Organic chemistry Iodoform Reaction












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Why does 2',6'dimethyl-acetophenone not give iodofom test?
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  • 2




    $begingroup$
    A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
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    – Waylander
    11 hours ago












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    It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
    $endgroup$
    – user224359
    11 hours ago






  • 3




    $begingroup$
    Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
    $endgroup$
    – Waylander
    11 hours ago










  • $begingroup$
    @Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
    $endgroup$
    – Zhe
    5 hours ago










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    Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
    $endgroup$
    – Waylander
    5 hours ago
















5












$begingroup$


Why does 2',6'dimethyl-acetophenone not give iodofom test?
enter image description here










share|improve this question











$endgroup$








  • 2




    $begingroup$
    A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
    $endgroup$
    – Waylander
    11 hours ago












  • $begingroup$
    It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
    $endgroup$
    – user224359
    11 hours ago






  • 3




    $begingroup$
    Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
    $endgroup$
    – Waylander
    11 hours ago










  • $begingroup$
    @Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
    $endgroup$
    – Zhe
    5 hours ago










  • $begingroup$
    Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
    $endgroup$
    – Waylander
    5 hours ago














5












5








5


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$begingroup$


Why does 2',6'dimethyl-acetophenone not give iodofom test?
enter image description here










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$endgroup$




Why does 2',6'dimethyl-acetophenone not give iodofom test?
enter image description here







organic-chemistry carbonyl-compounds






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edited 9 hours ago









Waylander

6,60411424




6,60411424










asked 13 hours ago









user224359user224359

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434








  • 2




    $begingroup$
    A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
    $endgroup$
    – Waylander
    11 hours ago












  • $begingroup$
    It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
    $endgroup$
    – user224359
    11 hours ago






  • 3




    $begingroup$
    Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
    $endgroup$
    – Waylander
    11 hours ago










  • $begingroup$
    @Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
    $endgroup$
    – Zhe
    5 hours ago










  • $begingroup$
    Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
    $endgroup$
    – Waylander
    5 hours ago














  • 2




    $begingroup$
    A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
    $endgroup$
    – Waylander
    11 hours ago












  • $begingroup$
    It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
    $endgroup$
    – user224359
    11 hours ago






  • 3




    $begingroup$
    Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
    $endgroup$
    – Waylander
    11 hours ago










  • $begingroup$
    @Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
    $endgroup$
    – Zhe
    5 hours ago










  • $begingroup$
    Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
    $endgroup$
    – Waylander
    5 hours ago








2




2




$begingroup$
A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
$endgroup$
– Waylander
11 hours ago






$begingroup$
A google search for the specific reaction on 2,6-dimethyl acetophenone failed to find an answer. It did find a number of methylacetophenones that do undergo the reaction e.g. 3,4-dimethylacetophenone, 2,4,5-trimethylacetophenone. This review pdfs.semanticscholar.org/4f9f/… notes some acetophenones that do not undergo the reaction (e,g, 2,4,6 tribromoacetophenone). I can see no reason why it would not.
$endgroup$
– Waylander
11 hours ago














$begingroup$
It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
$endgroup$
– user224359
11 hours ago




$begingroup$
It came in an exam.. I also thought it should give the iodoform test but the answer key for the exam said it would the triiodide intermediate but will not give the final compound i.e. CHI_3
$endgroup$
– user224359
11 hours ago




3




3




$begingroup$
Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
$endgroup$
– Waylander
11 hours ago




$begingroup$
Possibly there is too much steric hindrance for the OH- to attack the tri-iodo intermediate. Unless it has been specifically covered in your lectures or textbook this is an unfair question.
$endgroup$
– Waylander
11 hours ago












$begingroup$
@Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
$endgroup$
– Zhe
5 hours ago




$begingroup$
@Waylander We can debate whether or not it's fair, but I think that if the question states that it does not happen and asks for a rationale, that seems totally fair game. I certainly wouldn't want to predict whether or not the reaction happens in the absence of any data.
$endgroup$
– Zhe
5 hours ago












$begingroup$
Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
$endgroup$
– Waylander
5 hours ago




$begingroup$
Depends entirely on the wording of the question. If states it doesn't happen then fair enough, good question. If it is just pick from a list of possible substrates then a very poor question
$endgroup$
– Waylander
5 hours ago










4 Answers
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As @Waylander pointed out, it appears this reaction has not been performed and/or recorded in any literature, so it is quite dangerous to speculate.



But keeping that aside, A 3D perspective reveals that abstraction of protons from the methyl group in quite unhindered.



2',6'-acetophenone



Hence, the triiodo intermediate is well anticipated.
Triiodo substituted product



However, a quick glance at spatial orientation of iodine atoms reveals the reaction may be dead slow in the next step.



Trajectory of incoming hydroxide ion is hindered



Notice that the Burgi-Dunitz trajectory, which we may assume the incoming nucleophile to take, is hindered by the large iodine atoms and the methyl group.



It is quite safe to assume that the attack at the carbonyl carbon is unfavoured, preventing the release of the $ce{CI3-}$, and ultimately $ce{CHI3}$ never appears.






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    I'd agree with Waylander's 2nd comment - hydrolysis to form the carboxylic acid requires formation of the tetrahedral intermediate (from OH- attack on the keton), which the presence of two ortho substituents on the benzene ring doesnt allow, sterically.



    A related effect is that methyl 2,6-dimethylbenzoate doesnt undergo basic hydrolysis by the normal BAc2, since it would involve that same tetrahedral intermediate. Instead it goes via teh BAl2 mechanism (i.e. SN2 attack at the methyl group and rate-determining cleavage of the alkyl, rather than acyl bond).






    share|improve this answer









    $endgroup$





















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      During my mechanisms and named reactions lecture at bachelor’s level, a number of different mechanisms were introduced for transesterification of carboxylic acids and we were required to select the correct mechanism for a given set of reaction partners.



      One of the typical special cases was a 2,6-disubstituted benzoic ester—basically your starting material but with an ester group rather than an acetyl group. It was noted that nucleophilic attack on the carbonyl carbon was not possible as the methyl groups sterically blocked the Bürgi-Dunitz trajectory. Instead, these esterifications would proceed via an acylium cation formed by displacement of the $ce{OR-}$ residue; once the linear acylium cation ($ce{Ph-C#overset{+}{O}}$) was formed, this could be attacked from any angle without the ortho substituents interfering.



      It is likely, as William outlined, that the same problem exists for 2,6-dimethylacetophenone. While there should be no problem replacing the methyl hydrogens with iodides, there is no angle of attack for the hydroxide ion to generate the tetrahedral intermediate.



      In the case of transesterification, the $ce{OR-}$ group is a sufficiently good leaving group so that the acylium cation may form. $ce{CI3-}$ is a much stronger base, so it seems highly unlikely to generate a corresponding acylium in this reaction. In the usual haloform reaction, the regeneration of the $ce{C=O}$ double bond provides a driving force to promote the liberation of $ce{CI3-}$ but that pathway is not possible if an acylium must be generated.






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        There have been a few answers for this question, which make sense on steric hindrance preventing the idoform formation. However, one thing I wouldn’t agree with is almost everybody’s claim of not having literature evidence to support their theory, thus some may categorize this question as just opinion based and chose to close it (regardless how good it is). To avoid that, I’m going to try to give some acceptable literature evidence to support steric hindrance argument.



        Because of original idoform test (introduced by Lieben in 1870) is not reliable for water insoluble compounds, Fuson and Tullock provided improved idoform test in 1934 (Ref.1), which use dioxane as a secondary solvent. They have checked new method with wide variety of compounds that have been analyzed previously with Lieben’s method, but had given mixed results, some of which were misleading. For example, in a majority of these cases, the behavior toward hypoiodite has not been previously reported. Such example is pinacolone, which was previously considered as negative to the test, but given positive result with a longer period of heating (one of the evidence for role of steric hindrance). According to authors, some of the most notable negative results were given by following compounds (Figure 1; Ref. 1 & 2):



        Negative Idoform Test



        Yet, Figure 2 listed the compounds, which have given positive results, but have significant steric hindrance (Ref. 1 & 2):



        Positive Idoform Test



        Most notably, you may compare compounds 5 (negative; Figure 1) vs compound 11 (positive; Figure 2). They both have similar steric hindrance (aromatic $ce{C8-H}$ vs $ce{C3-H}$ is the only difference), yet gives contrary results. Only explanation could be acetic acid group on $ce{C1-O}$ must be cleaved before iodoform formation on compound 11, but similar cleavage on $ce{C2-O}$ of compound 5 is restricted due to its position, since it was known that 1-naphthyloxy group (conjugate base of 1-naphthol) is more stable than 2-naphthyloxy group (conjugate base of 2-naphthol). Same can be told about compound 12 giving positive test. Nonetheless, these results clearly shows that only restriction to give idiform is di-ortho-substitution on the substrate (cf., 1-4; Figure 1), which gives the additional resistance to the formation of final tetrahedral intermediate as pointed by Jan. Meanwhile, mono o-, p-, or m-substitution OR di-o,p-, o,m-, or m,m-substitution does not effect the idoform formation. This fact is stated in Ref.1 as:




        The iodoform reaction is greatly retarded by steric hindrance. The test is negative for all compounds which contain one of the requisite groupings joined to an aryl radical carrying two ortho substituents. As a matter of fact, the reaction is slow, even with pinacolone.




        Even tri-substituted compounds such as compound 8 give positive idoform test as long as two of substitutions were not in di-ortho positions. In their conclusion, Fuson and Tullock provided a generalization to the reaction (Ref.1):




        The test is positive for compounds which contain the grouping $ce{CH3CO}$-, $ce{CH2ICO}$-, or $ce{CHI2CO}-$ when, joined to a hydrogen atom or to a carboy atom which does not carry highly activated hydrogen atoms or groups which provide an excessive amount of steric hindrance. The test will, of course, be positive also for any compound which reacts with the reagent to give a derivative containing one of the requisite groupings. Conversely, compounds which contain one of the requisite groupings will give a negative test in case this grouping is destroyed by the hydrolytic action of the reagent before iodination is complete.




        The reference 3 would give some insight to the formation of sterically hindered idocompounds at $alphace{C}$ without giving idoform (formation of the triiodide intermediate as stated in OP's comment). Also read Ref.4 for review on idoform test.





        References:




        1. R. C. Fuson, C. W. Tullock, “The Haloform Reaction. XIV. An Improved Iodoform Test,” J. Am. Chem. Soc. 1934, 56(7), 1638–1640 (DOI: 10.1021/ja01322a061).

        2. M. Večeřa, J. Gasparič, In Detection and Identification of Organic Compounds; Plenum Press: New York, NY, 1971, “Chapter XII: Carbonyl Compounds,” pp. 208-246.

        3. C. H. Fisher, H. R. Snyder, R. C. Fuson, “The Haloform Reaction. VI. Alpha-Halogen Derivatives of Hindered Ketones,” J. Am. Chem. Soc. 1932, 54(9), 3665–3674 (DOI: 10.1021/ja01348a025).

        4. R. C. Fuson, B. A. Bull, “The Haloform Reaction,” Chem. Rev. 1934, 15(3), 275–309 (DOI: 10.1021/cr60052a001).






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          4 Answers
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          4 Answers
          4






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          active

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          11












          $begingroup$

          As @Waylander pointed out, it appears this reaction has not been performed and/or recorded in any literature, so it is quite dangerous to speculate.



          But keeping that aside, A 3D perspective reveals that abstraction of protons from the methyl group in quite unhindered.



          2',6'-acetophenone



          Hence, the triiodo intermediate is well anticipated.
          Triiodo substituted product



          However, a quick glance at spatial orientation of iodine atoms reveals the reaction may be dead slow in the next step.



          Trajectory of incoming hydroxide ion is hindered



          Notice that the Burgi-Dunitz trajectory, which we may assume the incoming nucleophile to take, is hindered by the large iodine atoms and the methyl group.



          It is quite safe to assume that the attack at the carbonyl carbon is unfavoured, preventing the release of the $ce{CI3-}$, and ultimately $ce{CHI3}$ never appears.






          share|improve this answer









          $endgroup$


















            11












            $begingroup$

            As @Waylander pointed out, it appears this reaction has not been performed and/or recorded in any literature, so it is quite dangerous to speculate.



            But keeping that aside, A 3D perspective reveals that abstraction of protons from the methyl group in quite unhindered.



            2',6'-acetophenone



            Hence, the triiodo intermediate is well anticipated.
            Triiodo substituted product



            However, a quick glance at spatial orientation of iodine atoms reveals the reaction may be dead slow in the next step.



            Trajectory of incoming hydroxide ion is hindered



            Notice that the Burgi-Dunitz trajectory, which we may assume the incoming nucleophile to take, is hindered by the large iodine atoms and the methyl group.



            It is quite safe to assume that the attack at the carbonyl carbon is unfavoured, preventing the release of the $ce{CI3-}$, and ultimately $ce{CHI3}$ never appears.






            share|improve this answer









            $endgroup$
















              11












              11








              11





              $begingroup$

              As @Waylander pointed out, it appears this reaction has not been performed and/or recorded in any literature, so it is quite dangerous to speculate.



              But keeping that aside, A 3D perspective reveals that abstraction of protons from the methyl group in quite unhindered.



              2',6'-acetophenone



              Hence, the triiodo intermediate is well anticipated.
              Triiodo substituted product



              However, a quick glance at spatial orientation of iodine atoms reveals the reaction may be dead slow in the next step.



              Trajectory of incoming hydroxide ion is hindered



              Notice that the Burgi-Dunitz trajectory, which we may assume the incoming nucleophile to take, is hindered by the large iodine atoms and the methyl group.



              It is quite safe to assume that the attack at the carbonyl carbon is unfavoured, preventing the release of the $ce{CI3-}$, and ultimately $ce{CHI3}$ never appears.






              share|improve this answer









              $endgroup$



              As @Waylander pointed out, it appears this reaction has not been performed and/or recorded in any literature, so it is quite dangerous to speculate.



              But keeping that aside, A 3D perspective reveals that abstraction of protons from the methyl group in quite unhindered.



              2',6'-acetophenone



              Hence, the triiodo intermediate is well anticipated.
              Triiodo substituted product



              However, a quick glance at spatial orientation of iodine atoms reveals the reaction may be dead slow in the next step.



              Trajectory of incoming hydroxide ion is hindered



              Notice that the Burgi-Dunitz trajectory, which we may assume the incoming nucleophile to take, is hindered by the large iodine atoms and the methyl group.



              It is quite safe to assume that the attack at the carbonyl carbon is unfavoured, preventing the release of the $ce{CI3-}$, and ultimately $ce{CHI3}$ never appears.







              share|improve this answer












              share|improve this answer



              share|improve this answer










              answered 11 hours ago









              William R. EbenezerWilliam R. Ebenezer

              3658




              3658























                  3












                  $begingroup$

                  I'd agree with Waylander's 2nd comment - hydrolysis to form the carboxylic acid requires formation of the tetrahedral intermediate (from OH- attack on the keton), which the presence of two ortho substituents on the benzene ring doesnt allow, sterically.



                  A related effect is that methyl 2,6-dimethylbenzoate doesnt undergo basic hydrolysis by the normal BAc2, since it would involve that same tetrahedral intermediate. Instead it goes via teh BAl2 mechanism (i.e. SN2 attack at the methyl group and rate-determining cleavage of the alkyl, rather than acyl bond).






                  share|improve this answer









                  $endgroup$


















                    3












                    $begingroup$

                    I'd agree with Waylander's 2nd comment - hydrolysis to form the carboxylic acid requires formation of the tetrahedral intermediate (from OH- attack on the keton), which the presence of two ortho substituents on the benzene ring doesnt allow, sterically.



                    A related effect is that methyl 2,6-dimethylbenzoate doesnt undergo basic hydrolysis by the normal BAc2, since it would involve that same tetrahedral intermediate. Instead it goes via teh BAl2 mechanism (i.e. SN2 attack at the methyl group and rate-determining cleavage of the alkyl, rather than acyl bond).






                    share|improve this answer









                    $endgroup$
















                      3












                      3








                      3





                      $begingroup$

                      I'd agree with Waylander's 2nd comment - hydrolysis to form the carboxylic acid requires formation of the tetrahedral intermediate (from OH- attack on the keton), which the presence of two ortho substituents on the benzene ring doesnt allow, sterically.



                      A related effect is that methyl 2,6-dimethylbenzoate doesnt undergo basic hydrolysis by the normal BAc2, since it would involve that same tetrahedral intermediate. Instead it goes via teh BAl2 mechanism (i.e. SN2 attack at the methyl group and rate-determining cleavage of the alkyl, rather than acyl bond).






                      share|improve this answer









                      $endgroup$



                      I'd agree with Waylander's 2nd comment - hydrolysis to form the carboxylic acid requires formation of the tetrahedral intermediate (from OH- attack on the keton), which the presence of two ortho substituents on the benzene ring doesnt allow, sterically.



                      A related effect is that methyl 2,6-dimethylbenzoate doesnt undergo basic hydrolysis by the normal BAc2, since it would involve that same tetrahedral intermediate. Instead it goes via teh BAl2 mechanism (i.e. SN2 attack at the methyl group and rate-determining cleavage of the alkyl, rather than acyl bond).







                      share|improve this answer












                      share|improve this answer



                      share|improve this answer










                      answered 11 hours ago









                      PCKPCK

                      2104




                      2104























                          3












                          $begingroup$

                          During my mechanisms and named reactions lecture at bachelor’s level, a number of different mechanisms were introduced for transesterification of carboxylic acids and we were required to select the correct mechanism for a given set of reaction partners.



                          One of the typical special cases was a 2,6-disubstituted benzoic ester—basically your starting material but with an ester group rather than an acetyl group. It was noted that nucleophilic attack on the carbonyl carbon was not possible as the methyl groups sterically blocked the Bürgi-Dunitz trajectory. Instead, these esterifications would proceed via an acylium cation formed by displacement of the $ce{OR-}$ residue; once the linear acylium cation ($ce{Ph-C#overset{+}{O}}$) was formed, this could be attacked from any angle without the ortho substituents interfering.



                          It is likely, as William outlined, that the same problem exists for 2,6-dimethylacetophenone. While there should be no problem replacing the methyl hydrogens with iodides, there is no angle of attack for the hydroxide ion to generate the tetrahedral intermediate.



                          In the case of transesterification, the $ce{OR-}$ group is a sufficiently good leaving group so that the acylium cation may form. $ce{CI3-}$ is a much stronger base, so it seems highly unlikely to generate a corresponding acylium in this reaction. In the usual haloform reaction, the regeneration of the $ce{C=O}$ double bond provides a driving force to promote the liberation of $ce{CI3-}$ but that pathway is not possible if an acylium must be generated.






                          share|improve this answer









                          $endgroup$


















                            3












                            $begingroup$

                            During my mechanisms and named reactions lecture at bachelor’s level, a number of different mechanisms were introduced for transesterification of carboxylic acids and we were required to select the correct mechanism for a given set of reaction partners.



                            One of the typical special cases was a 2,6-disubstituted benzoic ester—basically your starting material but with an ester group rather than an acetyl group. It was noted that nucleophilic attack on the carbonyl carbon was not possible as the methyl groups sterically blocked the Bürgi-Dunitz trajectory. Instead, these esterifications would proceed via an acylium cation formed by displacement of the $ce{OR-}$ residue; once the linear acylium cation ($ce{Ph-C#overset{+}{O}}$) was formed, this could be attacked from any angle without the ortho substituents interfering.



                            It is likely, as William outlined, that the same problem exists for 2,6-dimethylacetophenone. While there should be no problem replacing the methyl hydrogens with iodides, there is no angle of attack for the hydroxide ion to generate the tetrahedral intermediate.



                            In the case of transesterification, the $ce{OR-}$ group is a sufficiently good leaving group so that the acylium cation may form. $ce{CI3-}$ is a much stronger base, so it seems highly unlikely to generate a corresponding acylium in this reaction. In the usual haloform reaction, the regeneration of the $ce{C=O}$ double bond provides a driving force to promote the liberation of $ce{CI3-}$ but that pathway is not possible if an acylium must be generated.






                            share|improve this answer









                            $endgroup$
















                              3












                              3








                              3





                              $begingroup$

                              During my mechanisms and named reactions lecture at bachelor’s level, a number of different mechanisms were introduced for transesterification of carboxylic acids and we were required to select the correct mechanism for a given set of reaction partners.



                              One of the typical special cases was a 2,6-disubstituted benzoic ester—basically your starting material but with an ester group rather than an acetyl group. It was noted that nucleophilic attack on the carbonyl carbon was not possible as the methyl groups sterically blocked the Bürgi-Dunitz trajectory. Instead, these esterifications would proceed via an acylium cation formed by displacement of the $ce{OR-}$ residue; once the linear acylium cation ($ce{Ph-C#overset{+}{O}}$) was formed, this could be attacked from any angle without the ortho substituents interfering.



                              It is likely, as William outlined, that the same problem exists for 2,6-dimethylacetophenone. While there should be no problem replacing the methyl hydrogens with iodides, there is no angle of attack for the hydroxide ion to generate the tetrahedral intermediate.



                              In the case of transesterification, the $ce{OR-}$ group is a sufficiently good leaving group so that the acylium cation may form. $ce{CI3-}$ is a much stronger base, so it seems highly unlikely to generate a corresponding acylium in this reaction. In the usual haloform reaction, the regeneration of the $ce{C=O}$ double bond provides a driving force to promote the liberation of $ce{CI3-}$ but that pathway is not possible if an acylium must be generated.






                              share|improve this answer









                              $endgroup$



                              During my mechanisms and named reactions lecture at bachelor’s level, a number of different mechanisms were introduced for transesterification of carboxylic acids and we were required to select the correct mechanism for a given set of reaction partners.



                              One of the typical special cases was a 2,6-disubstituted benzoic ester—basically your starting material but with an ester group rather than an acetyl group. It was noted that nucleophilic attack on the carbonyl carbon was not possible as the methyl groups sterically blocked the Bürgi-Dunitz trajectory. Instead, these esterifications would proceed via an acylium cation formed by displacement of the $ce{OR-}$ residue; once the linear acylium cation ($ce{Ph-C#overset{+}{O}}$) was formed, this could be attacked from any angle without the ortho substituents interfering.



                              It is likely, as William outlined, that the same problem exists for 2,6-dimethylacetophenone. While there should be no problem replacing the methyl hydrogens with iodides, there is no angle of attack for the hydroxide ion to generate the tetrahedral intermediate.



                              In the case of transesterification, the $ce{OR-}$ group is a sufficiently good leaving group so that the acylium cation may form. $ce{CI3-}$ is a much stronger base, so it seems highly unlikely to generate a corresponding acylium in this reaction. In the usual haloform reaction, the regeneration of the $ce{C=O}$ double bond provides a driving force to promote the liberation of $ce{CI3-}$ but that pathway is not possible if an acylium must be generated.







                              share|improve this answer












                              share|improve this answer



                              share|improve this answer










                              answered 6 hours ago









                              JanJan

                              49.7k7120261




                              49.7k7120261























                                  0












                                  $begingroup$

                                  There have been a few answers for this question, which make sense on steric hindrance preventing the idoform formation. However, one thing I wouldn’t agree with is almost everybody’s claim of not having literature evidence to support their theory, thus some may categorize this question as just opinion based and chose to close it (regardless how good it is). To avoid that, I’m going to try to give some acceptable literature evidence to support steric hindrance argument.



                                  Because of original idoform test (introduced by Lieben in 1870) is not reliable for water insoluble compounds, Fuson and Tullock provided improved idoform test in 1934 (Ref.1), which use dioxane as a secondary solvent. They have checked new method with wide variety of compounds that have been analyzed previously with Lieben’s method, but had given mixed results, some of which were misleading. For example, in a majority of these cases, the behavior toward hypoiodite has not been previously reported. Such example is pinacolone, which was previously considered as negative to the test, but given positive result with a longer period of heating (one of the evidence for role of steric hindrance). According to authors, some of the most notable negative results were given by following compounds (Figure 1; Ref. 1 & 2):



                                  Negative Idoform Test



                                  Yet, Figure 2 listed the compounds, which have given positive results, but have significant steric hindrance (Ref. 1 & 2):



                                  Positive Idoform Test



                                  Most notably, you may compare compounds 5 (negative; Figure 1) vs compound 11 (positive; Figure 2). They both have similar steric hindrance (aromatic $ce{C8-H}$ vs $ce{C3-H}$ is the only difference), yet gives contrary results. Only explanation could be acetic acid group on $ce{C1-O}$ must be cleaved before iodoform formation on compound 11, but similar cleavage on $ce{C2-O}$ of compound 5 is restricted due to its position, since it was known that 1-naphthyloxy group (conjugate base of 1-naphthol) is more stable than 2-naphthyloxy group (conjugate base of 2-naphthol). Same can be told about compound 12 giving positive test. Nonetheless, these results clearly shows that only restriction to give idiform is di-ortho-substitution on the substrate (cf., 1-4; Figure 1), which gives the additional resistance to the formation of final tetrahedral intermediate as pointed by Jan. Meanwhile, mono o-, p-, or m-substitution OR di-o,p-, o,m-, or m,m-substitution does not effect the idoform formation. This fact is stated in Ref.1 as:




                                  The iodoform reaction is greatly retarded by steric hindrance. The test is negative for all compounds which contain one of the requisite groupings joined to an aryl radical carrying two ortho substituents. As a matter of fact, the reaction is slow, even with pinacolone.




                                  Even tri-substituted compounds such as compound 8 give positive idoform test as long as two of substitutions were not in di-ortho positions. In their conclusion, Fuson and Tullock provided a generalization to the reaction (Ref.1):




                                  The test is positive for compounds which contain the grouping $ce{CH3CO}$-, $ce{CH2ICO}$-, or $ce{CHI2CO}-$ when, joined to a hydrogen atom or to a carboy atom which does not carry highly activated hydrogen atoms or groups which provide an excessive amount of steric hindrance. The test will, of course, be positive also for any compound which reacts with the reagent to give a derivative containing one of the requisite groupings. Conversely, compounds which contain one of the requisite groupings will give a negative test in case this grouping is destroyed by the hydrolytic action of the reagent before iodination is complete.




                                  The reference 3 would give some insight to the formation of sterically hindered idocompounds at $alphace{C}$ without giving idoform (formation of the triiodide intermediate as stated in OP's comment). Also read Ref.4 for review on idoform test.





                                  References:




                                  1. R. C. Fuson, C. W. Tullock, “The Haloform Reaction. XIV. An Improved Iodoform Test,” J. Am. Chem. Soc. 1934, 56(7), 1638–1640 (DOI: 10.1021/ja01322a061).

                                  2. M. Večeřa, J. Gasparič, In Detection and Identification of Organic Compounds; Plenum Press: New York, NY, 1971, “Chapter XII: Carbonyl Compounds,” pp. 208-246.

                                  3. C. H. Fisher, H. R. Snyder, R. C. Fuson, “The Haloform Reaction. VI. Alpha-Halogen Derivatives of Hindered Ketones,” J. Am. Chem. Soc. 1932, 54(9), 3665–3674 (DOI: 10.1021/ja01348a025).

                                  4. R. C. Fuson, B. A. Bull, “The Haloform Reaction,” Chem. Rev. 1934, 15(3), 275–309 (DOI: 10.1021/cr60052a001).






                                  share|improve this answer









                                  $endgroup$


















                                    0












                                    $begingroup$

                                    There have been a few answers for this question, which make sense on steric hindrance preventing the idoform formation. However, one thing I wouldn’t agree with is almost everybody’s claim of not having literature evidence to support their theory, thus some may categorize this question as just opinion based and chose to close it (regardless how good it is). To avoid that, I’m going to try to give some acceptable literature evidence to support steric hindrance argument.



                                    Because of original idoform test (introduced by Lieben in 1870) is not reliable for water insoluble compounds, Fuson and Tullock provided improved idoform test in 1934 (Ref.1), which use dioxane as a secondary solvent. They have checked new method with wide variety of compounds that have been analyzed previously with Lieben’s method, but had given mixed results, some of which were misleading. For example, in a majority of these cases, the behavior toward hypoiodite has not been previously reported. Such example is pinacolone, which was previously considered as negative to the test, but given positive result with a longer period of heating (one of the evidence for role of steric hindrance). According to authors, some of the most notable negative results were given by following compounds (Figure 1; Ref. 1 & 2):



                                    Negative Idoform Test



                                    Yet, Figure 2 listed the compounds, which have given positive results, but have significant steric hindrance (Ref. 1 & 2):



                                    Positive Idoform Test



                                    Most notably, you may compare compounds 5 (negative; Figure 1) vs compound 11 (positive; Figure 2). They both have similar steric hindrance (aromatic $ce{C8-H}$ vs $ce{C3-H}$ is the only difference), yet gives contrary results. Only explanation could be acetic acid group on $ce{C1-O}$ must be cleaved before iodoform formation on compound 11, but similar cleavage on $ce{C2-O}$ of compound 5 is restricted due to its position, since it was known that 1-naphthyloxy group (conjugate base of 1-naphthol) is more stable than 2-naphthyloxy group (conjugate base of 2-naphthol). Same can be told about compound 12 giving positive test. Nonetheless, these results clearly shows that only restriction to give idiform is di-ortho-substitution on the substrate (cf., 1-4; Figure 1), which gives the additional resistance to the formation of final tetrahedral intermediate as pointed by Jan. Meanwhile, mono o-, p-, or m-substitution OR di-o,p-, o,m-, or m,m-substitution does not effect the idoform formation. This fact is stated in Ref.1 as:




                                    The iodoform reaction is greatly retarded by steric hindrance. The test is negative for all compounds which contain one of the requisite groupings joined to an aryl radical carrying two ortho substituents. As a matter of fact, the reaction is slow, even with pinacolone.




                                    Even tri-substituted compounds such as compound 8 give positive idoform test as long as two of substitutions were not in di-ortho positions. In their conclusion, Fuson and Tullock provided a generalization to the reaction (Ref.1):




                                    The test is positive for compounds which contain the grouping $ce{CH3CO}$-, $ce{CH2ICO}$-, or $ce{CHI2CO}-$ when, joined to a hydrogen atom or to a carboy atom which does not carry highly activated hydrogen atoms or groups which provide an excessive amount of steric hindrance. The test will, of course, be positive also for any compound which reacts with the reagent to give a derivative containing one of the requisite groupings. Conversely, compounds which contain one of the requisite groupings will give a negative test in case this grouping is destroyed by the hydrolytic action of the reagent before iodination is complete.




                                    The reference 3 would give some insight to the formation of sterically hindered idocompounds at $alphace{C}$ without giving idoform (formation of the triiodide intermediate as stated in OP's comment). Also read Ref.4 for review on idoform test.





                                    References:




                                    1. R. C. Fuson, C. W. Tullock, “The Haloform Reaction. XIV. An Improved Iodoform Test,” J. Am. Chem. Soc. 1934, 56(7), 1638–1640 (DOI: 10.1021/ja01322a061).

                                    2. M. Večeřa, J. Gasparič, In Detection and Identification of Organic Compounds; Plenum Press: New York, NY, 1971, “Chapter XII: Carbonyl Compounds,” pp. 208-246.

                                    3. C. H. Fisher, H. R. Snyder, R. C. Fuson, “The Haloform Reaction. VI. Alpha-Halogen Derivatives of Hindered Ketones,” J. Am. Chem. Soc. 1932, 54(9), 3665–3674 (DOI: 10.1021/ja01348a025).

                                    4. R. C. Fuson, B. A. Bull, “The Haloform Reaction,” Chem. Rev. 1934, 15(3), 275–309 (DOI: 10.1021/cr60052a001).






                                    share|improve this answer









                                    $endgroup$
















                                      0












                                      0








                                      0





                                      $begingroup$

                                      There have been a few answers for this question, which make sense on steric hindrance preventing the idoform formation. However, one thing I wouldn’t agree with is almost everybody’s claim of not having literature evidence to support their theory, thus some may categorize this question as just opinion based and chose to close it (regardless how good it is). To avoid that, I’m going to try to give some acceptable literature evidence to support steric hindrance argument.



                                      Because of original idoform test (introduced by Lieben in 1870) is not reliable for water insoluble compounds, Fuson and Tullock provided improved idoform test in 1934 (Ref.1), which use dioxane as a secondary solvent. They have checked new method with wide variety of compounds that have been analyzed previously with Lieben’s method, but had given mixed results, some of which were misleading. For example, in a majority of these cases, the behavior toward hypoiodite has not been previously reported. Such example is pinacolone, which was previously considered as negative to the test, but given positive result with a longer period of heating (one of the evidence for role of steric hindrance). According to authors, some of the most notable negative results were given by following compounds (Figure 1; Ref. 1 & 2):



                                      Negative Idoform Test



                                      Yet, Figure 2 listed the compounds, which have given positive results, but have significant steric hindrance (Ref. 1 & 2):



                                      Positive Idoform Test



                                      Most notably, you may compare compounds 5 (negative; Figure 1) vs compound 11 (positive; Figure 2). They both have similar steric hindrance (aromatic $ce{C8-H}$ vs $ce{C3-H}$ is the only difference), yet gives contrary results. Only explanation could be acetic acid group on $ce{C1-O}$ must be cleaved before iodoform formation on compound 11, but similar cleavage on $ce{C2-O}$ of compound 5 is restricted due to its position, since it was known that 1-naphthyloxy group (conjugate base of 1-naphthol) is more stable than 2-naphthyloxy group (conjugate base of 2-naphthol). Same can be told about compound 12 giving positive test. Nonetheless, these results clearly shows that only restriction to give idiform is di-ortho-substitution on the substrate (cf., 1-4; Figure 1), which gives the additional resistance to the formation of final tetrahedral intermediate as pointed by Jan. Meanwhile, mono o-, p-, or m-substitution OR di-o,p-, o,m-, or m,m-substitution does not effect the idoform formation. This fact is stated in Ref.1 as:




                                      The iodoform reaction is greatly retarded by steric hindrance. The test is negative for all compounds which contain one of the requisite groupings joined to an aryl radical carrying two ortho substituents. As a matter of fact, the reaction is slow, even with pinacolone.




                                      Even tri-substituted compounds such as compound 8 give positive idoform test as long as two of substitutions were not in di-ortho positions. In their conclusion, Fuson and Tullock provided a generalization to the reaction (Ref.1):




                                      The test is positive for compounds which contain the grouping $ce{CH3CO}$-, $ce{CH2ICO}$-, or $ce{CHI2CO}-$ when, joined to a hydrogen atom or to a carboy atom which does not carry highly activated hydrogen atoms or groups which provide an excessive amount of steric hindrance. The test will, of course, be positive also for any compound which reacts with the reagent to give a derivative containing one of the requisite groupings. Conversely, compounds which contain one of the requisite groupings will give a negative test in case this grouping is destroyed by the hydrolytic action of the reagent before iodination is complete.




                                      The reference 3 would give some insight to the formation of sterically hindered idocompounds at $alphace{C}$ without giving idoform (formation of the triiodide intermediate as stated in OP's comment). Also read Ref.4 for review on idoform test.





                                      References:




                                      1. R. C. Fuson, C. W. Tullock, “The Haloform Reaction. XIV. An Improved Iodoform Test,” J. Am. Chem. Soc. 1934, 56(7), 1638–1640 (DOI: 10.1021/ja01322a061).

                                      2. M. Večeřa, J. Gasparič, In Detection and Identification of Organic Compounds; Plenum Press: New York, NY, 1971, “Chapter XII: Carbonyl Compounds,” pp. 208-246.

                                      3. C. H. Fisher, H. R. Snyder, R. C. Fuson, “The Haloform Reaction. VI. Alpha-Halogen Derivatives of Hindered Ketones,” J. Am. Chem. Soc. 1932, 54(9), 3665–3674 (DOI: 10.1021/ja01348a025).

                                      4. R. C. Fuson, B. A. Bull, “The Haloform Reaction,” Chem. Rev. 1934, 15(3), 275–309 (DOI: 10.1021/cr60052a001).






                                      share|improve this answer









                                      $endgroup$



                                      There have been a few answers for this question, which make sense on steric hindrance preventing the idoform formation. However, one thing I wouldn’t agree with is almost everybody’s claim of not having literature evidence to support their theory, thus some may categorize this question as just opinion based and chose to close it (regardless how good it is). To avoid that, I’m going to try to give some acceptable literature evidence to support steric hindrance argument.



                                      Because of original idoform test (introduced by Lieben in 1870) is not reliable for water insoluble compounds, Fuson and Tullock provided improved idoform test in 1934 (Ref.1), which use dioxane as a secondary solvent. They have checked new method with wide variety of compounds that have been analyzed previously with Lieben’s method, but had given mixed results, some of which were misleading. For example, in a majority of these cases, the behavior toward hypoiodite has not been previously reported. Such example is pinacolone, which was previously considered as negative to the test, but given positive result with a longer period of heating (one of the evidence for role of steric hindrance). According to authors, some of the most notable negative results were given by following compounds (Figure 1; Ref. 1 & 2):



                                      Negative Idoform Test



                                      Yet, Figure 2 listed the compounds, which have given positive results, but have significant steric hindrance (Ref. 1 & 2):



                                      Positive Idoform Test



                                      Most notably, you may compare compounds 5 (negative; Figure 1) vs compound 11 (positive; Figure 2). They both have similar steric hindrance (aromatic $ce{C8-H}$ vs $ce{C3-H}$ is the only difference), yet gives contrary results. Only explanation could be acetic acid group on $ce{C1-O}$ must be cleaved before iodoform formation on compound 11, but similar cleavage on $ce{C2-O}$ of compound 5 is restricted due to its position, since it was known that 1-naphthyloxy group (conjugate base of 1-naphthol) is more stable than 2-naphthyloxy group (conjugate base of 2-naphthol). Same can be told about compound 12 giving positive test. Nonetheless, these results clearly shows that only restriction to give idiform is di-ortho-substitution on the substrate (cf., 1-4; Figure 1), which gives the additional resistance to the formation of final tetrahedral intermediate as pointed by Jan. Meanwhile, mono o-, p-, or m-substitution OR di-o,p-, o,m-, or m,m-substitution does not effect the idoform formation. This fact is stated in Ref.1 as:




                                      The iodoform reaction is greatly retarded by steric hindrance. The test is negative for all compounds which contain one of the requisite groupings joined to an aryl radical carrying two ortho substituents. As a matter of fact, the reaction is slow, even with pinacolone.




                                      Even tri-substituted compounds such as compound 8 give positive idoform test as long as two of substitutions were not in di-ortho positions. In their conclusion, Fuson and Tullock provided a generalization to the reaction (Ref.1):




                                      The test is positive for compounds which contain the grouping $ce{CH3CO}$-, $ce{CH2ICO}$-, or $ce{CHI2CO}-$ when, joined to a hydrogen atom or to a carboy atom which does not carry highly activated hydrogen atoms or groups which provide an excessive amount of steric hindrance. The test will, of course, be positive also for any compound which reacts with the reagent to give a derivative containing one of the requisite groupings. Conversely, compounds which contain one of the requisite groupings will give a negative test in case this grouping is destroyed by the hydrolytic action of the reagent before iodination is complete.




                                      The reference 3 would give some insight to the formation of sterically hindered idocompounds at $alphace{C}$ without giving idoform (formation of the triiodide intermediate as stated in OP's comment). Also read Ref.4 for review on idoform test.





                                      References:




                                      1. R. C. Fuson, C. W. Tullock, “The Haloform Reaction. XIV. An Improved Iodoform Test,” J. Am. Chem. Soc. 1934, 56(7), 1638–1640 (DOI: 10.1021/ja01322a061).

                                      2. M. Večeřa, J. Gasparič, In Detection and Identification of Organic Compounds; Plenum Press: New York, NY, 1971, “Chapter XII: Carbonyl Compounds,” pp. 208-246.

                                      3. C. H. Fisher, H. R. Snyder, R. C. Fuson, “The Haloform Reaction. VI. Alpha-Halogen Derivatives of Hindered Ketones,” J. Am. Chem. Soc. 1932, 54(9), 3665–3674 (DOI: 10.1021/ja01348a025).

                                      4. R. C. Fuson, B. A. Bull, “The Haloform Reaction,” Chem. Rev. 1934, 15(3), 275–309 (DOI: 10.1021/cr60052a001).







                                      share|improve this answer












                                      share|improve this answer



                                      share|improve this answer










                                      answered 2 hours ago









                                      Mathew MahindaratneMathew Mahindaratne

                                      1,50913




                                      1,50913






























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