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Structures of pyridine and quinoline-n-oxides
~e~ar~rn~~t of
Chemistry, Denton,
(Ree*~ived in IKA 24 June 1970; There have been few reparts aromatic
ring
analyses
have been completed
North Texas State Texas
76203
received
in uic for
in the literature
compounds containing
bond.
an two such compounds,
Z-hydro~~etby~~~r~dine-~-oxide
(II]
x-ray
data
the
structural
Three dimensional
lvt97Dj
propertiesof x-ray
structural
8-hydrox~uinoliue-~-oxide (I), and
in an attempt
to provide
such infornratian.
(II)
CT.1 The preliminary
~~~bli~~t~*n 7 July
concerning
the N-Q dative
University
are:
crystal symmetry
space
moIec~os
group
per cell
III
monoclinic
P2,/c
4
12.136
4.921
13.138
-0.3576
U-I)
monoclinic
P2I/C
4
7.079
8.946
10.599
-0.2254
a
b
C
CbSS
Botk structureswere solved by a direct phasing proceduredue to Long (I) and were refined by full matrix are 0.053
least
squares
and 0.111,
techniques.
The final residual factors (R) for (I) and (II)
These are
respectively.
two features
of
interest
in the structures.
The N-O bond distancesare 1.333(Z)i and X.332 i for (I) and (II), respectively. These are in good agreementwith N-O distancesreportedfor sin&tarmqmmds pyridine-N-oxide both
structures
In (I), length
(23,
is
1.42 i.
and X,X!& i in tetrafpyridine oxide~cop~r(II)pa~hlorate(3). Also,
exhibit
the hydrogen
sach as I.33 i in
hydrogen
bonding:
band is between In (II],
intramolecular
the bydroxyf
the hydroxyl
hydrogen SW5
in
hydrogen atom is
(I) and inttwmolecularin (II), and the dative
oxygen;
bonded to an M-oxide
its
oxygen
atom
3204
$10. 57
of a neighboring,symmetryrelated molecule. Its length is 1.99 i. These data appear to support a correlationbetween the strengthof the hydrogenbonding and the length of the N-O bond as proposedby Hanson (4) and Hanson and Hum1 (5) in
their studies of the compounds,
myxin and iodinin;that is, as the hydrogenbond to the N-oxide is strengthened,the N-O distance is lengthened. This effect is attributedto the delocalizationof the nonbonding electronson the oxygen atom affectedby hydrogenbonding which results in a decrease in the ionic characterof the N-O bond. The N-O distancesin myxin and iodinin are 1.32 and 1.31 i, respectively,when the N-oxide oxygen atoms are affectedby intramolecularhydrogen bonding. However, the additiona N-O bond in myxin is unaffectedby hydrogenbonding and its distance is given as 1.28 i.
Other featuresof these two structuresappear to be normal: the pyri-
dine and quinolinemoietiesare planar within experimentalerror and bond distancesand angles are as expectedfor these two types af aromatic systems. Acknowledgements:We wish to thank the Oak Ridge National Laboratoryfor the use of its facilities. We are gratefulfor supportby grants from the Robert A. Welch Foundationand the North Texas State UniversityFaculty ResearchFund.
References: (1) R. E. Long, DoctoralDissertation,Departmentof Chemistry,Universityof California, Los Angeles, 1965. (2) J. C. Morrow, U. Dincer,and B. P. Huddle, American Crystallographic Association, Winter Meeting Abstracts,March, 1970. (3) J. D. Lee, D. S. Brown, and B. G. A, Melsom, Acta Cryst.,825, 1378, (1969). (4) A. W. Hanson, Acta Cryst.,E,
1084, (1968).
(5) A. W. Hanson and K. Huml, Acta Cryst.,E,
1766, (1969).
Chemistry, Denton,
(Ree*~ived in IKA 24 June 1970; There have been few reparts aromatic
ring
analyses
have been completed
North Texas State Texas
76203
received
in uic for
in the literature
compounds containing
bond.
an two such compounds,
Z-hydro~~etby~~~r~dine-~-oxide
(II]
x-ray
data
the
structural
Three dimensional
lvt97Dj
propertiesof x-ray
structural
8-hydrox~uinoliue-~-oxide (I), and
in an attempt
to provide
such infornratian.
(II)
CT.1 The preliminary
~~~bli~~t~*n 7 July
concerning
the N-Q dative
University
are:
crystal symmetry
space
moIec~os
group
per cell
III
monoclinic
P2,/c
4
12.136
4.921
13.138
-0.3576
U-I)
monoclinic
P2I/C
4
7.079
8.946
10.599
-0.2254
a
b
C
CbSS
Botk structureswere solved by a direct phasing proceduredue to Long (I) and were refined by full matrix are 0.053
least
squares
and 0.111,
techniques.
The final residual factors (R) for (I) and (II)
These are
respectively.
two features
of
interest
in the structures.
The N-O bond distancesare 1.333(Z)i and X.332 i for (I) and (II), respectively. These are in good agreementwith N-O distancesreportedfor sin&tarmqmmds pyridine-N-oxide both
structures
In (I), length
(23,
is
1.42 i.
and X,X!& i in tetrafpyridine oxide~cop~r(II)pa~hlorate(3). Also,
exhibit
the hydrogen
sach as I.33 i in
hydrogen
bonding:
band is between In (II],
intramolecular
the bydroxyf
the hydroxyl
hydrogen SW5
in
hydrogen atom is
(I) and inttwmolecularin (II), and the dative
oxygen;
bonded to an M-oxide
its
oxygen
atom
3204
$10. 57
of a neighboring,symmetryrelated molecule. Its length is 1.99 i. These data appear to support a correlationbetween the strengthof the hydrogenbonding and the length of the N-O bond as proposedby Hanson (4) and Hanson and Hum1 (5) in
their studies of the compounds,
myxin and iodinin;that is, as the hydrogenbond to the N-oxide is strengthened,the N-O distance is lengthened. This effect is attributedto the delocalizationof the nonbonding electronson the oxygen atom affectedby hydrogenbonding which results in a decrease in the ionic characterof the N-O bond. The N-O distancesin myxin and iodinin are 1.32 and 1.31 i, respectively,when the N-oxide oxygen atoms are affectedby intramolecularhydrogen bonding. However, the additiona N-O bond in myxin is unaffectedby hydrogenbonding and its distance is given as 1.28 i.
Other featuresof these two structuresappear to be normal: the pyri-
dine and quinolinemoietiesare planar within experimentalerror and bond distancesand angles are as expectedfor these two types af aromatic systems. Acknowledgements:We wish to thank the Oak Ridge National Laboratoryfor the use of its facilities. We are gratefulfor supportby grants from the Robert A. Welch Foundationand the North Texas State UniversityFaculty ResearchFund.
References: (1) R. E. Long, DoctoralDissertation,Departmentof Chemistry,Universityof California, Los Angeles, 1965. (2) J. C. Morrow, U. Dincer,and B. P. Huddle, American Crystallographic Association, Winter Meeting Abstracts,March, 1970. (3) J. D. Lee, D. S. Brown, and B. G. A, Melsom, Acta Cryst.,825, 1378, (1969). (4) A. W. Hanson, Acta Cryst.,E,
1084, (1968).
(5) A. W. Hanson and K. Huml, Acta Cryst.,E,
1766, (1969).