An organic class known as conjugated ketones is defined by the presence of a carbonyl group (C=O) sandwiched between two carbon-carbon double bonds. These unusual double and single bond arrangements result in intriguing chemical characteristics and reactivity. These ketones are unique from regular ketones in that they have a conjugated
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An organic class known as conjugated ketones is defined by the presence of a carbonyl group (C=O) sandwiched between two carbon-carbon double bonds. These unusual double and single bond arrangements result in intriguing chemical characteristics and reactivity. These ketones are unique from regular ketones in that they have a conjugated double bond structure that influences their stability and reactivity. Resonance stabilization is one of the important properties of conjugated ketones. The conjugated system's electron delocalization makes resonance structures possible, allowing the double bonds to move. Compared to non-conjugated ketones, this resonance stabilization leads to less energy and enhanced stability. Because the negative charge produced during the attack can be distributed across the conjugated system, conjugated ketones are therefore less vulnerable to nucleophilic attack at the carbonyl carbon. Conjugated ketones are useful in chemical synthesis due to their reactivity. They easily go through a number of reactions to create complicated compounds with several functional groups, such as Robinson annulations, Aldol condensations, and Michael additions. In the Michael addition, for instance, a nucleophile is added to the conjugated system's β-carbon, creating a new carbon-carbon bond. Moreover, conjugated ketones show intriguing spectroscopic characteristics. Because of the extended conjugation, their UV-Vis spectra frequently exhibit absorption peaks at longer wavelengths than those of non-conjugated ketones. The promotion of electrons from the highest occupied molecular orbital (HOMO) to the lowest unoccupied molecular orbital (LUMO) in the conjugated system is connected to this absorption. Moreover, these ketones may display keto-enol tautomerism, in which the hydrogen on the carbonyl's α-carbon neighboring oxygen atoms can move to produce an enol. Temperature and solvent concentrations can have an impact on the equilibrium between the keto and enol forms, with hydrogen bonds frequently stabilizing the enol form. In conclusion, the conjugated double bond system of conjugated ketones gives them special spectroscopic qualities, stability, and reactivity. These substances are essential to organic synthesis because they open up new avenues for the synthesis of intricate, varied molecules with particular uses.
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