hydroxide ion as a substitution reaction, but under different conditions, it can actually be an elimination reaction. This produces ethene, water, and a bromide ion. Take a look at the reaction mechanism:
One of ethene's hydrogen atoms is first attacked by the hydroxide ion. The hydroxide ion uses its lone pair of electrons to form a bond with hydrogen, producing water; the repsective C-H bond breaks and its electrons are used to turn an adjacent C-C single bond into a C=C double bond. This causes the C-Br bond to break heterolytically. The pair of electrons from this bond is transferred to the bromine atom, which is released as a bromide ion.
In organic chemistry, you might also come across these further types of reaction.
Head over to Redox to learn more about oxidation and reduction reactions.
You might have noticed in some of our examples above that we used terms such as nucleophilic and electrophilic. For example, the substitution of bromoethane was a nucleophilic reaction, whilst the addition of ethene was an electrophilic reaction. What do these words mean?
Well, they refer to the type of species responsible for the reaction. In nucleophilic reactions, the targeted organic molecule is attacked by a nucleophile, whilst in electrophilic reactions, the organic molecule is attacked by an electrophile.
Nucleophiles are electron pair donors. On the other hand, electrophiles are electron pair acceptors.
You should now feel confident at drawing and interpreting reaction mechanisms for a variety of different reactions. But why are reaction mechanisms important?
As we explored earlier, reaction mechanisms are step-by-step guides to a chemical reaction. They offer the following benefits:
Are you ready to learn more? For those of you wanting to stretch your understanding, we're now going to take a deep dive into how reaction mechanisms relate to the rate of reaction, and the order of a reaction.
Reaction mechanisms show the individual steps of a chemical reaction. Each step is called an elementary process, or elementary step, and represents a geometric change in the molecules involved in the reaction. You can think of an overall chemical reaction as a sequence of multiple elementary processes.
Elementary processes can be uni-, bi- or termolecular, depending on how many molecules they involve.
Termolecular elementary processes are relatively rare. For a reaction to occur, molecules need to collide at just the right time, with enough energy, and just the right orientation. It's quite uncommon for two molecules to do this, let alone three!
So, how do elementary processes relate to rate equations?
In Rate Equations, we explored what a rate equation is: an equation showing how the rate of a chemical reaction depends on the concentration of certain species. Reactions all have a rate-determining step. In other words, they have a rate-determining elementary process. This is the slowest part of a reaction, and all the species involved in elementary processes up to and including this step feature in the rate equation. Rate laws can be determined for each elementary process, showing how the rate of each step depends on a particular species.
The combined rate laws of all of the steps up to and including the rate-determining elementary process make up the rate equation. If we are given information about a rate equation and a reaction mechanism, we can work out the rate-determining step of a reaction, and vice versa.
Here's a handy table showing how elementary processes and rate laws are linked for three imaginary species. Let's call them A, B, and C, and we'll name the product D.
Type of elementary process | Equation | Rate law |
Unimolecular | k = [A] | |
Bimolecular | k = [A]2 | |
k = [A] [B] | ||
Termolecular | k = [A]3 | |
k = [A]2 [B] | ||
k = [A] [B] [C] |
Here's the rate equation for the reaction:
k = [H2] [ICl]
You'll notice that the rate equation for this reaction doesn't involve all of the molecules present in the overall equation. In fact, it only features one molecule of hydrogen (H2) and one molecule of iodine monochloride (ICl). This means that the only species that feature in the steps up to and including the rate-determining elementary process are one molecule of hydrogen, and one molecule of iodine monochloride. We can therefore predict that the overall reaction mechanism has two distinct steps.
In the first step, one molecule of hydrogen and one molecule of iodine monochloride react to form an intermediate and hydrogen chloride (HCl):
In the second step, the intermediate reacts with another molecule of iodine monochloride to form hydrogen chloride and iodine (I2):
Another example is the reaction between nitrogen dioxide (NO2), and carbon monoxide (CO). It has the following equation and rate equation:
k = [NO2]2
The rate equation features two molecules of nitrogen dioxide, but no molecules of carbon monoxide. We can therefore predict that the reaction again takes place in two distinct steps. The first step involves two molecules of nitrogen dioxide reacting to form nitrogen monoxide (NO) and an intermediate. This must be the rate-determining step, as these two nitrogen dioxide molecules are the only molecules involved in the rate equation. In the second step, the intermediate reacts with carbon monoxide to form nitrogen dioxide and carbon dioxide. You can see this below:
If we combine the two equations, one of the nitrogen dioxide molecules and the intermediate molecule appear on both the left- and the right-hand side, and so don't feature in the reaction's overall equation:
Reaction mechanisms are step-by-step descriptions of the changes involved in a chemical reaction.
You draw reaction mechanisms using displayed formulae, and curly arrows to show the movement of electrons. Make sure to include partial charges, ions, free radicals, and lone pairs of electrons on your diagram.
It can be quite hard to determine reaction mechanisms experimentally because they happen extremely quickly, on a microscopic level. However, techniques include measuring the enthalpy change of the reaction to determine activation energy, measuring the effect of ionic strength on rate of reaction, and detecting the stereochemistry of reactants, products, and intermediates at different stages of the reaction.
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