17.3.1 Benzene and Its Derivatives

    Cards (283)

    • Benzene is an organic compound with the chemical formula C_{6}H_{6}
    • All six carbon atoms in benzene lie in the same plane.
    • What type of reactions is benzene resistant to due to its stability?
      Addition
    • Each carbon atom in benzene is bonded to one hydrogen atom.
    • The delocalized electrons in benzene create a stable electron cloud above and below the plane
    • Why is benzene highly stable compared to regular alkenes?
      Delocalization of electrons
    • Kekulé's structure of benzene includes alternating single and double bonds.
    • Kekulé's structure fails to explain why all C-C bond lengths in benzene are equally identical
    • What type of reactions does Kekulé's structure incorrectly suggest benzene should undergo easily?
      Addition
    • What does delocalization of electrons in benzene create?
      Stable electron cloud
    • The delocalization of electrons in benzene contributes to its resistance to addition reactions.
    • Benzene is an aromatic hydrocarbon with the chemical formula C6H6
    • What is the arrangement of the carbon atoms in benzene?
      Cyclic six-carbon ring
    • All carbon atoms in benzene lie in the same plane
    • The delocalized electrons in benzene create an electron cloud above and below the plane of the ring.
    • What property of benzene is enhanced by the delocalization of electrons?
      High stability
    • Kekulé's structure depicts benzene as a six-membered ring with alternating single and double bonds
    • What is one limitation of Kekulé's structure regarding bond lengths in benzene?
      Unequal bond lengths
    • Experimental data shows all C-C bond lengths in benzene are equal, contradicting Kekulé's structure.
    • Kekulé's structure suggests benzene should react like a regular alkene
    • What year did Kekulé propose his structure for benzene?
      1865
    • Electron delocalization in benzene reduces electron density and minimizes repulsion.
    • Delocalization in benzene contributes to its stability through resonance
    • Benzene's stability is enhanced by its delocalized electrons.
    • What contributes to benzene's stability and resistance to addition reactions?
      Delocalized electrons
    • Benzene's delocalized electrons create a stable electron cloud above and below the plane
    • Benzene's delocalized electrons are evenly distributed around the ring.
    • What is the bond length of a C=C double bond in Kekulé's structure of benzene?
      1.34 Å
    • The actual benzene structure has equal C-C bond lengths due to delocalization
    • Kekulé's model correctly predicts that benzene has alternating single and double bonds.
      False
    • What do the resonance structures of benzene represent?
      Delocalized electron arrangements
    • The resonance hybrid of benzene results in uniform C-C bond lengths and enhanced stability
    • What is the chemical formula of benzene?
      C6H6C_{6}H_{6}
    • Benzene has a planar structure with all six carbon atoms in the same plane.
    • Benzene is a cyclic aromatic hydrocarbon with a planar six-carbon ring
    • What creates the stable electron cloud above and below the benzene plane?
      Delocalized electrons
    • Match the feature of benzene with its description:
      Planar Structure ↔️ All carbon atoms lie in the same plane
      Delocalized Electrons ↔️ Create a stable electron cloud
      High Stability ↔️ Resistant to addition reactions
    • What is the chemical formula of benzene?
      C6H6C_{6}H_{6}
    • Electrons in benzene are evenly distributed around the ring, creating a stable electron cloud
    • What contributes to the high stability of benzene?
      Delocalized electrons
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