Concept explainers
(a)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
(b)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
(c)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
(d)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
(e)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
(f)
To determine: A three dimensional representation for the given structure, each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers and each structure labeled as chiral or achiral.
Interpretation: A three dimensional representation for the given structure with each chiral centre marked by star, any planes of symmetry, any enantiomer, any diastereomers are to be drawn and the structure is to be labeled as chiral or achiral are to be stated.
Concept introduction: If two compounds have same molecular formula but the spatial arrangement of atoms is different, then they are known as stereoisomers. Stereoisomers are further divided into two categories: optical isomers and geometrical isomers. The two different forms in which a single chiral carbon can exist is referred to as enantiomers. The class of diastereomers includes stereoisomers that are not enantiomers. They are not the mirror images of each other. There are two or more chiral centers generally present in diastereoisomers.
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Chapter 5 Solutions
Organic Chemistry Plus Masteringchemistry With Pearson Etext, Global Edition
- Trabectedin, shown in a ball-and-stick model on the cover of this text, is an anticancer drug sold under the trade name Yondelis. a. Locate the stereogenic centers in trabectedin. b.What is the maximum number of stereoisomers possible for trabectedin? c.Draw the enantiomer. d.Draw a diastereomer. e.If the specific rotation of trabectedin is +41.5, what is the [α] of a solution that contains 75% trabectedin and 25% of its enantiomer?f . What is the ee of a solution with [α] = +10.5?arrow_forwardConsider the following molecules (a-h) and answer the questions below:i. How many chiral carbon does it contains?ii. Does the molecule have any internal plane of symmetry?iii. Identify the molecule whether it is chiral of achiral?iv. Does it rotate the plane of polarized light?v. Is the molecule optically active?vi. Is meso compound present?vii. Draw all possible stereoisomers for the molecule in Fischer projection and label the relationship between each of the isomer.arrow_forward1. Locate/Label the chirality center of the given molecules. a. OH H2N C H CH3 CH3 SH b. OH HO CH2NHC(CH3)3 HOCH2arrow_forward
- What is the relationship between each pair of molecules shown below? - Identical, Constitutional isomers, Enantiomers, Diastereomers, or No relationship CH3 CH3 Br Br CH3 CH3 OH .OH Br CH3 b.) a.) Br ICI Br d.) e.)arrow_forward1. a.) Put asterisk on chiral centers b.) Label each chiral center as R or S. c.) Draw the enantiomer d.) Draw one diastereomers H N. N- H N. ÕH CONH, O NH (CH3)3Carrow_forwardLabel each molecule with chiral centers (R) and (S). Which ones have more than one?arrow_forward
- Q1: For each of the compounds described by the following names 1. draw a three-dimensional representation. 2. star (*) each chiral center. 3. draw any planes of symmetry. 4. draw any enantiomer. 5. draw any diastereomers. 6. label each structure you have drawn as chiral or achiral. (a) (S)-2-chlorobutane (c) (2R,35)-2,3-dibromohexane (e) meso-hexane-3,4-diol, CH,CH,CH(OH)CH(OH)CH;CH, (b) (R)-1,1,2-trimethylcyclohexane (d) (1R, 2R)-1,2-dibromocyclohexanearrow_forward1. Label the following as a: diasteriomer, enantiomer or neither (different compound) CHO CHO a. H OH -HO- a. HO H and H OH HO- H OH CH,OH ČHHOH b. СНО СНО H OH HO H b. H OH HO H and H OH HO H H OH HO H ČH2OH 2. Indicate whether each of the following molecules are chiral or achiral. Circle the chiral carbon(s) if present in the structure. HOHO CH 3 H C=C%3DC%3DC BICH 2 C-CH 2CH 3 H3C CH3 H. b. а. C.arrow_forwarda. What is the name of this molecule according to IUPAC? b. The molecule is chiral; identify the chiral center. Draw the two enantiomers and assign their absolute chirality (R vs S)arrow_forward
- How many chirality centers does the following molecule contain? (Hint: Look at the entire group attached to each C, not just the directly attached atom) Select one: A. 2 CH3-CH₂-C-CH₂-C-CH-CH₂-C-CC13 B. 1 CI O C. O O D. 3 CI CH₂CH3 NH₂ CH₂CH3arrow_forward2. Mark any chirality centers (asymmetric carbons) with a *. How many stereoisomers are possible? Brarrow_forwardEphedrine, a stimulant and illegal drug is an optically active compound with two chiral centers. OH NHCH3 CH3 Ephedrine a. In the structure of ephedrine on the answer sheet, mark each chiral center with an asterisk. b. How many stereoisomer/s does ephedrine have? Show necessary solutions on the answer sheet. c. Compound EPS is a stereoisomer of ephedrine. Determine the absolute configuration (R or S) at carbons A and B of compound EPS.arrow_forward
Organic Chemistry: A Guided InquiryChemistryISBN:9780618974122Author:Andrei StraumanisPublisher:Cengage Learning