(a)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To identify: the given carbohydrate (a) is D or L sugar and the configuration of each chiral center.
(b)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To identify: the given carbohydrate (b) is D or L sugar and the configuration of each chiral center.
(c)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To identify: the given carbohydrate (c) is D or L sugar and the configuration of each chiral center.
(d)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To identify: the given carbohydrate (d) is D or L sugar and the configuration of each chiral center.
(e)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To identify: the given carbohydrate (e) is D or L sugar and the configuration of each chiral center.
(f)
Interpretation:
For each of the given compounds, whether it is D or L sugar should be determined, the configuration of each chiral center should be assigned and the trend on the configuration of each chiral center should be explained.
Concept introduction:
- The stereo-descriptor used for carbohydrates is D or L. it is based on the dextrorotatory or levorotatory of smallest carbohydrate glyceraldehyde (1 chiral center).
The stereo-descriptor for other carbohydrates of having more than one chiral center will be evaluated by the location of –OH group (right or left) of farthest chiral carbon from the carbonyl group. Such as,
If the –OH group is located in right side then, the carbohydrate is a D-sugar.
If the –OH group is located in left side then, the carbohydrate is a L-sugar.
- Chiral carbon: Chiral carbon is the one which is bonded to four different molecules or groups.
- Configuration of a molecule: The configurations of a molecule arise due to the spatial arrangement of atoms. The configuration can be assigned by following CIP rules as follows.
- Assign numbering to the groups which are bonded to the chiral carbon based on the molecular weight and electronegativity.
- If the sequence of the numbering follows clockwise direction the chiral atom is assigned as R configuration.
- If the sequence of the numbering follows anticlockwise direction the chiral atom is assigned as S configuration.
- If the least priority group is on horizontal line in the fisher projection, then configuration is inverted to the obtained configuration from the above CIP rule which means R configuration becomes S and vice versa.
- The D-configuration is needed not to be dextrorotatory; rather it means the chirality center of farthest from aldo-group is having R-configuration or the –OH group is on right side.
To explain: the trend on the configuration of each chiral center in each given carbohydrates.
Want to see the full answer?
Check out a sample textbook solution
Chapter 24 Solutions
ORG.CHEM EBOOK W/BBWILEY PLUS>CUSTOM<
- a) 5. Circle all acidic (and anticoplanar to the Leaving group) protons in the following molecules, Solve these elimination reactions, and identify the major and minor products where appropriate: 20 points + NaOCH3 Br (2 productarrow_forwardNonearrow_forwardDr. Mendel asked his BIOL 260 class what their height was and what their parent's heights were. He plotted that data in the graph below to determine if height was a heritable trait. A. Is height a heritable trait? If yes, what is the heritability value? (2 pts) B. If the phenotypic variation is 30, what is the variation due to additive alleles? (2 pts) Offspring Height (Inches) 75 67.5 60 52.5 y = 0.9264x + 4.8519 55 60 65 MidParent Height (Inches) 70 75 12pt v V Paragraph B IUA > AT2 v Varrow_forward
- Experiment: Each team will be provided with 5g of a mixture of acetanilide and salicylic acid. You will divide it into three 1.5 g portions in separate 125 mL Erlenmeyer flasks savıng some for melting point analysis. Dissolve the mixture in each flask in ~60mL of DI water by heating to boiling on a hotplate. Take the flasks off the hotplate once you have a clear solution and let them stand on the bench top for 5 mins and then allow them to cool as described below. Sample A-Let the first sample cool slowly to room temperature by letting it stand on your lab bench, with occasional stirring to promote crystallization. Sample B-Cool the second sample 1n a tap-water bath to 10-15 °C Sample C-Cool the third sample in an ice-bath to 0-2 °C Results: weight after recrystalization and melting point temp. A=0.624g,102-115° B=0.765g, 80-105° C=1.135g, 77-108 What is the percent yield of A,B, and C.arrow_forwardRel. Intensity Q 1. Which one of the following is true of the compound whose mass spectrum is shown here? Explain how you decided. 100 a) It contains chlorine. b) It contains bromine. c) It contains neither chlorine nor bromine. 80- 60- 40- 20- 0.0 0.0 TT 40 80 120 160 m/z 2. Using the Table of IR Absorptions how could you distinguish between these two compounds in the IR? What absorbance would one compound have that the other compound does not? HO CIarrow_forwardIllustrate reaction mechanisms of alkenes with water in the presence of H2SO4, detailing each step of the process. Please show steps of processing. Please do both, I will thumb up for sure #1 #3arrow_forward
- The decomposition of dinitrogen pentoxide according to the equation: 50°C 2 N2O5(g) 4 NO2(g) + O2(g) follows first-order kinetics with a rate constant of 0.0065 s-1. If the initial concentration of N2O5 is 0.275 M, determine: the final concentration of N2O5 after 180 seconds. ...arrow_forwardDon't used hand raitingarrow_forwardCS2(g) →CS(g) + S(g) The rate law is Rate = k[CS2] where k = 1.6 × 10−6 s−¹. S What is the concentration of CS2 after 5 hours if the initial concentration is 0.25 M?arrow_forward
ChemistryChemistryISBN:9781305957404Author:Steven S. Zumdahl, Susan A. Zumdahl, Donald J. DeCostePublisher:Cengage Learning
ChemistryChemistryISBN:9781259911156Author:Raymond Chang Dr., Jason Overby ProfessorPublisher:McGraw-Hill Education
Principles of Instrumental AnalysisChemistryISBN:9781305577213Author:Douglas A. Skoog, F. James Holler, Stanley R. CrouchPublisher:Cengage Learning
Organic ChemistryChemistryISBN:9780078021558Author:Janice Gorzynski Smith Dr.Publisher:McGraw-Hill Education
Chemistry: Principles and ReactionsChemistryISBN:9781305079373Author:William L. Masterton, Cecile N. HurleyPublisher:Cengage Learning
Elementary Principles of Chemical Processes, Bind...ChemistryISBN:9781118431221Author:Richard M. Felder, Ronald W. Rousseau, Lisa G. BullardPublisher:WILEY