Concept explainers
Interpretation:
The chirality centers in aldotetrose and ketopentose are to be calculated and the stereoisomers for each general case are to be determined.
Concept Introduction:
Carbohydrates are categorized mainly as monosaccharides, disaccharides, and polysaccharides. Monosaccharides are single sugar units, mainly glucose and fructose, disaccharides are two sugar units, such as sucrose, and polysaccharides are more than two sugar units, such as starch and cellulose.
Monosaccharides containing 3-carbon atoms are called triose, 4-carbon atoms called tetrose, 5-carbon atoms called pentose, and so on.
In chiral molecules, carbon atom having four nonidentical substituent groups is called the chirality center of that molecule. Chirality center may also be called stereocenter, which signifies any point in the molecule where the interchanging of any two groups may lead to stereoisomers. The carbon of a carbohydrate can be considered as chiral when the carbon has all four different substituents attached to it.
The stereoisomers are calculated as follows:
Here,
Answer to Problem 1PP
Solution:
a) Two
b) Two
c) Four
Explanation of Solution
a) The aldotetrose
A monosaccharide containing four carbon atoms is called a tetrose. An aldotetrose is a monosaccharide that contains
The structure of aldotetrose is as follows:
The carbon atom attached to four different groups is chiral carbon. The chiral center in ketopentose is marked by * as follows:
Hence, an aldotetrose has two chirality centers.
b) The ketopentose
A monosaccharide containing five carbon atoms is called a pentose. A pentose containing a keto group is called a ketopentose.
The structure of ketopentose is as follows:
The carbon atom attached to four different groups is chiral carbon. The chiral center in ketopentose is marked by * as follows:
Hence, a ketopentose has two chirality centers.
c) The number of stereoisomers that will be expected from each general structure
Stereoisomers of a molecule have the same molecular formula, but different arrangement of atoms in space. Stereoisomers are different from enantiomers as they are not mirror images of each other, while enantiomers are mirror images of one another.
The compounds aldotetrose and ketopentose have two sets of enantiomers. The number of stereoisomers is calculated as:
Substitute 2 for
Hence, they will have four stereoisomers for each general structure.
Want to see more full solutions like this?
Chapter 22 Solutions
Organic Chemistry
- The cobalt mu-hydroxide complex cobaltate(III) of potassium is a dinuclear complex. Correct?arrow_forwardThe cobalt mi-hydroxide complex cobaltate(III) of potassium is a dinuclear complex. Correct?arrow_forward3. Arrange the different acids in Exercise B # 2 from the strongest (1) to the weakest acid (10). 1. 2. (strongest) 3. 4. 5. 6. 7. 8. 9. 10 10. (weakest)arrow_forward
- Name Section Score Date EXERCISE B pH, pOH, pка, AND PKD CALCULATIONS 1. Complete the following table. Solution [H+] [OH-] PH РОН Nature of Solution A 2 x 10-8 M B 1 x 10-7 M C D 12.3 6.8 2. The following table contains the names, formulas, ka or pka for some common acids. Fill in the blanks in the table. (17 Points) Acid Name Formula Dissociation reaction Ka pka Phosphoric acid H₂PO₁ H3PO4 H++ H₂PO 7.08 x 10-3 Dihydrogen H₂PO H₂PO H+ HPO 6.31 x 10-6 phosphate Hydrogen HPO₁ 12.4 phosphate Carbonic acid H2CO3 Hydrogen HCO 6.35 10.3 carbonate or bicarbonate Acetic acid CH,COOH 4.76 Lactic acid CH₂CHOH- COOH 1.38 x 10 Ammonium NH 5.63 x 10-10 Phenol CH₂OH 1 x 10-10 Protonated form CH3NH3* 3.16 x 10-11 of methylaminearrow_forwardIndicate whether it is true that Co(III) complexes are very stable.arrow_forwardMnO2 acts as an oxidant in the chlorine synthesis reaction.arrow_forward
- In Potassium mu-dihydroxydicobaltate (III) tetraoxalate K4[Co2(C2O4)4(OH)2], indicate whether the OH ligand type is bidentate.arrow_forwardImagine an electrochemical cell based on these two half reactions with electrolyte concentrations as given below: Oxidation: Pb(s) → Pb2+(aq, 0.10 M) + 2 e– Reduction: MnO4–(aq, 1.50 M) + 4 H+(aq, 2.0 M) + 3 e– → MnO2(s) + 2 H2O(l) Calculate Ecell (assuming temperature is standard 25 °C).arrow_forward: ☐ + Draw the Fischer projection of the most common naturally-occurring form of aspartate, with the acid group at the top and the side chain at the bottom. Important: be sure your structure shows the molecule as it would exist at physiological pH. Click and drag to start drawing a structure. ✓arrow_forward
- For a silver-silver chloride electrode, the following potentials are observed: E°cell = 0.222 V and E(saturated KCl) = 0.197 V Use this information to find the [Cl–] (technically it’s the activity of Cl– that’s relevant here, but we’ll just call it “concentration” for simplicity) in saturated KCl.arrow_forwardA concentration cell consists of two Sn/Sn2+ half-cells. The cell has a potential of 0.10 V at 25 °C. What is the ratio of [Sn2+] (i.e., [Sn2+left-half] / [Sn2+right-half])?arrow_forwardElectrochemical cell potentials can be used to determine equilibrium constants that would be otherwise difficult to determine because concentrations are small. What is Κ for the following balanced reaction if E˚ = +0.0218 V? 3 Zn(s) + 2 Cr3+(aq) → 3 Zn2+(aq) + Cr(s) E˚ = +0.0218 Varrow_forward
Organic ChemistryChemistryISBN:9781305580350Author:William H. Brown, Brent L. Iverson, Eric Anslyn, Christopher S. FootePublisher:Cengage Learning
Macroscale and Microscale Organic ExperimentsChemistryISBN:9781305577190Author:Kenneth L. Williamson, Katherine M. MastersPublisher:Brooks Cole
Chemistry for Today: General, Organic, and Bioche...ChemistryISBN:9781305960060Author:Spencer L. Seager, Michael R. Slabaugh, Maren S. HansenPublisher:Cengage Learning