J. Org. Chem. 1996, 61, 6404 6406 UV/Vis Spectroscopic Evaluation of 4-Nitropyridine N-Oxide as a Solvatochromic Indicator for the Hydrogen-Bond Donor Ability of Solvents
Anthony F. Lagalante,* Ryan J. Jacobson, and Thomas J. Bruno
National Institute of Standards and Technology, Chemical Sciences and Technology Laboratory,Physical and Chemical Properties Division, 325 Broadway, Boulder, Colorado 80303
The potential of 4-nitropyridine N-oxide to act as a solvatochromic indicator of the hydrogen-bonddonor ability of solvents has been evaluated. A linear free-energy relationship has been establishedthat is predominantly dependent on the Kamlet Taft
to the previously reported results obtained for pyridine N-oxide, 4-nitropyridine N-oxide possessesa solvatochromic effect that is located in the long wavelength ultraviolet region (λ
of the spectrum, making it a viable probe for hydrogen-bond donation assessment. Introduction
of a dissolved small organic probe, such as 4-nitroanisole. Similarly, by measuring the π f π* transition maximum
UV/vis spectroscopic measurement of charge-transfer
of a second small dissolved organic probe, such as
maxima of probe solutes in solution is known to provide
4-nitrophenol, in conjunction with the peak maximum for
numerical values for the intermolecular interactions
between solute and solvent. The most extensively ap-
be calculated. The relationship can be understood in
plied method of generating values for intermolecular
terms of a LFER, in that the transition maximum of
solute/solvent interactions is the method of Kamlet and
4-nitroanisole will not include contributions from the R
The Kamlet Taft parameters are , the hydro-
terms of eq 1. Replacement of the methoxyl group
gen bond donation ability of the solvent, , the hydrogen-
of 4-nitroanisole by the hydroxyl group of 4-nitrophenol
bond acceptance ability of the solvent, and π*, a param-
results in a probe solute that is capable of hydrogen-bond
eter that describes the dipolarity and polarizability of the
solvent. Using linear free-energy relationships (LFER),
the Kamlet Taft parameters can effectively model pro-
cesses in solution according to the general expression
ally determined using large organic or organometallicprobes,3 due to the extensive use of these probes as
polarity indicators of solvents. Often these large probesare insoluble in fluorinated solvents.7,8 In our laboratory,
where XYZ is the value of the solvent-dependent process
we are in the process of determining the Kamlet Taft
to be modeled, XYZ°, s, d, a, and b are the coefficients
parameters for alternative solvents which may be useful
determined from the LFER analysis, and δ is a polariz-
as replacements for chlorinated solvents. Many of the
ability adjustment term. The δ term is dependent on the
alternative solvents possess a high degree of fluorination
class of solvent to be studied; for aromatic solvents δ
(but no chlorine or bromine) resulting in zero ozone
1, for polyhalogenated solvents δ
depletion potential by currently acceptable mechanisms.
As a potential solution to the solubility problem encoun-
success in modeling solution processes as diverse as
tered when using conventional UV/vis spectroscopic
solubility,4 partition coefficients,5 and chromatographic
acidity probes in fluorinated solvents, the replacementof the methoxyl group of 4-nitroanisole with a group that
retention.6 Analysis of the coefficients of the LFER
is capable of hydrogen-bond acceptance is desirable.
provide insight into the dominant solute/solvent interac-
Such an approach was undertaken using pyridine N-
tions involved in a particular solvent-dependent process.
oxide;9 however, the π f π* transition maxima observed
As suggested by Kamlet and Taft, the determination
283 254 nm) resided in the absorption region of
and π* parameters using solvatochromic peak
many solvents themselves, thus detracting from the
maxima of select probe solutes is relatively straightfor-
spectroscopic utility of the probe. Recognizing the po-
ward. A value of π* for a particular solvent can be
tential utility of pyridine N-oxide as an acidity probe, the
directly calculated from the π f π* transition maximum
13C NMR chemical shift of pyridine N-oxide was used toestablish a LFER that was related solely to a dependence
* To whom correspondence should be addressed.
X Abstract published in Advance ACS Abstracts, August 1, 1996.
A probe that would more closely resemble the nitroaro-
(1) Kamlet, M. J.; Taft, R. W. J. Am. Chem. Soc. 1976, 98, 377. (2) Kamlet, M. J.; Abboud, J.-L. M.; Taft, R. W. J. Am. Chem. Soc.
matics typically used in the Kamlet and Taft approach,
1977, 99, 6027.
(3) Taft, R. W.; Kamlet, M. J. J. Am. Chem. Soc. 1976, 98, 2886. (4) Taft, R. W.; Abraham, M. H.; Doherty, R. M.; Kamlet, M. J.
(7) Reichardt, C. Chem. Rev. 1994, 94, 2319. Nature 1985, 313, 384.
(8) Reichardt, C.; Asharin-Fard, S.; Blum, A.; Eschner, M. et al. Pure
(5) Kamlet, M. J.; Doherty, R. M.; Abraham, M. H.; Marcus, Y.; Taft,
Appl. Chem. 1993, 65, 2593.
R. W. J. Phys. Chem. 1988, 92, 5244.
(9) Vorkunova, E. I.; Levin, Y. A. Zh. Obshch. Khim. 1984, 54, 1349.
(6) Park, J. H.; Jang, M. D.; Kim, D. S.; Carr, P. W. J. Chromatogr.
(10) Schneider, B. H.; Badrieh, Y.; Migron, Y.; Marcus, Y. Z. Physik.1990, 513, 107. Chem. 1992, 177, 143.
4-Nitropyridine N-Oxide as a Solvatochromic Indicator
J. Org. Chem., Vol. 61, No. 18, 1996Maximum of the π f π* Transition of Measurement of Solution Spectra. 4-Nitropyridine N-Oxide in the 48 Solvents Studied and
available dual-beam high-resolution UV/vis spectrophotometer
the π*, a, b and d parameters of the solvent taken from
was used to determine the peak maximum of the transition
reference 16
for 4-nitropyridine N-oxide in the solvents. The neat solvent
was placed in a 1 cm quartz reference cuvette, and a small
amount of 4-nitropyridine N-oxide was placed in the matched
1 n-heptane
sample cuvette and filled with solvent. The solution in the
2 n-hexane
sample cuvette was shaken until a constant absorbance value
3 n-pentane 4 cyclohexane
was obtained. The 4-nitropyridine N-oxide solution was then
5 triethylamine
either diluted with the solvent or several more crystals were
6 diethyl ether
added to the solution to adjust the absorbance value to between
7 tetrachloroethene
0.2 and 1.8 absorbance units. The spectrum of 4-nitropyridine
8 carbon tetrachloride N-oxide in the solvent was scanned at a resolution of 0.05 nm
9 1-chlorobutane
per data point. The peak maximum was determined both by
10 p-xylene
a peak detection algorithm of the spectrophotometer software
11 mesitylene 12 m-xylene
package and by visual confirmation by the operator using an
13 1,1,1-trichloroethane
unsmoothed spectrum. Five spectra were measured for 4-ni-
14 trichloroethene
tropyridine N-oxide in each solvent and the average value of
15 toluene 16 1,4-dioxane 17 ethyl acetate 18 p-difluorobenzene 19 tetrahydrofuran Results and Discussion 20 benzene 21 methyl acetate 22 fluorobenzene
Results of the π f π* transition of 4-nitropyridine
23 cyclohexanone 24 1,2-dichloroethane N-oxide in the solvents studied are given in Table 1. The
25 pyridine
max value is expressed in kilokaysers (1 kK
26 N,N-dimethylformamide
along with the standard uncertainty, σ, multiplied by a
27 dimethyl sulfoxide 28 sec-butyl alcohol 29 octanol
classes of solvents studied. Within the framework of eq
30 isobutyl alcohol
1, multiple LFER equations were computed to examine
31 hexanol
the data collected. It was concluded that the experimen-
32 pentanol 33 isopentyl alcohol
tal νmax value in solvents 47 and 48 would not be included 34 tert-butyl alcohola
in any further regression equations because the values
35 decanol
deviated significantly (greater than three standard de-
36 n-butyl alcohola
viations) from the best LFER using all the data. A
37 isopropyl alcohola 38 ethanol
possible explanation for the poorer correlation of the
39 chloroform
transition maxima in solvents 47 and 48 is that 4-nitro- 40 methanol
pyridine N-oxide may not be sufficiently basic to offset
41 2-butanone 42 acetone
the self-association of these solvents,12 or 4-nitropyridine
43 aniline N-oxide may be simply protonated in solvent 47. 44 acetonitrilea
The following LFER set was computed for the remain-
45 dichloromethane 46 benzyl alcohol
ing 46 solvents using different combinations of the
47 acetic acid
Kamlet Taft parameters as independent variables.
yet still retain the desirable functionality of the pyridine
N-oxide probe, is 4-nitropyridine N-oxide. Addition of anitro group to the previously investigated pyridine N-
oxide would produce a bathochromic shift of the peak
maximum due to increased ring conjugation, resulting
in a greater spectroscopic utility for the probe. It is thepurpose of this study to measure the peak maxima of
4-nitropyridine N-oxide in various solvents and optimize
the LFER using Kamlet Taft parameters as the depend-
Examination of the standard error and t-value of the
term showed that it was not a statistically significant
Experimental Section
variable in the regression equation.
expected from a probe, such as 4-nitropyridine N-oxide,that is incapable of hydrogen-bond donor abilities. The
Chemicals.
4-nitropyridine N-oxide (purity 97%) was
obtained from a commercial supplier and was vacuum desic-cated over CaSO
(11) Taylor, B. N.; Kuyatt, C. E. Guidelines for Evaluating and
4 prior to use due to the hygroscopic nature
of the compound. Solvents were obtained from commercial
Expressing the Uncertainty of NIST Measurement Results, NationalInstitute of Standards and Technology, U.S. Government Printing
suppliers and were of spectroscopic purity or better and were
(12) Chmurzynski, L. J. Chem. Soc., Faraday Trans. 1991, 87, 1729. J. Org. Chem., Vol. 61, No. 18, 1996
According to the Franck Condon principle, although
the dipole moments of the excited state, µe, and groundstate, µg, are different, the positions of the nuclei of theexcited state solute and the nuclei of the surroundingsolvent molecules should not change on the time scale ofthe electronic transition. The dipole moment of 4-nitro-pyridine N-oxide in the ground state was calculated tobe 0.09 D.14 The hypsochromic band shift observed insolvents capable of hydrogen-bonding can be attributedto the increased stabilization of the electronic groundstate relative to the excited state of 4-nitropyridineN-oxide (µg
Figure 1. Linear correlation of the experimental UV/vis
Considering all LFER equations, we recommend that
absorption maxima and the predicted values according to eq
3. Points for solvents 47 and 48 are included in the plot, but N-oxide as a probe. Both the π* and
not in the regression equation. The inset shows the chemical
to the measured transition maxima in solution; however,
structure of 4-nitropyridine N-oxide.
transition maxima appears to also depend on solvent
positive charge at the pyridinium nitrogen is resonance
class, addition of the δ term appears to correct for the
delocalized about the ring for poorer electron acceptor
polarizability of the solvent classes and is not an
ability of the probe. A LFER using solely
additional experimentally determined quantity. In com-
the independent variables, as in eq 4, results in separate
parison to the aforementioned results obtained for pyri-
LFERs among the solvent classes measured. Therefore,
dine N-oxide, 4-nitropyridine N-oxide possesses a solva-
inclusion of the δ term in eq 3 was deemed necessary to
tochromic effect that is located in the long wavelength
account for the variation in polarizability among the
various solvent classes. The correlation is graphically
making it a viable probe for hydrogen-bond donation
The a/s coefficient ratio in eq 3 is 9.42 indicating that
the hydrogen-bond donor ability of the solvent is the
Acknowledgment. A.L. wishes to acknowledge the
predominant solute/solvent interaction on the solvato-
financial support of the Professional Research Experi-
chromic activity of 4-nitropyridine N-oxide.
ence Program at the National Institute of Standards and
manifest in the relative insensitivity of the position of
the peak maximum of the π f π* transition13 to the
solvents incapable of hydrogen-bond donation. In fact,a good correlation exists for the solvents capable of
(14) Lazzeretti, P.; Malagoli, M.; Turci, L.; Zanasi, R. J. Mol. Struct.1993, 288, 255.
(15) Reichardt, C. In Solvent and Solvent Effects in Organic
(13) Pierre, M.; Baldeck, P. L.; Block, D.; Georges, R.; Trommsdorff,
Chemistry, 2nd ed.; VCH: Weinheim, Germany, 1988.
H. P. Chem. Phys. 1991, 156, 103.
(16) Marcus, Y. Chem. Soc. Rev. 1993, 22, 409.
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