(a)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(b)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(c)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(d)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(e)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(f)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(g)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
(h)
To determine: The plane of symmetry if the molecule has an internal plane of symmetry and if the structure is chiral on absence of plane of symmetry.
Interpretation: The validation of the statement that the given molecule contains a plane of symmetry is to be stated and on absence of plane of symmetry, the chirality of the molecule is to be detected.
Concept introduction: A carbon which has all the four different atoms or group of atoms show tetrahedral geometry is referred to as the chiral carbon. The mirror image of an object that contains chiral carbon has non-super imposable mirror image. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The number of enantiomers of a molecule depends on the number of chiral centres.
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Chapter 5 Solutions
EP ORGANIC CHEMISTRY -MOD.MASTERING 18W
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- Part VII. Below are the 'HNMR, 13 C-NMR, COSY 2D- NMR, and HSQC 2D-NMR (similar with HETCOR but axes are reversed) spectra of an organic compound with molecular formula C6H1003 - Assign chemical shift values to the H and c atoms of the compound. Find the structure. Show complete solutions. Predicted 1H NMR Spectrum 4.7 4.6 4.5 4.4 4.3 4.2 4.1 4.0 3.9 3.8 3.7 3.6 3.5 3.4 3.3 3.2 3.1 3.0 2.9 2.8 2.7 2.6 2.5 2.4 2.3 2.2 2.1 2.0 1.9 1.8 1.7 1.6 1.5 1.4 1.3 1.2 1.1 f1 (ppm) Predicted 13C NMR Spectrum 100 f1 (ppm) 30 220 210 200 190 180 170 160 150 140 130 120 110 90 80 70 -26 60 50 40 46 30 20 115 10 1.0 0.9 0.8 0 -10arrow_forwardQ: Arrange BCC and Fec metals, in sequence from the Fable (Dr. R's slides) and Calculate Volume and Density. Aa BCC V 52 5 SFCCarrow_forwardNonearrow_forward
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