What is the Difference Between Synthesis Reaction and Substitution Reaction?
🆚 Go to Comparative Table 🆚The main difference between a synthesis reaction and a substitution reaction lies in the process and the resulting products.
Synthesis Reaction:
- A synthesis reaction occurs when two or more elements or compounds combine to form a new compound.
- The general equation for a synthesis reaction is: $$\ce{A + B -> C}$$, where A and B are the reactants, and C is the product.
- The reactants in these reactions are either chemical elements or molecules, and the final product is always a compound or a complex.
- An example of a synthesis reaction is the combination of hydrogen gas and oxygen gas to form water: $$\ce{2H2 + O2 -> 2H2O}$$.
Substitution Reaction:
- A substitution reaction takes place when an element or radical (more reactive) replaces another element in a compound.
- The general equation for a substitution reaction is: $$\ce{A + BC -> B + AC}$$, where A is the element or radical that replaces the element in compound B.
- This type of reaction produces a new compound and a new element.
- An example of a substitution reaction is the reaction between magnesium and copper(II) sulfate, resulting in the formation of magnesium sulfate and copper: $$\ce{Mg + CuSO4 -> Cu + MgSO4}$$.
In summary, a synthesis reaction involves the combination of two or more elements or compounds to form a new compound, while a substitution reaction occurs when an element or radical replaces another element in a compound, producing a new compound and a new element.
On this pageWhat is the Difference Between Synthesis Reaction and Substitution Reaction? Comparative Table: Synthesis Reaction vs Substitution Reaction
Comparative Table: Synthesis Reaction vs Substitution Reaction
Here is a table comparing synthesis reactions and substitution reactions:
| Feature | Synthesis Reaction | Substitution Reaction |
|---|---|---|
| Definition | A chemical reaction in which two or more elements or compounds combine to form a new compound or complex. | A chemical reaction where an element or radical (more reactive) replaces another element in a compound. |
| General Form | $$\ce{A} + \ce{B} \rightarrow \ce{AB}$$. | $$\ce{A} + \ce{BC} \rightarrow \ce{B} + \ce{AC}$$. |
| Example | The combination of hydrogen gas and oxygen gas to form water molecules: $$\ce{2H2 + O2 \rightarrow 2H2O}$$. | The replacement of hydrogen in water by a more reactive element, such as sodium: $$\ce{2Na + 2H2O \rightarrow 2NaOH + H2}$$. |
| Energy Change | Synthesis reactions are exothermic, meaning they release energy during bond formation. | Substitution reactions may be exothermic or endothermic, depending on the specific reaction and the reactivity of the substituent. |
| Reactants | Synthesis reactions involve chemical elements or molecules. | Substitution reactions involve an element or radical (more reactive) reacting with a compound. |
| Products | Synthesis reactions always produce a compound or complex as the final product. | Substitution reactions may produce a new compound or a molecule with a substituted atom or group. |
Read more:
- Addition vs Substitution Reaction
- Elimination vs Substitution Reaction
- Synthesis Reaction vs Dissociation Reaction
- Synthesis vs Retrosynthesis
- Synthesis vs Decomposition
- Analysis vs Synthesis
- Combination vs Decomposition Reaction
- Synthesis vs Biosynthesis
- Hydrolysis vs Dehydration Synthesis
- Free Radical Substitution vs Nucleophilic Substitution
- Electrophilic vs Nucleophilic Substitution
- Composition vs Reaction Stoichiometry
- Homogeneous vs Heterogeneous Reactions
- Free Radical Substitution vs Free Radical Addition
- Catalytic vs Non Catalytic Reaction
- Single Displacement vs Double Displacement Reaction
- Adulteration vs Substitution
- Reactant vs Reagent
- Oxidation Reaction vs Reduction Reaction