6 Reactions of Alkanes

Tom Iwanowski

30 Jul 201413:07

Summary

TLDRThis educational video delves into the chemical properties of alkanes, a type of hydrocarbon, focusing on their reluctance to react due to high bond enthalpies and low bond polarity. It explains the concept of complete and incomplete combustion, providing equations for both. Additionally, the video explores alkanes' reactions with halogens under UV light, detailing the free radical mechanism involved in these substitution reactions, from initiation to termination, and emphasizing the importance of understanding homolytic fission in the context of these chemical processes.

Takeaways

🔍 Alkanes are part of the homologous series and are characterized by their saturation, meaning they have no double or triple bonds.
🔄 Alkanes are generally unreactive due to their high bond enthalpies and low bond polarity between carbon and hydrogen atoms.
🔥 All hydrocarbons, including alkanes, can undergo combustion, which is a reaction with oxygen, resulting in carbon dioxide and water as products.
🌐 Complete combustion of alkanes involves the formation of carbon dioxide and water, with the number of carbon dioxide molecules equal to the number of carbon atoms and the number of water molecules equal to half the number of hydrogen atoms.
🚫 Incomplete combustion occurs when there is a lack of oxygen, leading to the formation of carbon or carbon monoxide, which is a poisonous gas.
🌞 Alkanes can react with halogens under the influence of bright light, such as UV light, in a process known as a substitution reaction.
💡 The reaction of alkanes with halogens involves a free radical mechanism, starting with the formation of free radicals from the halogen molecules.
🔄 The propagation step in the free radical mechanism involves the reaction of a free radical with an alkane, leading to the formation of new radicals and products.
🔚 The termination step in the free radical mechanism occurs when two radicals collide and react, forming a stable molecule without unpaired electrons.
📚 It is important to understand the concept of homolytic fission, where a bond breaks and each atom retains one electron, leading to the formation of free radicals.

Q & A

What are homologous series in organic chemistry?
-Homologous series refer to a group of organic compounds that have similar chemical properties and a gradation in physical properties, differing by a constant unit, typically a -CH2- group.
Why are alkanes considered saturated hydrocarbons?
-Alkanes are considered saturated hydrocarbons because their molecules contain only single bonds between carbon and hydrogen atoms, meaning they have the maximum number of hydrogen atoms possible for the given number of carbon atoms.
What is the significance of bond enthalpy in the reactivity of alkanes?
-The bond enthalpy, or bond dissociation energy, indicates the strength of a bond. Alkanes have high bond enthalpies, meaning their carbon-hydrogen and carbon-carbon bonds are strong and difficult to break, which contributes to their unreactive nature.
How does bond polarity affect the reactivity of alkanes?
-Bond polarity arises from an electronegativity difference between atoms. Since carbon and hydrogen have similar electronegativities, the bonds in alkanes are nonpolar, and there is an even distribution of electron density, making alkanes less likely to participate in reactions.
What are the products of complete combustion of alkanes?
-In complete combustion, alkanes react with oxygen to produce carbon dioxide (CO2) and water (H2O) as the primary products.
How can you balance the chemical equation for the complete combustion of methane?
-The balanced equation for the complete combustion of methane (CH4) is CH4 + 2O2 → CO2 + 2H2O. The number of carbon dioxide molecules equals the number of carbon atoms, and the number of water molecules equals twice the number of hydrogen atoms in the alkane.
What is incomplete combustion and why does it occur?
-Incomplete combustion occurs when there is insufficient oxygen to fully react with the fuel. This can lead to the formation of carbon monoxide (CO) and carbon (C), which are dangerous due to their toxicity and potential to cause fires.
What are the conditions required for alkanes to react with halogens?
-Alkanes react with halogens under conditions of bright light, specifically ultraviolet (UV) light, which is necessary to initiate the reaction through the formation of free radicals.
What is a free radical mechanism and why is it important in the reaction of alkanes with halogens?
-A free radical mechanism is a chemical reaction that involves the participation of free radicals, which are molecules with unpaired electrons. This mechanism is important in the reaction of alkanes with halogens because it explains the initiation, propagation, and termination steps of the reaction, which would not easily occur due to the unreactive nature of alkanes.
What is the term used to describe the breaking of a bond in a free radical mechanism?
-The term used to describe the breaking of a bond in a free radical mechanism is 'homolytic fission', which results in two free radicals, each with an unpaired electron.
What are the possible products of the reaction between alkanes and halogens, and why are they significant?
-The reaction between alkanes and halogens can produce haloalkanes (e.g., CH3Cl) and hydrogen halides (e.g., HCl). These products are significant because they demonstrate the substitution of hydrogen atoms in alkanes with halogen atoms, and the reaction can lead to various other products depending on the reaction conditions and the presence of radicals.