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CHM624 Experiment

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CHM624
ADVANCED ORGANIC CHEMISTRY
LABORATORY EXPERIMENTS
Extracted from:
Harwood, L.M.; Moody, C.J.; Experimental Organic Chemistry:
Principles and Practice, Blackwell Scientific Publications, 1989
LIST OF EXPERIMENTS
1. Peparation of 4-vinylbenzoic acid by a Wittig reaction in aqueous medium
2. 4-Bromobenzophenone by the Friedel-Crafts reaction
3. Oxidation of 4-tert-Butyl Cyclohexanol with PCC on a Silica Gel Substrate
4. Synthesis of flavone
5. Chemoselective Reduction of Methyl Acetoacetate using NaBH4
Note: The recommended experiments are experiments 1, 2 and 3 above. Duration: 7-8 weeks
ASSESSMENT AND GRADING
The laboratory sessions contribute 20% of the course grade. The marks for each experiment will be
based on the followings:
A.
B.
C.
Pre-laboratory preparations
(assessed from the lab note books)
Laboratory techniques
(performance in the lab)
Laboratory reports
(all reports are individual work)
Total
2 marks
1 marks
17 marks
20 marks
A well written report should have the followings:
1. All laboratory reports must be typed and submitted one week after the experiments.
2. The cover page should contain the following information: Course name, Course code, number
and title of experiment, name of student, name of partners (for group work), name of lecturer,
and date of experiment and date of submission of report.
3. The following marking scheme table must be included with the laboratory report.
4. Should the student fail to submit the week’s report, the student is given maximum of 3 marks
(for prelab and technique). Marks will also be deducted for late submission of report.
5. No report will be accepted (no marks given) from students who did not perform the week’s
experiment.
6. Students who missed any lab session (with medical certificate) will be graded based on the
remaining number of experiments.
LABORATORY REPORT MARKING SCHEME
Objective of the Experiment
Introduction
Experimental Procedure
Results and Observations
Calculations
Discussion
Conclusion
Answers to Questions
References
Pre-laboratory preparations
Laboratory techniques
Total Marks
Full
Mark(s)
1.0
2.0
1.0
2.0
2.0
5.0
1.0
2.0
1.0
2.0
1.0
20
Marks
(to be filled by lecturer)
CHEMICALS REQUIRED
Experiment 1: Peparation of 4-vinylbenzoic acid by a Wittig reaction in aqueous medium
(Recommended Experiment)
1. Preparation of phosphonium salt
4-Bromomethylbenzoic acid (FW 215.1)
Triphenylphosphine (FW 262.3)
Acetone
Diethyl ether
2. Preparation of 4-vinylbenzoic acid
Formaldehyde (37 wt % solution) (FW 30.0)
Sodium hydroxide pellets
Ethanol
Hydrochloric acid (concentrated)
4.30 g (20 mmol)
5.20 g (20 mmol)
32 mL
2.5 g
Experiment 2: 4-Bromobenzophenone by the Friedel-Crafts reaction
(Recommended Experiment)
Bromobenzene (FW 157.0)
Benzoyl chloride (FW 140.6)
Anhydrous aluminium chloride (FW 133.3)
Sodium hydroxide (10%)
Diethyl ether
Light petroleum (60 - 80C)
pH indicator paper
2.0 mL, 3.0 g (19 mmol)
3.3 mL, 4.0 g (30 mmol)
4.0 g (30 mmol)
Experiment 3: Oxidation of 4-tert-Butyl Cyclohexanol with PCC on a Silica Gel Substrate
(Recommended Experiment)
4-tert-butyl cyclohexanol (FW 156.27)
Pyridinium chlorochromate (FW 215.56)
Silica gel (230 – 400 mesh)
Dichloromethane
Celite
Saturated NaCl
Anhydrous Na2SO4
Ethyl acetate
Petroleum ether
Silica gel (30 – 70 mesh)
0.16 g (1.0 mmol)
0.43 g (2.00 mmol)
0.43 g (for synthesis)
for filtering
Experiment 4: Synthesis of flavone
1. Preparation of 2-benzoyloxyacetophenone
2-Hydroxyacetophenone (FW 136.2)
Benzoyl chloride (FW 140.6)
Pyridine (FW 79.1)
Hydrochloric acid (3%)
2.46 mL, 2.72 g (20 mmol)
3.48 mL, 4.22 g (30 mmol)
5 mL
Methanol
2. Preparation of ortho-hydroxydibenzoylmethane
Potassium hydroxide
0.85 g
*Important: Pulverize the KOH rapidly in mortar pre-heated to 100C
Pyridine
8 mL
*Important: Dry the pyridine over KOH
Acetic acid solution (10%)
15 mL
3. Preparation of flavone
Glacial acetic acid
Sulfuric acid (concentrated)
Light petroleum (bp 60 -80C)
7 mL
0.25 mL
Experiment 5: Chemoselective Reduction of Methyl Acetoacetate using NaBH4
Methyl acetoacetate (FW 116.12)( 1.08 g/mL)
Sodium borohydride (FW 37.83)
Methanol
Dichloromethane
Saturated ammonium chloride
Anhydrous MgSO4
Ethyl acetate
Petroleum ether
Silica gel (230 – 400 mesh)
0.50 g (4.31 mmol)
0.20 g (5.17 mmol)
10 mL
Experiment 1: Peparation of 4-vinylbenzoic acid by a Wittig reaction in aqueous medium
(Recommended Experiment)
This is an aqueous Wittig reaction in which the ylid is generated in the presence of a large excess of a
reactive aldehyde. The ylid is stabilized by virtue of the electron withdrawing carboxylic acid group
on the aromatic ring and resistant to hydrolysis. The phosphonium salt is prepared from
4-bromomethylbenzoic acid which, being nonvolatile, is relatively safe to handle, although it still has
irritant properties. This starting material is available commercially.
+
PPH3, acetone
reflux
Time
Br
_
HCHO, NaOH
H2O
3hx3
Equipments and instruments
Magnetic stirrer
Reflux apparatus
Suction filtration
IR
Materials
1. Preparation of phosphonium salt
4-Bromomethylbenzoic acid (FW 215.1)
Triphenylphosphine (FW 262.3)
Acetone
Diethyl ether
2. Preparation of 4-vinylbenzoic acid
Formaldehyde (37 wt % solution) (FW 30.0)
Sodium hydroxide pellets
Ethanol
Hydrochloric acid (concentrated)
4.30 g (20 mmol)
5.20 g (20 mmol)
32 mL
2.5 g
Procedure
1. Preparation of 4-carboxybenzyltriphenylphosphonium bromide
Dissolve the bromomethylbenzoic acid and the triphenylphosphine in 60 mL acetone in a 100 mL
round bottomed flask and reflux the mixture for 45 min. After this time, cool the reaction mixture
and filter off the precipitated phosphonium salt with suction. Wash the solid with diethyl ether (2 x
20 mL) on the sinter and dry it with suction. Record the yield and mp of the product which is
sufficiently pure to use directly in the next stage.
2. Preparation of 4-vinylbenzoic acid
Place 4-carboxybenzylphenylphosphonium bromide (3.76 g, 8 mmol), the aqueous formaldehyde and
15 mL water in a 250 mL Erlenmeyer flask equipped with a magnetic stirrer bar. Stir vigorously and a
solution of the sodium hydroxide in 15 mL water over approximately 10 min. Stir the mixture for an
additional 45 min and filter off the precipitate with suction, and wash it with water. Acidify the
combined filtrate and washings with concentrated hydrochloric acid and filter off the residual
precipitate of crude product with suction. Recrystallize the product from aqueous ethanol and
record the yield and mp of the material obtained. Analyze the purified material using NMR and IR
spectroscopy.
Problems
1. Assign the main absorptions in the IR spectrum of 4-vinylbenzoic acid.
2. Explain why it is possible to generate the ylid with aqueous sodium hydroxide in this experiment.
3. If an aldehyde other than formaldehyde were to be used, what would be the geometry at the
double bond in the major product? Why?
Experiment 2: 4-Bromobenzophenone by the Friedel-Crafts reaction
(Recommended Experiment)
The introduction of an acyl group into an aromatic ring is accomplished by an electrophilic
substitution by the acylium ion (RCO+) generated by the reaction between an acyl halide and
aluminium chloride. In bromobenzene, the benzene is a deactivating and ortho, para-directing
substituent. However, this reaction gives mainly the para-isomer, presumably ortho-substitution
which might also be expected is sterically less favoured.
PhCOCl
AlCl 3
Time
3hx2
Equipments and instruments
Steam bath
Rotary Evaporator
IR
Materials
Bromobenzene (FW 157.0)
Benzoyl chloride (FW 140.6)
Anhydrous aluminium chloride (FW 133.3)
Sodium hydroxide (10%)
Diethyl ether
Light petroleum (60 - 80C)
pH indicator paper
2.0 mL, 3.0 g (19 mmol)
3.3 mL, 4.0 g (30 mmol)
4.0 g (30 mmol)
Procedure
Place the bromobenzene and benzoyl chloride in a 50 mL Erlenmeyer flask. Add the aluminium
chloride in three portions, shaking and stirring in between additions, and then heat the flask on a
boiling water bath for 20 min. Cool, and pour the dark red liquid onto ice and wash out the
remaining contents by careful addition of 10% NaOH to the flask. Make the combined solutions
alkaline by the addition of 10% NaOH solution to dissolve any benzoic acid present and also
aluminium salts. Extract with 2 x 25 mL of ether, dry the organic extract over MgSO4 and remove the
ether on the rotary evaporator. 4-Bromobenzophenone remains and may be recrystallized from light
petroleum to give a colourless solid. Record the yield and mp of the product. Analyze the purified
material using NMR and IR spectroscopy.
Problems
1. Suggest syntheses of the following from benzene:
a)
b)
c)
Experiment 3: Oxidation of 4-tert-Butyl Cyclohexanol with PCC on a Silica Gel Substrate
(Recommended Experiment)
Oxidation reactions of alcohols greatly increase the synthetic usefulness of these compounds. Only
primary and secondary alcohols can be easily oxidized with the former converted to aldehydes or
carboxylic acids and the latter to the corresponding ketones. The strength and selectivity of oxidizing
agents varies widely, the use of oxochromium(VI)-amine reagents is fundamental for a number of
organic oxidative transformations. Pyridinium chlorochromate (PCC) is the most commonly used of
these reagents, due to its availability, stability and versatility. Oxidation with PCC generally proceeds
through a simple, one step reaction:
PCC, silica gel
DCM
Time
3hx2
Equipments and Instruments
Pestle and mortar
Magnetic stirrer
Rotary evaporator
IR
Materials
4-tert-butyl cyclohexanol (FW 156.27)
Pyridinium chlorochromate (FW 215.56)
Silica gel (230 – 400 mesh)
Dichloromethane
Celite
Saturated NaCl
Anhydrous Na2SO4
Ethyl acetate
Petroleum ether
Silica gel (30 – 70 mesh)
0.16 g (1.0 mmol)
0.43 g (2.00 mmol)
0.43 g (for synthesis)
for filtering
Cautions
PCC is an oxidizing agent! Handle with care! Wear gloves during the grinding process and do it under
a hood. You do not want to oxidize your skin.
Procedure
Combine and grind PCC and silica gel (230 – 400 mesh) with a pestle and mortar to form a light
orange powder. Add this powder to a 25 mL round bottomed flask along with 6 mL
dichloromethane. While stirring, add the 4-tert-butyl cyclohexanol. Stir for additional 30 – 40
minutes. Test the reaction solution every five minutes with TLC (develop in iodine).
After the reaction has completed, dilute the reaction solution with 10 mL of ether and filter the
solution through a pipet containing a cotton plug, 1 cm Celite, 3 cm silica gel (35 – 70 mesh).
Concentrate the filtrate by blowing on it with N2 until it is a yellow oil. Then dilute with 5 mL of ether
and transfer to a reaction tube. Extract with 2 x 5 mL of water and saturated NaCl solution. Dry over
anhydrous Na2SO4 and transfer the organic layer to a tared 10 mL flask. Allow the solvent to
evaporate overnight.
Record the yield, melting point, NMR and IR data of the product.
Problems
1. Would the final product have beenany different if you had used a stronger oxidizing agent such
as chromic acid? What would your products have been if you had been oxidizing the following
compound with a) PCC, and b) chromic acid?
2. Given that PCC is only sparingly soluble in CH2Cl2 while cyclohexanol is miscible in CH2Cl2, suggest
a reason for the importance of grinding the PCC and silica gel to form a fine powder. (Hint: What
basic physical property is changed by this?)
Experiment 4: Synthesis of flavone
Nature abounds with bright colours. Some arise by light diffraction by the complex structure of the
compounds but most colours in nature are by the absorption of certain wavelengths of visible light
by organic compounds.
Most red and blue flowers contain coloured glucosides called anthocynins. The colour imparted by
an anthocynin is pH dependent. For an exmple, the red colour of roses and the blue of cornflowers
are due to the same compound cyanin, which in its phenol form is red, and in its anionic form is blue.
The nonsugar part of the glucoside is a type of flavylium salt. This term comes from the parent
compound flavone, itself colourless, although the 3-hydroxy derivative, called flavonol, is yellow in
colour (Latin flavus = yellow).
cyanin
flavone
flavonol
This project involves the 3-step synthesis of flavone from 2-hydroxyacetophenone, which is
commercially available or can be prepared. The first stage is the benzoylation of the phenolic OH
group with benzoyl chloride in pyridine to give 2-benzoyloxyacetophenone, which on heating in the
presence of potassium hydroxide undergoes the Baker-Venkataraman rearrangement to give orthohydroxydibenzoylmethane in the second step. The final step involves cyclization of the orthohydroxydibenzoylmethane to flavone in the presence of acetic acid and sulfuric acids. After
recrystallization, the flavone is obtained as colourless needles.
AcOH
PhCOCl
C5H5N
Time
3hx4
Equipments and instruments
Steam bath
Hot plate with magnetic stirrer
Reflux apparatus
Calcium chloride guard tube
Suction filtration
IR
NMR
KON
H2SO4
Materials
1. Preparation of 2-benzoyloxyacetophenone
2-Hydroxyacetophenone (FW 136.2)
Benzoyl chloride (FW 140.6)
Pyridine (FW 79.1)
Hydrochloric acid (3%)
Methanol
2.46 mL, 2.72 g (20 mmol)
3.48 mL, 4.22 g (30 mmol)
5 mL
2. Preparation of ortho-hydroxydibenzoylmethane
Potassium hydroxide
0.85 g
*Important: Pulverize the KOH rapidly in mortar pre-heated to 100C
Pyridine
8 mL
*Important: Dry the pyridine over KOH
Acetic acid solution (10%)
15 mL
3. Preparation of flavone
Glacial acetic acid
Sulfuric acid (concentrated)
Light petroleum (bp 60 -80C)
7 mL
0.25 mL
Procedure
1. Preparation of 2-benzoyloxyacetophenone
Dissolve the 2-hydroxyacetophenone in 5 mL pyridine (dried over KOH) in a 25 mL round bottomed
flask. Add the benzoyl chloride, fit the flask with a calcium chloride guard tube and swirl the flask to
ensure mixing of the reagents. The temperature of the reaction mixture rises spontaneously. Leave
the reaction mixture for about 20 min or until no further heat is evolved. Then pour the mixture into
a 250 mL beaker containing 120 mL hydrochloric acid (3%) and 40 g crushed ice with good stirring.
Collect the product by suction filtration and wash it with 4 mL cold methanol and then 5 mL water.
Dry the product by suction at the filter pump for 20 min, then recrystallize it from approximately 5
mL methanol. Record the yield, mp, and the IR and NMR (in CDCl3) spectra of the product after
recrystallization. Record an IR spectrum of the starting 2-hydroxyacetophenone for comparison.
2. Preparation of ortho-hydroxydibenzoylmethane
Dissolve 2.4 g (10 mmol) of the 2-benzoyloxyacetophenone in 8 mL pyridine (dried over KOH) in a 50
mL beaker. Warm the solution to 50C in hot water bath. Add the finely powdered potassium
hydroxide and stir the mixture for 15 min using a glass rod. During this time a yellow precipitate of
the potassium salt of the product forms. Cool the mixture to room temperature and add 15 mL of
10% acetic acid solution. Collect the product by suction filtration and dry it by suction at the filter
pump for a few minutes. Record the yield and mp of the product, which is sufficiently pure for use in
the next stage.
3. Peparation of flavone
Dissolve 1.20 g (5 mmol) of the ortho-hydroxydibenzoylmethane in 7 mL glacial acetic acid in a 25 mL
round bottomed flask. Swirl the solution and add 0.25 mL concentrated sulfuric acid. Fit the flask
with a reflux condenser, add boiling chips and heat it for 1 h. Remove the boiling chip and pour the
reaction mixture onto 40 g crushed ice contained in a 100 mL beaker with rapid stirring using a glass
rod. When all the ice has melted, collect the crude product by suction filtration and wash with
approximately 80 mL water until free from acid. Dry the product by suction at the filter pump and
then at 50C. Recrystallize the crude flavone from approximately 40 mL light petroleum. Record the
yield, mp, and the IR and NMR (in CDCl3) spectra of the product after recrystallization.
Problems
1. Discuss the mechanism of the Baker-Venkataraman rearrangement.
2. Assign the spectroscopic data for the starting 2-hydroxyacetophenone, its benzoylated derivative
and for flavone.
Experiment 5: Chemoselective Reduction of Methyl Acetoacetate using NaBH4
NaBH4, MeOH
0oC
Time
3hx3
Instruments
Magnetic stirrer
Rotary evaporator
IR
Materials
Methyl acetoacetate (FW 116.12)( 1.08 g/mL) 0.50 g (4.31 mmol)
Sodium borohydride (FW 37.83)
0.20 g (5.17 mmol)
Methanol
10 mL
Dichloromethane
Saturated ammonium chloride
Anhydrous MgSO4
Ethyl acetate
Petroleum ether
Silica gel (230 – 400 mesh)
Procedure
Methyl acetoacetate in methanol is cooled to 0C. NaBH4 is added in small portions over 5 minutes
and the mixture is stirred at 0C for an additional 30 min. The methanol is then removed under
reduced pressure. The residue is diluted with dichloromethane and saturated NH4Cl, and extracted
three times with dichloromethane. The combined organic layers are dried with anhydrous MgSO4
and concentrated under vacuum. The crude product is purified using column chromatography
(ethyl/acetate petroleum ether as the solvent system). Perform TLC to identify the suitable solvent
system.
Record the yield, NMR and IR spectra of the product after purification via chromatography. Use
HPLC to identify the ratio of the product’s isomers.
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