Aldehydes, bromination halogenation

Thiophene-2-carbaldehyde, 3-bromo-synthesis, 4, 81 Thiophenecarbaldehydes benzothiophene synthesis from, 4, 906 reactions, 4, 807 synthesis, 4, 148 Wittig reactions, 4, 807 Thiophene-2-carb aldehydes bromination, 4, 753 conformation, 4, 33 halogenation, 4, 753 reactions, 4, 72-73 reactivity, 4, 72-73 reduction, 4, 776 Thiophene-3-carb aldehydes conformation, 4, 33 reactivity, 4, 72... 

Replacement of hydrogen with halogen can be carried out in the alpha position of fluorinated ethers, amines, aldehydes, or nitriles In 2,2,3,4,4,4 hexafluoro-bulyl methyl ether, chlorination occurs predominantly at the methyl, however, bromination occurs mostly at the internal position of the fluorobutyl group 133] (equation 20)... 

As in the acid-catalyzed halogenation of aldehydes and ketones, the reaction rate is independent of the concentration of the halogen chlorination, bromination, and iodination all occur at the same rate. Fomnation of the enolate is rate-detemnining, and, once fomned, the enolate ion reacts rapidly with the halogen. 

The halogenation of enamines is formally analogous to protonation with salt formation. Thus the steroidal enamine (164) undergoes bromination (7/5) to give the j8-bromo iminium bromide (165), which is readily hydrolyzed to the /5-bromo aldehyde (166). 

From resonance structure (12) it is obvious that a —I—M-substit-uent strongly deactivates the 2-position toward electrophilic substitution, and one would thus expect that monosubstitution occurs exclusively in the 5-position. This has also been found to be the case in the chlorination, bromination, and nitration of 3-thiophenecarboxylic acid. Upon chlorination and bromination a second halogen could be introduced in the 2-position, although further nitration of 5-nitro-3-thiopheneearboxylic acid could not be achieved. Similarly, 3-thiophene aldehyde has been nitrated to 5-nitro-3-thiophene aldehyde, and it is further claimed that 5-bromo-3-thiopheneboronic acid is obtained upon bromination of 3-thiopheneboronic acid. ... 

A particularly common cr-substitution reaction in the laboratory is the halogenation of aldehydes and ketones at their a- positions by reaction with Cl2, Br2, or I2 in acidic solution. Bromine in acetic acid solvent is often used. 

In the haloform reaction, methyl ketones (and the only methyl aldehyde, acetaldehyde) are cleaved with halogen and a base. The halogen can be bromine, chlorine, or iodine. What takes place is actually a combination of two reactions. The first is an example of 12-4, in which, under the basic conditions employed, the methyl group is trihalogenated. Then the resulting trihalo ketone is attacked by hydroxide ion ... 

The introduction of chlorine or bromine into a saturated chain is facilitated by the presence of a C 0-group. Thus, aldehydes and ketones are halogenated with great ease, the halogen entering exclusively in the a-position. It has been shown that in this process the enol-form, which is present in minute amounts, takes up bromine additively.1... 

Our observations are summarized as follows (1) no induction period, (2) fast alcohol oxidation in an oxygen-poor liquid phase, (3) no carboxylic acids from the higher alcohols, (4) slow oxidation of lauryl aldehyde to lauric acid in the presence of water, and (5) recovery of bromine in the organic phase on reaction completion. These data show that the reaction is not a radical chain process but rather a bromine oxidation in which the halogen is continuously regenerated, as shown in Reactions 1 through 7. 

Furthermore, direct halogenation sometimes leads to substitution in the C-residue of the aldehyde hydrazone. For example, hydrazonoyl bromide 28c was obtained by direct bromination of hydrazone 58a or 58b (75CJC1484). Electron-withdrawing substituents in the N-aryl moiety of the arylhydrazone derivatives of heterocyclic aldehydes inhibit ring bromi-... 

The first conversion is the a halogenation of an aldehyde. As described in Section 18.2, this particular conversion has been achieved in 80% yield simply by treatment with bromine in chloroform. 

Anthraquinone synthesis.1 The original anthraquinone synthesis (10, 75) from benzamides and benzaldehydes involving a tandem orf/io-lithiation can be improved by use of an ort/to-bromobenzaldehyde as the second component. In this version, the second lithiation involves halogen-metal exchange, which results in higher yields. In the example cited here, the yield was only 15% in the absence of the bromine substituent on the aldehyde. 

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