Free Radicals

Professor Dave Explains

4 Jan 201508:14

Summary

TLDRIn this video, Professor Dave introduces the concept of free radical chemistry, explaining the nature of unpaired electrons in radicals, their sp2 hybridization, and trigonal planar geometry. He compares the stability of carbon radicals to carbocations, noting that more substituted radicals are more stable. The video also covers how radicals form through homolytic bond cleavage, promoted by energy like UV light. Additionally, the three main steps in radical reactions—initiation, propagation, and termination—are explained, emphasizing their thermodynamic characteristics. The video offers a foundational understanding of free radical reactions.

Takeaways

🌀 Free radicals are species with unpaired electrons, often formed via homolytic bond cleavage.
📐 A carbon radical is sp2 hybridized and has a trigonal planar geometry, similar to a carbocation.
⚖️ Carbon radicals are neutral but electron-deficient, and their stability increases with substitution, much like carbocations.
🌟 Hyperconjugation from neighboring alkyl groups stabilizes carbon radicals, with allylic radicals being the most stable due to resonance.
🔥 Homolytic bond cleavage occurs when two electrons in a bond split evenly, forming radicals, often promoted by heat or UV light.
💡 Oxygen-oxygen and halogen-halogen bonds are particularly prone to homolysis under specific conditions, like exposure to UV light.
🔄 Radical reactions typically have three stages: initiation, propagation, and termination.
⚡ The initiation step is always endothermic, requiring energy input (heat or light) to break bonds and form radicals.
🔗 Propagation steps involve radicals reacting with covalent species to form new radicals and covalent bonds. These steps can be either endothermic or exothermic.
❄️ The termination step is always exothermic, as two radicals combine to form a stable covalent bond, lowering the system's energy.

Q & A

What is a free radical in chemistry?
-A free radical is a molecule or atom with an unpaired electron, making it highly reactive. Unlike most atoms with paired electrons in covalent bonds or lone pairs, free radicals have one unpaired electron.
How is the geometry of a carbon radical described?
-A carbon radical is sp2 hybridized and has a trigonal planar geometry, similar to a carbocation, due to the missing fourth electron domain.
Why are more substituted carbon radicals more stable?
-More substituted carbon radicals are more stable due to hyperconjugation, where neighboring alkyl groups help stabilize the electron deficiency, similar to the stability trend in carbocations.
What makes allylic radicals particularly stable?
-Allylic radicals are stable because they can participate in resonance, allowing the unpaired electron to be delocalized across multiple atoms, which lowers the overall energy of the system.
What is the difference between heterolytic and homolytic bond cleavage?
-In heterolytic bond cleavage, both electrons from a bond go to one atom, creating a cation and an anion. In homolytic cleavage, each atom takes one electron from the bond, resulting in two free radicals.
What promotes homolytic bond cleavage?
-Homolytic bond cleavage is promoted by UV light or heat, which excites an electron from the bonding orbital into the antibonding orbital, reducing the bond order to zero and causing bond dissociation.
What are the three main steps of a radical reaction?
-The three steps are initiation (formation of radicals), propagation (radicals react with covalent species to form new radicals), and termination (two radicals combine to form a covalent bond).
Why is the initiation step always endothermic?
-The initiation step is always endothermic because energy, often from heat or UV light, must be absorbed to break the covalent bond and form radicals.
What determines whether a propagation step is endothermic or exothermic?
-Whether a propagation step is endothermic or exothermic depends on the bond energies involved. The overall enthalpy change depends on the bonds being broken and formed.
Why is the termination step always exothermic?
-The termination step is always exothermic because two high-energy radicals combine to form a stable covalent bond, releasing energy and lowering the system’s energy.