AN ABSTRACT OF THE THESIS OF YILIN QIAO for the
Transcript of AN ABSTRACT OF THE THESIS OF YILIN QIAO for the
AN ABSTRACT OF THE THESIS OF
YILIN QIAO for the Master of Science
in Chemistry presented on September 1st, 1994.
Title: Synthesis of substituted Planar Triarylmethane.
Abstract approved:
Two protective groups, benzyl and butyl, were utilized to
protect the central carbon of sesquixanthene in electrophilic
sUbstitution reactions. Attempts were also made to perform
sUbstitution on unprotected sesquixanthene.
Nitration was carried out on sesquixanthene where the
central carbon was protected and where the central carbon was
unprotected. After bromination and nitration, cleavage of the
protective group by oxidation was successful. Reduction of the
nitro groups to amino groups by tin metal and stannous
chloride was also attempted, but because of inavailability of
necessary analytical methods, the results were inconclusive.
_ ------1
SYNTHESIS OF SUBSTITUTED
PLANAR TRIARYLMETHANES
A Thesis
Presented to
the Department of Chemistry
EMPORIA STATE UNIVERSITY
In Partial Fulfillment
of the Requirements for the Degree
Master of Science
by
Yilin Qiao ~
September 1994
~ 1
ACKNOWLEDGEMENT
I would like to express my deepest thanks to my thesis
advisor and committee chair, Dr. Eric Trump, for the guidance
of my research project and my graduate study. He was always
willing to answer any questions that I might have about the
SUbject matter of this thesis. without his encouragement, this
thesis would never have been completed.
I would also like to express my sincere gratitude to my
academic advisor, Dr. Charles Greenlief, for his suggestions
and for his devoting time and tolerance to give all kinds of
help.
I would like to voice my appreciations to Dr. Robert
Jones for devoting his valuable time to give advice and to
review my thesis.
I would like to express my sincere gratitude to Dr.
Arthur Landis and Dr. Kenneth Johnson for instructions in
using certain instrumentation.
"'"'-------
i
CONTENTS
INTRODUCTION••••••••••••••••••••••••••••••••••••••••••••••••• 1
EXPERIMENTAL SECTION••••••••••••••••••••••••••••••••••••••••• 6
2,6,2',6',2.. ,6..-hexamethoxytriphenylcarbinol •••••••••••••• 6
9-(2,6-dimethoxyphenyl)-1,8-dimethoXYXanthydrol ••••••••••• 7
sesquixanthydrol 8
a. From 2,6,2',6',2.. ,6..-hexamethoxytriphenylcarbinol. •••• 8
b. From 9-(2,6-dimethoxyphenyl)-1,8-dimethoxyxanthydrol •• 8
Benzyl sesquixanthene and butyl sesquixanthene••••••••••• 10
a. Reaction with fluoroboric acid ••••••••••••••••••••••• 10
b. Reaction with benzyl magnesium chloride•••••••••••••• 10
c. Reaction with butyl magnesium bromide •••••••••••••••• 11
Benzyl tribromosesquixanthene•••••••••••••••••••••••••••• 12
Butyl tribromosesquixanthene••••••••••••••••••••••••••••• 12
cleavageofprotectinggroup•••••••••••••••••••• . •.• .. 13
Fluoroboric trinitrosesquixanthene••••••••••••••••••••••• 14
Reductionoffluoroborictrinitrosesquixanthene •• • .15
Butyl trinitrosesquixanthene•••••••••••••••••••• • .15
Reductionofbutyltrinitrosesquixanthene•••••••••• • •• 15
DISCUSSION OF RESULTS ••••••••••••••••••••••••••••••••••••••• 17
CONCLUSION•••••••••••••••••••••••••••••••••••••••••••••••••• 23
REFERENCES. • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • 2 4
IR SPECTRA••••••••• • .26
NMR. SPECTRA••••••••••••••••••••••••••••••••••••••••••••••••• 41
"'---
ii
LIST OF IR SPECTRA
1. IR spectrum of 2,6,2',6',2",6"hexamethoxytriphenylcarbinol ••••••••••••••••••••••••••. 26
2. IR spectrum of 9-(2,6-dimethoxyphenyl)1,8-dimethoXYXanthydrol•••••••••••••••••••••••••••••••• 27
3. IRspectrumofsesquixanthydrol •••••••••••••••••••••••• 28
4. IR spectrum of fluroboric sesquixanthene ••••••••••••••• 29
5. IR spectrum of benzyl sesquixanthene ••••••••••••••••••• 30
6. IR spectrum of butyl sesquixanthene•••••••••••••••••••• 31
7. IR spectrum of the product obtained from bromination of benzyl sesquixanthene••••••••••••••••••••••••••••••• 32
8. IR spectrum of product obtained from bromination of butyl sesquixanthene•••••••••••••••••••••••••••••••• 33
9. IR spectrum of the product obtained from oxidation of benzyl trinitrosesquixanthene••••••••••••••••••••••. 34
10. IR spectrum of the product obtained from nitration of fluoroboric sesquixanthene•••••••••••••••••••••••••. 35
11. IR spectrum of the product obtained from reduction of fluoroboric trinitrosesquixanthene•••••••••••••••.•. 36
12. IR spectrum of the product obtained from nitration of butyl sesquixanthene•••••••••••••••••••••••••••••••• 37
13. IR spectrum of the product obtained from reduction reactionofbutyltribromosesquixanthene ••••••••••••••• 38
14. IR spectrum of the product obtained from nitration reactionofbenzylsesquixanthene •••••••••••••••••••••. 39
15. IR spectrum of the product obtained from bromination of fluoroboric sesquixanthene•••••••••••••••••••••••••. 40
1""'"""--
iii
LIST OF NMR SPECTRA
16. NMR spectrum of the solvent deuterated chloroform•••••• 41
17. NMR spectrum of the solvent deuterated acetone ••••••••• 42
18. NMR spectrum of 9-(2,6-dimethoxyphenyl)1,8-dimethoxyxanthydrol•••••••••••••••••••••••••••••••• 43
19. NMR spectrum of sesquixanthydrol ••••••••••••••••••••••• 44
20. NMR spectrum of benzyl sesquixanthene•••••••••••••••••• 45
21. NMR spectrum of butyl sesquixanthene••••••••••••••••••• 46
22. NMR spectrum of the product obtained from bromination of benzyl sesquixanthene••••••••••••••••••••••••••••••• 47
23. NMR spectrum of the product obtained from nitration of fluroboric sesquixanthene••••••••••••••••••••••••••• 48
........
----
1
INTRODUCTION
Triarylmethane dyes have been used in many areas of
chemistry. They are useful reagents for indicators, 1
dichromatic titration and redox indicators, determining the
presence of traces of halide irons,2 and the
spectrophotometric determination of Sb(III),3 Ta(V)," Ga(III),s
In,6 to list just a few. They are used in ball point pen inks'
and as corrosion inhibitors.' Several triarylmethane dyes are
good indicators of the titration for Fe(II), Ti(III), Cr(II),
Cu(I) with Ce(IV), and for the titration of Fe(II), Fe(CN):,
U(IV), Mo(V) and hydroquinone with dichromate.
Except for the azodyes, triphenylmethane and xanthene
dyes are the most commonly used reagents in the
spectrophotometric determination of metals. Reports on the
most common and well known sUbstances--aluminon,
phenylfluorone, malachite green, brilliant green, crystal
violet, and rhodamine--were published over a half century ago.
In the phenol red group, for example, phenolsulfonphthalein
has been used for the kinetic determination of copper,' the
decomposition of the dye being recorded
spectrophotometrically.
Two problems with these indicators are that their
reactions are not all reversible and they are often not stable
in oxidizing solutions. In spite of these disadvantages, they
have been commonly used. 10,11
2
The unique properties of the central carbon atom have
aroused much chemical interest in triarylmethane dyes. A free
radical, a cation, or an anion can occupy the central
position, with resonance delocalization on the aromatic rings.
The stabilization of triarylmethane dyes is dependent on the
degree of twist of three phenyl rings. The dye has maximum
stability when the rings are coplanar, but this is normally
impossible, so a propeller-shaped molecule results. 12,13
The stability of triarylmethanes is also dependent on the
ring substituents. Ortho-substitution decreases the
stabilization because of large steric effect. The cation of
this para-methyl substituted triarylmethane is five times as
stable as the cation of tris ortho-methyl substituted
triarylmethane. 14 It may be seen that the effect of ortho
substitution is large and the effect is most readily
attributed to steric factors. Increasing the degree of ring
twist will decrease the degree of ring resonance and thus
decrease stabilization.
The use of oxygen bridges to force planarity of
triarylmethane or triaryl radicals has been investigated and
numerous 9-substituted xanthyl (I) free radicals have been
reported by conant. IS stability increased because of the oxygen
bridges. The two oxygen bridged molecule (II) in the xanthyl
series has also been reported. 16 This radical was reported to
be 100% dissociated in benzene at room temperature since
dilute solutions of the radical were found to obey Beer's law
"'""----
3
and no darkening of the solution occurred on warming. The
authors have interpreted this high degree of dissociation as
being due to high resonance stabilization in the free radical
due to planarity of the system. When compound (II) is compared
with compound (I), it is observed that compound (II) shows
greater stabilization due to second oxygen bridge.
o
(I) (II )
sesquixanthydrol (III) was of considerable synthetic and
chemical interest to us. It has an unusually high basicity
caused by resonance distribution of the positive charge to the
oxygen bridge as shown in structure (IV).
o o
o
(III )
0+
(IV)
""-----
4
In a sUfficiently acidic solution, sesquixanthydryl is
protonated and loses water. This type of compound is called a
"secondary base" and the equilibrium constant is expressed in
terms of KR + .18 Triphenylcarbinol, has a pKR + of -6.63. 19 Based
on the differences between the resonance structure of
triarylmethane and sesquixanthene, the pKR+ for sesquixanthene
is expected to be much larger than -6.63. Generally, electron
donating groups should stabilize the carbonium ion and
increase pKR+. Three para dimethylamino groups increase the
pKR+ to 9.63 and three para methoxy groups change the pKR+ to
0.82.
The planar sesquixanthydryl cation (IV) is noted for its
exceptional stability. Propeller-shaped crystal violet (V),
which contains electron-donating dialkylamino groups, is noted
for its intense color, but it is not fluorescent. In
fluorescent Rhodamine B(VI),2° which contains dialkylamino
groups, two of the three rings are locked into the same plane
by an oxygen bridge. Combining the planarity of the
sesquixanthydryl cation with electron donating group such as
crystal violet (V) produces compound such as triamino
sesquixanthene (VII) is the objective of our research. Such a
series of compounds would be expected to be intensely colored
and strongly fluorescent.
A known synthetic route21 for the preparation of amino
substituted sesquixanthene dyes is to start with a substituted
benzene which has a good leaving group, such as 3,5-dimethoxy
(CH 3 CH 2 ) 2 N o
:.J---C -OH
+ N(CH 2 CH3 )2
5
fluorobenzene. This route avoids protecting the central
carbonium ion. Our primary purpose was to create a different
synthetic route which would allow us to synthesize the
sesquixanthene base first and then add protecting group to
form a sesquixanthene dye as an intermediate, then to replace
a hydrogen on the aromatic ring with an amino group, forming
a basic amino dye. When this synthesis was carried out, we had
the opportunity to investigate the activity of the central
carbon, the protective ability of different substituted
groups, and the relationship between fluorescence and color.
~H3)2
~ o
a N(CH 3 )2(CH 3 )2 N .//
( V)
H N NH2 2 (VII) ~
o 1/
(VI)
"-
6
EXPERIMENT SECTION
OCH3H3 CO
H3CDCH3 H3c6iCH3 + I Li) I
~ ~6 H3CO~OCH3
synthesis of 2,6,2',6',2",6"-hexamethoxytriphenylcarbinol
-
cx:::H3I -t CH30-~-OCH3 ~ ~
~./'1 ~
H3m cx:::H3
A solution of phenyl lithium was prepared by the addition
of bromobenzene (19.5 g,0.125 mole) to 65 mL of ether with
lithium wire (2.0 9 0.290 mole) and 30 mL of diethyl ether.
1,3-dimethyl benzene (15.0 g, 0.109 mole) was added and the
reaction mixture was allowed to stand at room temperature
under an atmosphere of nitrogen for sixty hours. 2, 6-dimethoxy
phenyl lithium was formed as white crystals. 29 Dimethyl
carbonate (3.24 g, 0.036 mole) in 200 mL of benzene was added
and the reaction mixture was refluxed for three days under a
protective nitrogen atmosphere. A white solid formed in the
reaction mixture during this time. After cooling, the reaction
mixture was poured into 300 mL of water to produce an aqueous
-
7
layer and an organic layer. The organic layer was separated
from the aqueous layer, washed twice with water, dried over
sodium sulfate and concentrated to yield a grey residue. The
residue was recrystallized once from ether to yield 14.98 g
(47%) of 2,6,2',6',2", 6"-hexamethoxytriphenyl carbinol with
melting point 163-164°C. The product was verified by IR
spectrum Figure 1.
Synthesis of 9-(2,6-dimethoxyphenyll-1,8-dimethoxyxanthydrol
OCH3
CH3~HCl
OCH3
CH3
A solution of 2,6,2',6',2",6"
hexamethoxytriphenylcarbinol (4.0 g, 0.0508 mole) in 1,000 mL
of water and 10 mL of concentrated hydrochloric acid was
heated for two hours on a sand bath. The initial deep purple
solution became deep red during the reaction and a white
precipitate formed. The precipitate was collected by suction
filtration and dried under vacuum to yield 3.48 g (96%) of 9
(2,6-dimethoxyphenyl)-1,8-dimethoxyxanthydrol. The product
was purified by one recrystallization from benzene-acetone to
give 2.58g of material with melting point 295-298°C. This
"
8
and
o
0.435 mole)(50.0 q,
Cl
oH-N+
H 3
CO OCH 3
~/i ~
pyridine hydrochloride
A. from 2,6,2',6',2 1 ,6"-hexamethoxytriphenylcarbinol
spectrum Figure 18.
2,6,2' ,6' ,2 1 ,6"-hexamethoxytriphenylcarbinol (10.0 q, 0.023
was identified by infrared spectrum Figure 2. and NMR
synthesis of sesquixanthydrol:
-
mole) were mixed and heated with stirrinq at 195°C for one
hour. The initial purple mass qradually became liquid under
these conditions and took on a red color. The reaction mixture
was washed into one litter of water to produce a red solid and
a yellow aqueous solution. The solution was filtered to remove
the red solid and was then basified with potassium hydroxide
to produce a white solid. This product was purified by
recrystallization from a solution of diethyl ether, benzene,
and ethanol to yield 0.9 q of pure material which was
identified as sesquixanthydrol.
B. from 9-(2,6-dimethoxyphenyl)-1,8-dimethoxyxanthydrol
9
The product wassesquixanthydrol.of
CH 3 0 0' ~ '0
OCH 3
.;.:-..... I >
+N I
H U
(89%)g
basified with potassium hydroxide Which discharged the yellow
were mixed and heated at maximum reflux on a sand bath for one
9-(2,6-dimethoxyphenyl)-1,8-dimethoxyxanthydrol (2.5 g,
0.006 mole) and pyridine hydrochloride (7.0 g, 0.061 mole)
hour. The initial solid became a deep red liquid. At the end
1.75
washed out with water. A red solid remained undissolved in the
water and the solids remaining in the reaction flask were
color of the solution and produced a light brown precipitate.
water while the solution was a reddish yellow color. The
aluminum absorption column to yield 1.17 g (65%) of white pure
of this time, the red liquid reaction product was poured into
solution was filtered to remove the red material and was then
The precipitate was collected and dried under vacuum to yield
recrystallized once from ether, purified by passing it through
.....
sesquixanthydrol with melting point 303°C. The product was
verified by Infrared spectrum Figure 3, and NMR spectrum
10
7+ HBF 4
b. Reaction with benzyl magnesium chloride.
(rH2Cl. ) OCH:>"9Cl
Mg
~
d9C' OCE
0
Sesquixanthydrol (2.0 g, 0.007 mole) was dissolved in 200
a. Reaction with fluoroboric acid.
synthesis of benzyl sesquixanthene and butyl sesquixanthene.
in the presence of acetic anhydride. The reaction mixture was
ml ether and fluoroboric acid (1.75 ml, 0.014 mole) was added
Figure 19.
point above 350°C. verified by infrared spectrum Figure 4.
stirred at room temperature for one hour. A yellow colored
solid gradually formed. The solution was separated by suction
filtration, and the solid was washed with 20 Xl benzene to
yield 2.3 g (94%) of fluoboric sesquixanthydrol with melting
...
Fluoboric sesquixanthene (0.8 g, 0.002 mole) was added in
70 mL of ethyl ether. Freshly prepared butyl magnesium bromide
was added dropwise under nitrogen with stirring. The yellow
CI-l 3
CH 2 CH 2 CH 3
o
o
CH 3
CH2
CH 2 CH 2 Br
CH 3
CH 2
CH 2
cH 2MgBr?
~
CH 3
CH 2
CH 2
cH 2
MgBr ~
+ Br
+ Mg
o
CIl 3
CH 2
CH 2
cH 2m:
CH 3
CH 2
CH 2
cH 2 Br
11
Fluroboric sesquixanthene (1.7 g, 0.0046 mole) was added
to 100 mL of diethyl ether. Freshly prepared benzyl magnesium
chloride was added dropwise under nitrogen while stirring. The
yellow solid disappeared gradually. The solution was allowed
to stand for 30 minutes after all solid had disappeared. The
solution was washed using 40% concentrated HCl. The organic
layer was separated from the aqueous layer, washed once with
water, dried over sodium sulfate and concentrated to yield a
light brown solid. The brown solid was recrystallized once
from hexane to yield 1.45 g (84%) of pure benzyl
sesquixanthydrol with melting point 173-175°C. The product was
analyzed spectroscopically using IR and NMR, giving the
infrared spectrum Figure 5, and NMR spectrum Figure 20.
c. Reaction with butyl magnesium bromide.
12
solid disappeared gradually. The solution was allowed to stand
for 30 minutes after all the solid disappeared. The solution
was washed with 10% hydrochloric acid. The organic layer was
separated from aqueous layer, washed once with water, dried
over sodium sUlfate and concentrated to yield a light brown
solid. The brown solid was recrystallized once from hexane to
yield 0.7 g (95%) of white, pure butyl sesquixanthene with
melting point 161-161. 5°C. The product was analyzed
spectroscopically using IR and NMR, giving the infrared
spectrum Figure 6 and NMR spectrum Figure 21.
synthesis of 1,1' ,1"-tribromo-benzyl sesquixanthene I 1,1' ,1"
tribromo butyl sesquixanthene:
>CH 2 { > + Br2 ~
Br
CH 2 {
Br
Finely powdered benzyl sesquixanthene or butyl
sesquixanthene was placed in a weighing bottle cover, and then
the bottle cover was placed in a large neck Erlenmeyer flask
(the ideal vessel is a desiccator). Another weighing bottle
cover containing chemical quantitative bromine liquid (neat)
was set side by side with weighing bottle cover in the
,
13
butyl
o
Br
For tribromo benzyl
H+ KMno~
benzyl sesquixanthene I
Br
B;H -O~ 2_
o
In the flask,
A solution was prepared by adding 1,1' ,1"-tribromo benzyl
Erlenmeyer flask and its contents was allowed to stand 8 hours
Erlenmeyer flask. A rubber stopper sealed the erlenmeyer
Erlenmeyer flask and allowed to stand in the air under the
hydrogen bromide. The orange solid was then removed from the
or overnight. During this period, a needle was inserted, at
flask.
30 JIlL of benzene, filtered and cooled in an ice-bath. The
two hour intervals, to provide a means of escape for the
hood for four hours to allow the evaporation of bromine. The
crude 2,2',2"-tribromo benzyl sesquixanthene was dissolved in
products were light pink color.
sesquixanthene was in contact with bromine vapor. The
NMR spectrum Figure 22.
sesquixanthene, the melting point was 261°C and for butyl
tribromosesquixanthene, the melting point was 220°C. The
products were analyzed by IR spectrum, Figures 7 and 8, and
resulting crystals were filtered and air dried. Both of the
Cleavage of protective group.
14
sesquixanthene (0 .1S g, 0.0003 mole) in so mL of diethyl
ether, potassium permanganate (0.14 g, 0.0009 mole) in 20 mL
of water, and 2 mL of sulfuric acid. The mixture was allowed
to reflux overnight. At the end of the reaction, a white solid
product was formed between the ether and aqueous layers. The
solid mixture was collected by suction filtration and then
poured into ethyl ether with stirring for ten minutes. The
ether insoluble portion was separated by suction filtration.
The ether layer was dried over sodium sulfate and concentrated
to yield a white solid with melting point at 30SoC. This
product was analyzed by IR spectrum and this spectrum is shown
in Figure 9.
synthesis of Fluroboric trinitrosesquixanthene.
HNOJ ~
N02
Fluroboric sesquixanthene 0.6 g, 0.0016 mole) was placed
in an Erlenmeyer flask, and 30 mL of concentrated nitric acid
was added. The Erlenmeyer flask was heated and maintained in
a SO°C water bath for two hours. After cooling, a small
portion was dried in air. A needle-shaped product was formed.
The rest was poured into 100 mL of crushed ice. At this time,
"
15
a golden orange colored solid was formed. The product was
collected by suction filtration, dried in 800e oven to yield
0.39 g, 0.0009 mole (59%) of the product, which was platelet
shaped with a melting point above 350oe. The product was
analyzed by IR in Figure 10 and NMR in Figure 23. A test by
iron (II) hydroxide was positive.
Reduction reaction of fluoroboric trinitrosesquixanthene.
The procedure of reducing the fluoroboric
trinitrosesquixanthene was the same as the procedure for the
reduction reaction of butyl trinitrosesquixanthene, but the
color of the product was different. The melting point was
above 360oe. The IR spectrum is presented in Figure 11.
synthesis of Butyl trinitrosesquixanthene.
The nitration procedure with butyl sesquixanthene was
almost the same as the procedure for the nitration reaction
of fluoroboric sesquixanthene. The only difference was that a
little sUlfuric acid was added. The melting point was 292
296°e. The product was analyzed by IR spectrum, Figure 12.
Reduction of butyl trinitrosesquixanthene.
Butyl trini trosesquixanthene (1.32 gO. 003 mole) was
placed in round-bottomed flask which was fitted with a reflux
condenser. 100 mL of concentrated hydrochloric acid was added.
The mixture was heated with vigorous stirring in order to
dissolve the fluoroboric trinitrosesquixanthene. After the
solid dissolved (it was difficult to dissolve all of the
solid), granulated tin metal (2.5 g, 0.02 mole) was added in
16
very small portions during a 6 hours period. After adding tin
metal, the color of the solution changed from yellow to
orange. When the reaction was complete, an orange solid
precipitated. As the reaction mixture cooled, the product was
separated by suction filtration. The solid portion was washed
with 20 mL of water and dried in the air at 110°C to yield
(0.56 g, 50%) a reddish orange colored powder with a melting
point of 219-222°C. This product did not dissolve in ether, or
benzene, but was slightly soluble in water. The IR spectrum of
the product shown in Figure 13.
17
DISCUSSION
There are two possible precursors to sesquixanthydrol.
Both are alcohols, the structures are shown as (I) and (II).
H CO OCH 33
H CO OCH 33(II)( I )
Of these two precursors, (I) is much more viable, as (II) is
formed only with great difficulty.
In considering synthetic routes to sesquixanthydrol the
most promising method utilized a ring closure reaction. 22
pyridine hydrochloride appears to be the most effective ring
closure agent for this reaction. Since the alcohol (II)
eXhibits large steric hindrance due to the methoxy groups, the
conditions for ring closur. of compound (II) were extremely
difficult to optimize. The synthetic route from alcohol (II)
was abandoned at this point and attempts were directed toward
a synthesis of alcohol(I), for which steric factors are less
extreme.
2,2' , 6' ,2", 6"-dimethoxytriphenylcarbinol is very acid
sensitive. It formed appreciable amounts of the deep purple
:.
18
cation even in distilled water. In ethyl ether, its initial
colorless solution rapidly changed to purple while evaporating
the ether in the atmosphere. It is water soluble, but also
slightly soluble in ether and benzene. Not only is it a deep
purple color but also a high adhesive ability as well. At low
pH, it will lose two of its methoxy groups and form one oxygen
bridge.
It is important to protect the central carbonium ion in
ring substitution reactions. since the central carboxyl group
is extremely active and easy to oxidize, it must be protected
by a group such as benzyl or n-butyl. Two Grignard reagents,
benzyl magnesium chloride and butyl magnesium bromide, were
successfully made and successfully reacted with sesquixanthyl
fluoroborate forming benzyl sesquixanthene and butyl
sesquixanthene. The protection of the central carbon seemed
perfect.
Two routes were designed to synthesize tris-4,4'4"-amino
sesquixanthene. One involved the synthesis of tris-4, 4' 4"
nitro sesquixanthene intermediate, and then, the subsequent
reduction of the nitro groups to amino groups. The other
involved halogenation of the phenyl rings first, then utilized
the benzyne mechanism to replace the halogens by amino groups.
The halogenation followed by benzyne elimination-addition was
expected to give a higher yield of the desired product,
4,4',4"-triamino sesquixanthene.
Nitration or halogenation were expected to be easy to
'--~
19
carry out. Theoretically, the ether groups should be strongly
activating. On the other hand, when the central carbon carries
a positive change, the rings should be deactivated with
respect to electrophilic sUbstitution.
Bromination of benzyl sesquixanthene in ethyl ether was
unsuccessful. When benzyl sesquixanthene was allowed to stand
with bromine for three days, the reactants retained their
yellow color and looked the same as the starting material even
in the presence of ferric chloride. We believe that 1,1',1"
bromo benzyl sesquixanthene should be white.
Bromination of benzyl sesquixanthene and butyl
sesquixanthene by bromine vapor was successful. The product of
the bromination reaction was analyzed by IR. From the IR
spectrum, Figures 7 and 8, it was impossible to determine
which isomer was produced.
Normally, the substitution pattern is identified by two
bands in IR spectrum, the stronger absorption bands are below
900 cm1• These out-of-plane bending and ring puckering bands
are very intense. The overtone and combination bands at 2000
1600 cm1 are also useful. Unfortunately, this type of band
analysis is suitable only for simple aromatic ring systems.
For complicated aromatic compounds, these two areas cannot
offer reliable identification. D Using a high resolution
instrument and relatively pure samples, the C-Br stretch will
appear at 690-515 em-I, but cannot be observed with most
instruments. 24
"
20
The product obtained from bromination of benzyl
sesquixanthene could not be identified by its IR spectrum, but
could be identified by the Bielstein test. 2S The green flame
indicated that bromination had occurred. When the same method
was applied to the bromination of sesquixanthyl fluoroborate,
the Bielstein test was negative, even though the reactant
changed color. Neither the IR (IR Figure 15) nor chemical
tests could prove that a reaction had occurred.
Since a better synthesis method to brominate benzyl
sesquixanthene could not be find, we tried to nitrate benzyl
and butyl sesquixanthenes. We utilized a mixture of three
parts nitric acid and one part sUlfuric acid. At room
temperature, benzyl sesquixanthene dissolved instantly, but
the product became pitch like at about 80De. What substitute
was formed is unknown. After this procedure failed to give the
desired product, we tried concentrated nitric acid. It seems
that nitration in cold nitric acid was very slow, even after
twenty hours. In hot nitric acid benzyl sesquixanthene
dissolved faster and a reaction occurred. The product obtained
from nitration was also green. After neutralization and
filtration, the cotton-like product was analyzed by IR. From
the IR spectrum shown in Figure 14, there was no stretching
peak at 1600-1500 cm-I and 1300-1250 cm-I • Around 3447 cm-I ,
there is a large peak, which represents the 0-8 stretch. Since
these peaks are all located within the area of aromatic
absorption, we cannot be sure whether nitration was successful
21
or not.
Nitration of benzyl sesquixanthene was not successful.
From the IR spectrum, Figure 10, we can see that two peaks
appear at 3406 and 3476 em-I, and it doesn't show CSp2_B stretch
in the range 3000-2900 cml• Obviously, the protecting group
was too weak to withstand oxidation by nitric acid.
Oxidation of benzyl sesquixanthene with potassium
permanganate was difficult. Basic, neutral, and acidic
reaction conditions were attempted, and different ratios of
potassium permanganate to benzyl sesquixanthene were tried.
Generally, oxidation by potassium permanganate occurs rapidly
in basic solution. Treatment with potassium permanganate in
basic solution failed. Boiling for twenty-four hours in
neutral solution also failed. Although potassium permanganate
will slowly decompose in acidic conditions, its high oxidation
ability was critical in this reaction. oxidation occurred
after sUlfuric acid was added and the reaction occurred very
rapidly. According to IR Figure 19, the wide peak at 3500 em-I
may be due to moisture. The peak at 3081 em-I was aromatic C-B
stretch. The aromatic absorption peak at 1600.8 cm- l was
smaller. Since the IR spectrum shows methylene CSp3-B stretch,
there are two possibilities. One is that the sample was not
pure enough, the other was that it was not cleaved by
oxidation. In the IR spectrum, the aromatic major
characteristic peak 1600 cml was less intense. Other peaks,
such as 1464 and 1047 cm- l were unchanged. c-o-c absorption at
"
22
1267 cm-1 was also present.
The oxidation product was barely soluble in non-polar
organic solvents, however these product did dissolved in
common NMR solvent after several days. Although several
solutions were prepared for NMR analysis, none of these gave
satisfactory results because they were too dilute.
sesquixanthyl fluoroborate seemed easier to nitrate.
Although neither IR and NKR spectrums can distinctly indicate
that the -HOz function group was present, we can say that
nitration was successful. This conclusion is based upon both
the iron (II) hydroxide testZ6 and the sodium fusion testZ7 ,
both showing positive reSUlts. Further, the product after
nitration showed more intense fluorescence than the un
nitrated material.
The reaction to reduce -NOz to -NHz was unsuccessful,
although the color of the product after reduction changed from
yellow to orange and to reddish orange. Neither the IR, NMR
spectrum, nor chemical tests indicated success. There was no
evidence of a color change caused by the SUbstituting amino
group. If -NHz was successfully attached on the aromatic ring,
it would be expected to be mostly meta substitution because of
-0- group attached at both ortho position. If an amino group
occupies the meta position, the compound would not show a
color change. Z8
"
23
CONCLUSION
synthesis of a bromine-substituted sesquixanthene was
successful. In the bromination reaction, the sesquixanthene
whose central carbon was protected showed better results in
terms of higher yield and fluorescence than those whose
central carbon was not protected. But in cleavage of the
protective group, an improved oxidation method needs to be
developed.
synthesizing nitro-substituted sesquixanthene was also
successful. This succeeded whether or not the molecule's
central carbon was well-protected. Nitro-sesquixanthene has
high fluorescence and high solubility in both polar and
nonpolar solvents.
24
REFERENCES
1. Lund, H., J. Am. Chem. Soc. 49, 1346, 1927.
2. Bunikiene, L.; Ramanauskas, E., Chem. Abstr. 69, 113233W, 1969.
3. Liu, Shaopu and Liu, zhongfang, Fenxi Huaxue, 10, 464, 1982; Chem. Abstr. 97, 229295, 1982.
4. Dobkina, B. M.; ZUbynina, K. B.; Nadezhdina, G. B., Khim. Metody Anal. Niobiya Splavov Ego Osn. 58, 1970.
5. prabhu, B. N.; Khopkar, S. M., Talanta, 25, 109, 1978.
6. Kuznetsov, V. I.; Kleschel'skaya, E. I., Agrokhimiya (2), 148, 1970, Chem. Abstr. 73, 41531z, 1970.
7. Badischi Anilin' soda-Fabrik A.-G. (by H. Finkenauer; H. Ottervach) British Patent 902110, 1972; Chem. Abstr. 57, p12664b. 1962.
8. Antropov. L. I.; Kozlob, E. I.; Barmachenko. I. B., Chem. Abstr. 82, 46714g, 1975.
9. Soares, V. M.; Rodrigues, R. A., Chem. Abstr. 94, 76101, 1981.
10. Brazier, J. N.; stephen, W. I., Analytica Chimica Acta 33, 625, 1965.
11. Rao, N. V.; Dutt, V. V., Chem. Abstr. 74, 105686v, 150688X, 1971.
12. Coulter, A. K.; Schuster, I. I.; Kurland, R. J. J. Am. Chem.Soc. 87, 2278, 1965.
13. Ohla, G. A., Angew. Chem. Int. Ed. 12, 173, 1973.
14. Theilacker, W.; Schulz, H.;Baumgarte, U. ;Drossler, H. G.; Rohde, W.; Thater, F. ; Uffmann, U., Angew. Chem. 69, 322, 1957.
15. Conant, J. B.; Sloan, A. W., J. Am. Chem. Soc. 45, 2466, 1923.
16. Neunhoeffer, 0.; Haase, H., J. Chem. Ber., 91, 1801, 1958.
"
25
17. Soares, V. M.; Rodriques, R. A., Chem. Abstr. 94, 76101, 1981.
18. Fold, V.: Hawes, J. Chem. Soc. 2102, 1951.
19. Deno, N. C.; Jaruzel, J.; Schrieseim, A. J.,J. Org. Chem. 19, 155, 1954.
20. Oldrich Valcl, M. Se.; Irena Memcova; Valelav CUk, CRC Handbook of Triatylmethane and Xanthene Dyes. 4, 291, CRC Press, Boca Raton, FL, 1981.
21. Oldrich Valel, M. Se.; Irena Memcova: Valclav Cuk, CRC Handbook of Triarymethane and Xanthene Dyes. 3, 233, CRC Press, Boca Raton, FL, 1981.
22. Vanallen J. V., J. org. Chem., 23, 1679, 1958.
23. Koji Nakanishi; Phillippa H. Solomon, Infrared Absorption Spectroscopy, 1977, page 20.
24. Douglas, C. N.; Michael P. D., J. Org. Chem. 65, 1977.
25. Williamson K. L., Macroscale and Microscale organic Experiments, D.C. Heath, Lexington, MA, 1989.
26. Williamson K. L., Macroscale and Microseale organic Experiments, D.C. Heath, Lexington, MA, 1989, page 660.
27. Williamson K. L., Macroscale and Microscale organic Experiments, D.C. Heath, Lexington, MA, 1989, page 649.
28. Lucas J.; Pressman D, principles and Practice in organic Chemistry, wiley, New York, 1949, page 429.
29. Slocum, D.W., and Jennings, C.A. J. Org. Chem. 14, 3653, 1976.
,,"~,~
f'll" . 1~11fi'
'111' :l
l·~
26
Figure 1: IR spectrum of 2,6,2',6',2",6"
hexamethoxytriphenylcarbinol
(KBr pellet)
I -----,--- I -----, I
3000 2000 1000 WavenuITlbers (crn-l)
......-l C";)
C'
W
ree co
c::. ~ o oc:l_
c:o t:O ~OC\l _
......-l .....-l
1c:"'J
~ f'I:O
~~ ......-l......-l
Res= 2 cln-lIR spectrum No.1
200
Q) (J
~ ro
l;")
+oJ
.1100
I N '-0 Q')C,\l
0)1 ......-l
c:\l C'-:J'-0 .""
~-• l;") ~CO
~
c:"'JC\2C' N
I 0
2,6,2' .6' .2" .6" - hexarnethoxytriphenylcarbinolL--___ .. _
t '" ~tll
lIJ~'I>. . ilr,l ~'jl~
"l~1
1'1
:~,. I'" j
"h
'.I'
27
Fiqure 2: IR spectrum of 9-(2,6-dimethoxyphenyl)-1,8
dimethoxyxanthydrol
(KBr pellet)
l:'
c:'\l o c:o
'"Eb
~ ~
I I
--I
l:'--I rn
I
1000
C\l •
~-
~
co C"j-I I
~ - f'.. ~ c:o ~ C\l co f'.co ~ N
--I --I -Res= 2 clll.-1
I
2000 Wavenurnbers (cnl.-l)
C'J • I
M I ~m-.,.....fC\.rt' •
C'?co ~t:":l C\lr:o
r:\l
I
3000
~
--I o ~
r.;>J
U')
C\l o lr.l C":l
9--(2.6--diIllethoxyphenyl)--1,B-diuH:·thoxyxanthydrol
Ir spectrulU No.2
0
50
100
Q) CJ ~ «S
+J ....,J..... Ei (Jl
~ cd ~ ~
Tra
nsm
itta
nce
0 a.
0
~
0 0
i "~
UJ
I'C
r:ll ~
~
~,
~ ~
~
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~ ::r ~ p. ., 0 """'"
~
~
til
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f"'"
"'$
~ S
2 0 , W
~
0 0 0
3496
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3406
.1 -
~
~
til II N
I":i S I P-'
~
)I)
~
I'C =' ~ S ~N
I'C
0
""I
0 tn
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~
'-'
1618
.2
1485
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1272
-13
4
~
0 0 0 1~2ttt~~6
_
746.
4 -
580.
5
Ell
••PI,,,, I'':;
'li,"1 I:l~
If
':~ .II
, ..;!~
. " i ' I
29
Figure 4: IR spectrum of fluroboric sesquixanthene
(KBr pellet)
200
lD
co Q.) C» (;) o
C"':l~ .s 100 ~ • .-4
S (fJ
~ a:I
~
I I 'I If' o ,~ l'-~ C"':l
lQM ceo• Lr:> ~ o~~ .....fIccC\l ~co U":I~ c:o <:0O':'......-i ll.l~ .,....ri U":I
~ o....... "" - -
2000 1000 Wavenurnbers (crn.-1)
IR spectrull:.l. No.4 Res= 2 clTI-l
f'luroboric Sesquixanthene
3000
I
--
~ttl
~
ro ~
(IJ'N
~
<'ll
I~
('j
(+rJ
) 11
ro C!J
~
w~
"'" ::l
0~
~.
0
Z~
0
0~
.
I~
01
iJ'
~
ro ~
~
=:l <'ll
<1
lro
Ul
ctI
I II
::l I
~
I
N
S ,:'
jI
c'~
s C1
l 0
11
0I
til
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I
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I S
I I ......
I I I I I I
I 0
! 0
i 0
! I
Tra
nsm
itta
nce
N
0
0
II II
3025
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1614
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1460
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1266
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-
I 77
3.4
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700.
1 -
I L
630.
7 - 54
9.7
-
I I I I
Tra
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itta
nce ro
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ttl ~
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r.tJ
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-
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32
~ ,!
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'~" , lSIl'1~~"1
Ilrt il~',' 11,; III'",~.
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Figure 7: XR spectrum of the product obtained
bromination of benzyl sesquixanthene
(KBr pellet)
from the
l\J,,: 1 1'_:1
,,: :i'''~1
:~ iWi;
I:! J'II'.;<
w
,I t' I, II' I~ ~, jl: I
f~"
Tra
nsnl
itta
nce
0 lo
0 N
0
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ttl
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r.JJ
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.... al
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c,.:l 0 0 0
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a'N
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2
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1052
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869.
8 77
3.4
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-
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33
~!.!.. ~: ,~" l QJl~~!'io
ti Figure 8: IR spectrum of product obtained from the lr:~""
:'~':: ij,-,,,,,Ii! bromination of butyl sesquixanthene~:'~2":i!,L I~:
~~il~ (KBr pellet)'::~r,~
il~' f~i~ i~li!
I: 'gl~ I :~~
1 11 ".
J .',"
;:: ~~I : ,,.JIll,!
I:'~I':
Tra
nsn1
ittan
ce
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08
z 0
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00
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.
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.....
I~
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-<
Po'
r.tJ
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=:"
N
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It
=:s
(~
O'"
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96
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75.8
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1050
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0 0 0 87
2. '7
-77
3.4
-
622
-
I
'--
J
34
\.. ~~r,rl
.....w,:'1 Figure 9: IR spectrum of the product obtained from the
!~.~: ~~ oxidation of benzyl trinitrosesquixanthene'~~
' • I~;"'J' (KBr pellet),JllP'li~
,(1II 'ilflil
II~
!~ ~~: I~ )"1'".,. ~' ",-,
~;~ f!~
--~
I
IN o "<:t4(.....
C\l ['"t-
ex:::> 0)
CO CO
1000
o::J
o o c:o -
Res= 2 crn-l
2000 Wavenurnbers (crn-l)
t>:I
o CO CO C\l
......... -CO o C":l
3000
IR spectruIU No.9
3,3' ,3"--Tribrcnnosesquixanthene
0-1
I I ...-j4
.....-i
eJM~ C":l
~ r- l'
~~ "<:t4 0
........ .....-i .....-i
<:t>(.) 90 ~ ...., ~ ~
+-> .~
S rn Q CO ~
E-<
35
i
~~ , ,~'l~~ '~,.,
'1"11 tl'~:I~:
~r"~~
:1:~~I
I
I~.~~".~.': j~ -~.I~ ·~I ;~~: ~.~~:
~,
t~ ~~; ~~~
~
Figure 10: IR spectrum of the product obtained from the
nitration of fluoroboric
(KBr pellet)
sesquixanthene
--
0
~
~
~ 0 ~ I~ ....
(1
~
I~. ::l ....
~
0 ~
[,(] t'tI [Jl
~ ~
....
~
~ ::l c-+ =r
t'tI :::l en
~
~
00 ~
~
(';J
r+
~
~ S
Z
0 . ~ 0 ::0
~
00 II N
(') S
I ~
~
~ <1 \tI ~
~
=
0 \tI -~
00
(';J S
I ""'"
Tra
nsm
itta
nce lV
....
00
~
0 0 0
3054
.1
-
N
0 0 0 ~
0 0 0
I
1633
.B
-15
49.7
-
1465
.8 -
1338
.5 - 12
59.4
- 1164
1~
.'Z5
--
784
-
559.
3 -
-
36
Fiqure 11: IR spectrum of the product obtained from the
reduction of fluoroboric tribromosesquixanthene
(KBr pellet)
C":J
o:l .0 lQ
q ~ """-'I.
tC:l CO l'
l,Q.'l--I
~ ~
C\} co-
1000
~
0:>
l:'-:I 'lQo IN lD C7J ...... lD • "......ll ~
~ a:JC"':l ..0~ '"i" ......
-.t'
~ f;'? ~ -
2000 Wavenunl.bers (CIll- 1)
3000
IR spectruIll No.ll Res= 2 cln-l
Reduction of fluoroboric trinitrosesquixanthene
o
30 -I At" I. ~
20
v Q
~ ~ ~
+-'..... S 10
r-rn 1:::1
~e to 0Eo-< C'j
37
~1
I ~ ';;+0'
it' Figure 12: IR spectrum of the product obtained from the
nitration of butyl sesquixanthene
(KBr pellet)
i
38
'1.,1~r:'~.~l,tl' Figure 13: IR spectrum of the product obtained from ~:~:' :: r the reduction of butyl sesquixanthene~< :1
(KBr pellet)~.~l !r,.~".
..Ot.f -
IR spectrum No.13 Res= 2 cln-l
The product of butyl sesquixanthene nitration reduction
-I
C":l 0')
..0 U')
C:l C\l .....-l 0:>
C:O' ;.I
t:O ~
~ ~ o -
1000
COI~
~ I ~c» - I cO-~lO
ll? C"1Y.l N ~co.....t:t4......-i
lQ aD "'" .,.......jc:.o -
~ .,.......j
..0
~ C'? co-
I I
2000 Wavenurnbers (crn-i)
c:J C\l co o C':l
3000
o
40
Q.I e..;, c:: ~ 20 ~-S ct:l t:1 ro h
Eo-<
40
Figure 15: IR spectrum of the product obtained from the
bromination of fluoroboric
sesquixanthene
(KBr pellet)
Tra
nsm
itta
nce
ro ~
0
0 0
-~ -~
~
0
1'.ll
11
0 0'
~
(0
('j
0 11 ~
11
~
~.
('j
S ~
0
3054
.1
-~
.., .... 0 ., 0 S
'Z
0 . ,... C,i1
~
0 0
0
1
00
I<'C 00
~
('D
1'.ll II
~ <: ('U D
,Q
~
~ ....
('~
S i'<
~
D
~ ::r
('j S I 10"""
0'"
t-J
('U
0 ~
0 -0 <Ii
:= <Ii
0 S I 16
36.5
-~ -
1550
.7 -
1465
.8 -
1338
.5
- 1259
.4 - 1164
-
~
0 10
~~?P
'§ -
0 0
ftat9
-
559.
3 -
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I-- C. Cit, 1'--- I I -CH, CO +- - CH'-cr' - CH.-St+I -CH,O- ----~H.C.,.C
HC - eH I - CH, A. -II -CH.N-
- C CH,O--C CH, ,. - ~- C CH, C ....""'... - CCH,O I -CCH,N -CH•...• -", CH. 0 - ~C CH,C-
I -·CCH. OJ -HC:C
-A.CH,N- I .....tlGI IIH
7010'0 • • •f-I '.3 ".CF,COOH P"id,n.I.1 P,.id,no" I ';IridiMlIII C. •.CHC'.
10.0
r
HITACHI PERt<IN ELM!:R CHAII' NO.•~,.aa ~J'.~
, .
----I-- CHO ~ ~ :
"" : A_lie 'itt
• • •1-, l.:t ,-.C',COOH p,.idinel.1 P,'id.... ' ~ I Pjl'idintl,1lC, ,.CHCI,
A,·H
2
I SEC
OPER,,'OR:
.wnl' flIIE: I!I :t001l SOSEC 0
DATE: 04/15/9]
CH'" NO.'~J.aa ~".~
H. lEvn :
11111".115 :
I .. 1-' i 'il lULl Ito LEVEL: _
CAIN:
swnl' WIDTH:
I .:-:l!!1--- l!!!l-'" 1:J
c..---r .!I-J
lIE, EIlENCE : _.!"S I SOLYEN' : ~ _ CONC: . __ . _
AlIl'LnUOE : 1] snC'RUII: ~
INTEGRAL'
SAIIPLE : __~=!'_~~!~!... _
'H SPECnUll NO. :
----_ ....... . F1UE"e&iwh:-=]
t·· :.IS
- CH,'SIT
10]040so ",,0•CH,Cr,
10
HITACHI PERMIN ELMI!R
10••• •(CH,', SO (CH, ,,CO C'cloht..... CH,PIl
CzCH,-- - CH,COT - CH,-C-.-I -CH,O- ----.:H,C~C HC - Cit -----+-- I - CH,A, -I
I -CH,H--C-CH,O--CCH,"' ~_CCH'C]m;""',,,
- CCH.O I -CCH,H -CH, -'I<CH,O -~CCH,C--
I -·C CH, N -ItC;C ....idn -A, CH,-N- I ....ino
HH- I - IIH
7010'010_0
r
43
Figure 18: NMR spectrum of 9-(2,6-dimethoxyphenyl)-1,8
dimethoxyxanthydrol
Solvent: CDC13
Reference: THS
..
.'
SIC
04/15/9JDATl :
OPlRATOR:
aWup TllIl: 11300/1 10UC 0
",Lun: _ CAIN:
--_......• II •
FILTER HI; I l:l!I:n!IOI _ OJ
l1li1 SWl: ':ID~~i~ ·ITJ
I i II I its... '1I j i:J
~•II I::tIt
II
H,LEvn:
REFlRlNCl : -~ I SOLVENT: JlCJ:.L, .......; CONC: _ _
AIiPLITUDl : SPlCTAUN: .l1 ~
INTlGAAl'
1'II.rll'lllALJ
NH ,m,61.
II ,.I A!IIU.S :
s C, ,.CHCI, CH,Ph
I A,H I C=CH'-I- - CH,COT - CN"C1 -CH,-CH,O- ----.:H,C~C
He - CH I - CH, fI, -II -CH N-
--C-CH,O--CCH",---= ~-CCH'C be - CCH;O I --CCH,H- -CH, fm IS -~. CH, 0 - =C CH,C-
I -"C C11, 11 -Ite;c - Ar CHI N- I Imlf'O
I IIHAI: A_tie: " ••
'00
'H SPECTRUM N~ : )
S~NPlE : _
9-12.6-dl~~tho.yhpenyll
1.8-dl~~tho.y.anthydrol
90 80 70 60 10 40 , 0 1.0 10. .. . - .... II "'.CF,COOHp"id.n.(.' P"Nlinll ,I Pjl'i41inel'I CH,C', 11,0 ICH, ),50 (CH,I,CO C'clah.....
HITACHI PERt<lN ELM~R CNa., "0....,_ l7D(u'08
. '
I
LiLl...!lI...J
H, LEVU:
I " I. i UL:l_iAl
IWU' WIDT":
• iT."". .HI 'T' i ]----_ ....... .
t'·T.5
II I m~~:~':'::_~"_1
AII'LITUDI : I'ICTIIUM : .1.l .. _ I"TEGllAl . H _
• , ,CH,-StT-
No LUll: _
CAl" :
II
• II ~O_
10.0 10 70 10 40 3 a 1.0 1.0'0 • • • • •• ••• •1-11.3 ".Cr.COOH P,.idin.I.1 p,.idine" I P'......"I CH,C'. 11,0 '-O....n. (CH.I.50 (CH.I,CO C'elo/l...... CoH•.CHCI. CH.OH CH,pIl
t- -, I I .A.H c. CH.---- - CH, CO, - CH,-C-:-r- -+-CHO -CH,O-- ----.:H,C-C1
HC - eH I - CH, A'-I-CH N--C CH,O--C CH, ~ • ...:.... ~-C CH, C-r.:"_mbe I
-- C(H;O- -CCH,N- -CH,·il"""I - A. eH. 0- - ~CCH,C--
-~CCH,,,- -HGC _idn -A.CH,·N-- tonino
'" : '-lie .ift NH-- I IfH
HfTACHI PERI<IN ~eA
I I
'H 5PlCTRuM NO. : ,
SAMPLE: ..5uquLulltheu__
flLUII III: I llILllI!IT:::J
IWU' TlIII: 11300/IS0nc 0 '~C DAU: 05/01")
OplRATOII :
IIfllAlIllS :
CMllt 1m, ...,_ S7'I1(' ••.,
. '
A, M-4-CHO I I
AI: "-lie ,...
05/04/9)
CNallT 110.'.,_ J71YJO ••~
DATE:
OPlR"TOR:
IIUI"-" :
r7 JT::I T I I I J T---_......• II •
'IL TUI ... : II lbLL"I.J
IWUP TillE: 113OO/l505(C 0 I SIC
H, LEvn : 1 S'lIM:
I LITTI!lJ
SWUP WIDTH:-- --""
t· TU ::-t - CN,'It;-
10405011,0
SAIIPLE : •
I • I. I llLiDLJ
'H SPEC TRUll NO.: 5
Benoyl Selqul •• nthene
UFUlNCE : __ nts I SOLVENT: __ • __ .Da:.l,.. _ COMC : ._ ..... ' , ... _
AMPLITUDE : SPlCTRUll: 11
INTEGllAl . ::::..:~~~~:~:==
N.LEVEl :
•CH,CI,
HITACHI PERKIN ELM!!'"
10 ] 0 z.o••• •ICH,I, SO (CHoI,CO C'elah...... CH,P"
C· CH, -- - CIl, CO T - CH,-C..--. I -CH,O --':H'CJ~
HC - CII -----l.. I - CH, AI -I -CI1,N-I --CCH.O--CCH,·~I- ~-CCH'C ""mb...
CCH,O I -CCH,N -CH, - A. CH, 0 -:C CH,C-
I -~CCH. N -IlCoC
NH ,mid.. - Ar 1"' M- I NH ,mlllO
70
II
10
'.
to • • •1-11.3 ' ••C' ,COOH P"id.n.f.1 P"id'Ilf' rI Pjl'i4lilttf'"C, ,.CHCI,
100
rT'
SAMPLE: __ . __ • __ ••__ • _
'H SPECTRUII NO.: 5
SIC
0510419]
CHIIT 110....,_ ~,.•••
DATE:
OPERATOR:
II
RElla-liS:
r·. _---y0...-_. , .. J JaLJI
H,LEYU:
REFERENCE: _ llIS I SOLVENT: _._._.Da:l,... CONC: .. ..... " ... _
AIIPlITUDE : SPlCTRUM: .... .!.~_._. _ IHTEGUl . __ ._.~_ •• _
_.... _......• I' • flL TER HI: II
c:nLtJIIIlI. :J
SWUP TillE: 1l300/150UC 0
'"nayl S••qul.anth.nl
H, LEYU : .... ._
U'N:
I ULIi!lJ
SWUP WIDT":
I ,-;,..... let.,. , L:J
t·· T.S
::-I - CH"St;
10
l!
]04050H,O•CH,CI,
60
I
70
II
10'0 • • •l-11.3".Cf.COOHp,,;d,n.C.1 P"id,nt'11 Pjl'ilI"","C, ,.CHCI,
A, H
. •• zI r .~o.,.~·· 0 C'CH I (eH·
_ l "' ~ ~~, I I <~.. ,I," ',",I" •'" ------"- I '",..' <"......
I -ICH,O - - CH, CO.!... ...
I ' - ,",'< ., . ~ - '" .--.:~..c ..,. - CCH O-CCH 0 -ell H''''-.I H,C~C,I -". eH 0' - I' CCIl",,"':",_ -C -_......' I -.:""< ,",' ~ C ~H, C~_", CH N ·e eH. H. CH.·il"."mb...
I' - -lIe;c bNH·m,no J I
HITACHI PERK IIN ELM!!'R
100
SIC
--
05104/9 )
OPERATOR:
DATE :
REMARkS:
CHAR' MO. 1"'_ .C7.".,~
SWEEP WIDTH: ... "'" ........
H, LEVEL:
[2! 1·'.-1
I -. I.A I , ... LiAI j
H.LEVEL:
lOAIN:
CIAr:r:r r::r J.-J....-,. ....• •• • fiLTER Ib: X
I CiG r ;0. I =:J
SWEEP TIME: C1300/150SEC 0 1
REfERENCE: THS I SOLVENT: DCCl, CONC : .. _
AMPLITUDE: SPECTRUM: L __. _ INTEGRAL: _
SAMPLE: _._. __
'H SPECTRUM NO.: 6
Butyl lesquixlnthene
Ib
II
~.. TIIS ~
·St"":'""- CH,
\.03.0
T'
4.0
HITACHI PERKIN ELMER
5.0",0
Z.O•• ••• •p-D"u.I (CH,I,SO (CH,I,CO C,c/oll.u•• CH,OH tH,Pft
I I -CH,'COT - CH,·C.....!.I -,CH,O -I-':H'CUJ-- - CH."A, --tH N-I -ttH.O--C·CH,·_,~ --C·CH,·C
- CCH,O I -CCH.N- ~ -CH, m,mblll - AI CH, 0 - -C CH,C-
I --CCH,H -HC:C -A,CH ·N- II t NH ,m,na
•CH,C',
HH ",ud"
'.0
I
AJ : AP'CIMtlC IIftl
10.0 '.0 '.0 7.0• • •I 1.3 ".Cf,COOH P,ridi.,C.I P,rid;."71 P,ridMteI"IC,H•.CHCI,
Ar'H C· CH,-....;-------11 I HC • eH _
'1'
47
Figure 22: HMR spectrum of the product obtained from the
bromination of benzyl sesquixanthene
Solvent: Deuterated acetone
Reference: TMS
"-Ttill Il" j "J H. LEVU:
SIC
OVI~/lJ
OPERA TOil :
DATI:
IlfllA1l1lS :
H, LEVEL: •
SAIN:
SWU, WIOT":
I .-:-t"'. /!!!it", L:J
~
UnRINCE : __~ _ SOLVENT: =, _ CONC: ----------------------1 AII'L1 TUDE : SPECTIlUII: ~~ _ INTEGIlAl' _ L _
'H SPECnUM HO I
SAMPLE ~ ----------n-------1
-_ .• •• • 'IL T[II HI; _
tDLI:!!!KI __ ]
SWU, TIllE: .3OO/15051t 0 1
'en.yl trlbrOGlo
8eequlManthene
t· TU
::-I - CH,'St;
10
II
•
10.0 to 10 70 60
a.· a.....hC Il~.
""-'LH' ,=»ERMfN ELMI!R CHal' 110.••r_ T7"''''06
48
Figure 23: NMR spectrum of the product obtained from the
nitration of fluoroboric sesquixanthene
Solvent: Deuterated acetone
Reference: THS
---l--CHO' I A,·H
AI: __lie ,oe,
•
1 SIC
05/01l/9)
II!IIAIlIIS :
DATE :
OPIIIATOII ;
CMlII' lID. 4.'_ J7'V".~
... LEVEL: ._ .. __
5AI" : c-Ul!llJ
III.UINCE : __.!!!~
~:~~~N.~~~~~~~_~._.~ AIIPLITUDE : SPICTRUII: . U •• __ ._. _ INTEGIIAl : .... !_~_.._. _
",LEVU:
.1. ...... JLiLl
IWIIP WIDTN:-- --""
SAIIPLE : • .._. __
Fluoroborlc Trlnllro· •••qul ••nthene
'H SPECTIIUM NO. :
[ I I.-------rT rJ":J I:J-_ .. .. . 'llTlIt~_:::J
IWUP TIllE: 1)300/IS0SEC 0
t·· 'liS
-1.0
II
]0 1.0•• ••• •p-O....n. ICH,I.50 ICH,I.CO C'clo/l...... CH.OH CH.P~
40
..
50H,O•CHIC'.
HITACHI P£R~IN ELMER
.0
I---- C· CH·I '- I I -CH, COT - CH'-C
J ' -CH,-St+I -CH.O- ----.:H,CkC
HC . eH I -CH, A, -/
I -CH,N-- C CH,O--C CH, ,, ~- C CH, C mb
- C CH,O I --C CH, H- - CH, "" tiS - ,II, CH, 0 - =C CH,C-
I --eCH,N -HCoC ,mldl, -A,CH."H- I ,mino
NH - I IIH
m I
'.0 10 70• • •!-1l.J'••Cf,COOHp"id;n.I.1 P"idi.... )) Pil'....'''. C. ,.CHe',
10.0
I
I, YILIN QIAO , hereby submit this thesis to Emporia
state University as partial fulfillment of the requirements
for an advanced degree. I agree that the library of the
University may make it available for use in accordance with
its regulations governing materials of this type. I further
agree that quoting, photocopying, or other reproduction of
this document os allowed for private study, scholarship
(including teaching) and research purposes of a nonprofit
nature. No copying which involves potential financial gain
will be allowed without written permission of the author.
LLf/;i/} 0 laD Signature of Author
September 1st, 1994 Date