(a)
Interpretation: The given red protons are whether homotopic, Enantiotopic or Diastereotopic to be predicted.
Concept Introduction:
Homotopic: If the protons are interchangeable by rotational symmetry, then the protons are chemically equivalent and termed as homotopic.
Enantiotopic: If the protons are interchangeable by reflectional symmetry, then the protons are chemically equivalent and termed as Enantiotopic.
Diastereotopic: If the protons are not interchangeable by either of the symmetry operations, then the protons are Diastereotopic; the protons are not chemically equivalent if a chiral center present in the molecule.
(b)
Interpretation: The given red protons are whether homotopic, Enantiotopic or Diastereotopic to be predicted.
Concept Introduction:
Homotopic: If the protons are interchangeable by rotational symmetry, then the protons are chemically equivalent and termed as homotopic.
Enantiotopic: If the protons are interchangeable by reflectional symmetry, then the protons are chemically equivalent and termed as Enantiotopic.
Diastereotopic: If the protons are not interchangeable by either of the symmetry operations, then the protons are Diastereotopic; the protons are not chemically equivalent if a chiral center present in the molecule.
(c)
Interpretation: The given red protons are whether homotopic, Enantiotopic or Diastereotopic to be predicted.
Concept Introduction:
Homotopic: If the protons are interchangeable by rotational symmetry, then the protons are chemically equivalent and termed as homotopic.
Enantiotopic: If the protons are interchangeable by reflectional symmetry, then the protons are chemically equivalent and termed as Enantiotopic.
Diastereotopic: If the protons are not interchangeable by either of the symmetry operations, then the protons are Diastereotopic; the protons are not chemically equivalent if a chiral center present in the molecule.
(d)
Interpretation: The given red protons are whether homotopic, Enantiotopic or Diastereotopic to be predicted.
Concept Introduction:
Homotopic: If the protons are interchangeable by rotational symmetry, then the protons are chemically equivalent and termed as homotopic.
Enantiotopic: If the protons are interchangeable by reflectional symmetry, then the protons are chemically equivalent and termed as Enantiotopic.
Diastereotopic: If the protons are not interchangeable by either of the symmetry operations, then the protons are Diastereotopic; the protons are not chemically equivalent if a chiral center present in the molecule.
(e)
Interpretation: The given red protons are whether homotopic, Enantiotopic or Diastereotopic to be predicted.
Concept Introduction:
Homotopic: If the protons are interchangeable by rotational symmetry, then the protons are chemically equivalent and termed as homotopic.
Enantiotopic: If the protons are interchangeable by reflectional symmetry, then the protons are chemically equivalent and termed as Enantiotopic.
Diastereotopic: If the protons are not interchangeable by either of the symmetry operations, then the protons are Diastereotopic; the protons are not chemically equivalent if a chiral center present in the molecule.
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Chapter 15 Solutions
ORGANIC CHEM PRINT STUDY GDE & SSM
- Synthesize 2-Hydroxy-2-phenylacetonitrile from phenylmethanol using the necessary organic or inorganic reagents. Draw the structures of the compounds.arrow_forwardSynthesize N-Methylcyclohexylamine from cyclohexanol using the necessary organic or inorganic reagents. Draw the structures of the compounds.arrow_forwardSynthesize N-Methylcyclohexylamine from cyclohexanol using the necessary organic or inorganic reagents. Draw the structures of the compounds.arrow_forward
- If possible, please provide the formula of the compound 3,3-dimethylbut-2-enal.arrow_forwardSynthesize 1,4-dibromobenzene from acetanilide (N-phenylacetamide) using the necessary organic or inorganic reagents. Draw the structures of the compounds.arrow_forwardIndicate the products obtained by mixing (3-oxo-3-phenylpropyl)triphenylphosphonium bromide with sodium hydride.arrow_forward
- We mix N-ethyl-2-hexanamine with excess methyl iodide and followed by heating with aqueous Ag2O. Indicate the major products obtained.arrow_forwardIndicate the products obtained by mixing acetophenone with iodine and NaOH.arrow_forwardIndicate the products obtained by mixing 2-Propanone and ethyllithium and performing a subsequent acid hydrolysis.arrow_forward
- Indicate the products obtained if (E)-2-butenal and 3-oxo-butanenitrile are mixed with sodium ethoxide in ethanol.arrow_forwardQuestion 3 (4 points), Draw a full arrow-pushing mechanism for the following reaction Please draw all structures clearly. Note that this intramolecular cyclization is analogous to the mechanism for halohydrin formation. COH Br + HBr Brarrow_forwardIndicate the products obtained if 2,2-dimethylpropanal and acetaldehyde are mixed with sodium ethoxide in ethanol.arrow_forward
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