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Article

Synthesis and Characterization of Nitro-p-xylenes

1
State Key Laboratory of Prevention and Control of Explosion, Beijing Institute of Technology, P. R. China
2
Center of Analysis and Test of Chengdu Branch, Chinese Academy of Sciences, P.R. China
*
Author to whom correspondence should be addressed.
Molecules 2005, 10(8), 978-989; https://doi.org/10.3390/10080978
Submission received: 25 January 2004 / Revised: 23 April 2005 / Accepted: 25 April 2005 / Published: 31 August 2005

Abstract

:
In this paper we elected to nitrate p-xylene because this compound has only one mononitro- and trinitro- isomer. Trinitro-p-xylene was used as a starting material for the synthesis of other compounds in subsequent work. The mononitration of p-xylene can be easily carried out at 30°C. Nitro-p-xylene is easily nitrated to dinitro-p-xylene at a temperature of 80°C. The trinitro-p-xylene can be obtained at 120°C. Single crystals of 2,3-dinitro-p-xylene and 2,3,5-trinitro-p-xylene were grown using the slow cooling method and we report the X-ray structure of the former. The thermal decomposition of the compounds was studied using differential scanning calorimetry (DSC) and thermogravimetry-derivative thermogravimetry (TG-DTG) techniques and FT-IR. The target compounds were also characterized by 1H-NMR, 13C-NMR and MS.

Introduction

The nitration of p-xylene to give the corresponding mononitro-p-xylene, dinitro-p-xylene (DPX) and trinitro-p-xylene (TPX) has been studied many years ago. Prior to World War II the nitration of the xylenes was carried out only on a small scale to produce solvents and chemical intermediates. However, during the war mixed xylenes were nitrated in at least three government ordnance works and reduced to xylidines that were used as an additive to increase the octane rating of aviation grade gasoline. Numerous uses were suggested for the surplus xylidines at the end of the war, such as for dyes and intermediates, wood preservatives, wetting agents, accelerators for rubber, and frothing agents for the flotation of ores [1]. The production of xylenes by the hydroforming process used for the manufacture of toluene from petroleum hydrocarbons makes available large amounts of these three isomeric hydrocarbons. Their nitration represents the application of one of the important unit processes to give an intermediate compound for further chemical utilization [2].
p-Xylene was first nitrated by Glinzer and Fitting [3]. In 1885 Nolting and Forel [4] were the first to use the mixed sulfuric and nitric acids to nitrate p-xylene. Konowalow and Gurewitsch [5] nitrated a number of alkyl benzenes, including p-xylene, with mixed nitric and acetic acids. Two patents also describe the nitration of mixed xylenes. Batchelder [6] claimed a mononitro product low in dinitro and by-product impurities. Most of the previous work, which reported on the dinitro- compounds, has been incidental to the nitration of p-xylene. Glinzer and Fittig heated mononitro-p-xylene and fuming nitric acid to produce a solid mixture of dinitro compounds. Lellmann’s [7] nitration method was to mix 25 grams of p-xylene and 100 grams of nitric acid (density, 1.51g/cm3) and allow them to stand for several days, however the yield was poor (only 2 grams of the 2,5-dinitro-p-xylene isolated from 100 grams of solid product). Giua [8] nitrated p-xylene with mixed acid and obtained only the 2,3-and 2,6-isomers.
Dinitro aromatic hydrocarbons may be made in either one or two steps [9,10], but it is more common to carry out the nitration in separate steps to reduce oxidation and also reduce the solubility of the product in the strong acid required for the one step process. For the nitration of nitro-p-xylene, it would be expected that the mixed acid would be less concentrated than for the dinitration of toluene but more concentrated than for the mononitration of p-xylene. Likewise, the temperature of nitration should be lower than for dinitration of toluene but higher than that used for the mononitration of p-xylene.
In this work, the para isomer is selected for its regular structure – only one mononitro and trinitro compounds exist – making it easier to obtain the single nitration compounds. Furthermore, the trinitro-p-xylene is the raw material of our subsequent work for its high nitrogen content. Trinitro-p-xylene has similar structure to 2,4,6-trinitrotoluene (TNT) which has been used traditionally as not only as a melt-case explosive but also a starting material for synthesis of two commonly used thermally stable explosives, i.e. 2,2’,4,4’,6,6’-hexanitrostilbene (HNS) [11] and 1,3,5-triamino- 2,4,6-trinitrobenzene (TATB) [12]. These compounds are high melting explosives that have been applied in situations where a combination of insensitivity to impact as well as heat is important.
In this paper, we have obtained mononitro-p-xylene, pure 2,6-dinitro-p-xylene, 2,3-dinitro-p-xylene and trinitro-p-xylene. Furthermore, we have determined the molecular and crystal structures of 2,3-dinitro-p-xylene. The thermal properties of 2,3- and 2,6-DPX and TPX were studied in detail.

Results and Discussion

The single crystal structure [13]

The structure of the 2,3-DPX was determined by single crystal X-ray diffraction. Dimensions of the single crystal used for measurement were 0.40 mm×0.40 mm×0.30 mm. Cell parameters were determined in the range of 2.64°<θ<27.48° at the temperature of 293(2) K. 2094 independent reflections were obtained, among which 1096 observed reflections with I>2σ(I) were used for the determination and refinement of the crystal structure in the range of -9≤h≤9, -15≤k≤15, -13≤l≤13. The crystal structure of 2,3-DPX is monoclinic with space group of P2(1)/n. The cell parameters are: a=0.7594(2) nm, b=1.1825(2) nm, c=1.0331(2) nm; β=98.74(3)°, V=0.9170(3) nm3, Dc=1.421g•cm-3, Z=4, F(000)=408, μ=0.116 mm-1, Mr=196.16. The final R1=0.0556 (for observed data) and wR2 is 0.1520 (for data I>2σ(I)), R1 = 0.0831, wR2 = 0.1686(for all data). All calculations were carried out with SHELXS98 [14]. The unit structure and the packing of the molecule in crystal lattice are illustrated in Figure 1 and Figure 2.
Figure 1. Molecular structure of DPX and the atom numbering
Figure 1. Molecular structure of DPX and the atom numbering
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Figure 2. Crystal packing of DPX
Figure 2. Crystal packing of DPX
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From Figure 1 and Figure 2 we can see that the nitro groups are not coplanar. The torsion angles are similar: O(1)-N(1)-C(2)-C(1) is 56.4°, O(2)-N(1)-C(2)-C(1) is -122.8°, O(4)-N(2)-C(3)-C(4) is 57.8 °, O(3)-N(2)-C(3)-C(4) is -122.4° while C(1)-C(2)-C(3)-C(4) is -2.3° and O(1)-N(1)-C(2)-C(3) is -125.0°, O(2)-N(1)-C(2)-C(3) is 55.8°, O(4)-N(2)-C(3)-C(2) is -124.9°, O(3)-N(2)-C(3)-C(2) is 54.9°. According to these data we present the “ball and stick” face and side face views of 2,3-DPX in Figure 3. The bond lengths of the crystal that are C-N 1.478, C1-C7 1.512, C4-C8 1.506 and the benzene C-C length is between 1.378 and 1.396, within the normal bond length range.
Figure 3. The face and side face views of 2,3-DPX
Figure 3. The face and side face views of 2,3-DPX
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The single crystal structure of TPX (CCDC number 256461) is discussed in another paper, currently in press [15]

Thermal behavior of the compounds

Typical DSC and TG-DTG curves for the compound 2,6-DPX are shown in Figure 4 and Figure 5. The DSC curve shows two endothermic peaks between 50 °C and 225 °C, with peak temperatures at 123.9 °C and 202.9 °C, respectively. The first peak temperature corresponds to the melting point of 2,6-dinitro-p-xylene (123°C or 126°C). The TG curve shows one stage mass loss without any stable intermediate products being formed in which the stage began at about 105.9 °C and was completed at 192 °C accompanied by a 96.6% mass loss.
Figure 4. DSC curve of the 2,6-DPX
Figure 4. DSC curve of the 2,6-DPX
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Figure 5. TG-DTG curve of 2,6-DPX
Figure 5. TG-DTG curve of 2,6-DPX
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Figure 6 and Figure 7 are the DSC and TG-DTG curves of 2,3-DPX. The curves are similar to those of 2,6-DPX as we can observe two endothermic peaks in Figure 6 and one stage mass loss in Figure 7. In the DSC curve the first endothermic peak temperature is at 92.8 °C, which matches with the literature melting point of 90-93 °C.
Figure 6. DSC curve of 2,3-DPX
Figure 6. DSC curve of 2,3-DPX
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Figure 7. TG-DTG curve of 2,3-DPX
Figure 7. TG-DTG curve of 2,3-DPX
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Figure 8 and Figure 9 are the DSC and TG-DTG curves of TPX. We can see that two endothermic peaks can be recognized in Figure 8 between room temperature and 245.0 °C. The first intense endothermic peak has a peak temperature of 140.9 °C, the same as the melting point of TPX (139-140°C). To find out what the decomposition residues are, FT-IR analysis was performed. The IR spectra of the solid residues of TPX at room temperature and 150 °C are shown in Figure 10. We can observe that the two curves have no difference according with the DSC and TG results. This also proved that the first peak of the DSC curve is the melting endothermic peak.
Figure 8. DSC curve of the TPX
Figure 8. DSC curve of the TPX
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Figure 9. TG-DTG curve of TPX
Figure 9. TG-DTG curve of TPX
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Figure 10. IR spectra of TPX and its decomposition residues, observed at room temperature (top) and 150 °C (bottom.)
Figure 10. IR spectra of TPX and its decomposition residues, observed at room temperature (top) and 150 °C (bottom.)
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The second endothermic process is wider, with a peak temperature of 228.1 °C. This shows the largest mass loss rate of 23.3%/min at 185.0 °C and a mass loss is 53.2%. From 190.0~202.0 °C the mass change is 22.7%. After 202.0 °C there is a slow mass loss process. The compound decomposed completely at 350 °C. The DSC and TG-DTG curves of DPX and TPX are similar. They both have two endothermic peaks, the first intense and the second wider. In the TG-DTG curve they have same shape and differ only in the peak temperatures. This is in agreement with the fact that 2,3-DPX and 2,6-DPX are isomers and TPX only has one nitro-group more than DPX, so they should have similar thermal properties. Because TPX has the most nitro-groups it has the highest melting point and 2,6-DPX is more symmetrical than 2,3-DPX so it has the higher melting point.

Conclusions

In this paper we studied the synthesis of the various nitro-p-xylenes and selected the optimal conditions for this reaction. We grew single crystals from an appropriate solution and studied the crystal structures of 2,3-DPX and TPX. The thermal properties of dinitro-p-xylene and trinitro-p-xylene are similar. Because the content of nitrogen of trinitro-p-xylene is higher it has potential application as a precursor for energetic materials.

Experimental

General

A Perkin- Elmer Pyris-1 DSC was used for DSC measurements. Dry, oxygen-free nitrogen was used to purge the DSC at 20 mL/min. The heating rate was 10 °C/min and the sample mass was about 0.5 mg contained in sealed aluminum pans. A Perkin-Elmer Pyris-1 TG analyzer was used for thermogravimetric analysis. About 0.5 mg of sample was held in a platinum pan, in a flow of dry, oxygen-free nitrogen at 20 mL/min, and the heating rate was 10°C /min. A Bruker Equinox 55 FT-IR spectrometer (KBr pellet) was used in the range of 400-4000cm-1. The p-xylene used was A.R. grade. All nitrations were carried out with mixed acid prepared from sulfuric acid (specific gravity, 1.84g/cm3) and nitric acid (specific gravity, 1.50 g/cm3).

Synthesis of mononitro-p-xylene (MNP)

The nitration was carried out in a flask with 4 necks. For the mononitration, the p-xylene was adding into the mixed acid. The reaction temperature and the amount of p-xylene added were recorded to ensure good temperature control and an even rate of addition of the p-xylene. A reaction temperature below 13.28°C cannot be used because p-xylene solidifies. A small amount of oxidation product was observed during every nitration and it became more and more prevalent with higher temperatures, longer reaction times and lower D.V.S. values. The presence and extent of the oxidation was indicated by the amount of brown fumes of nitrogen dioxide liberated during the reaction. After the addition of all of the p-xylene, stirring was continued for 10 minutes, then the reaction mixture was slowly and carefully added to a beaker containing chipped ice (300-400 g). Separation of the two layers occurred after 30 minutes. The nitro-p-xylene layer was washed twice with portions of water (100 mL), 10% sodium carbonate solution, and finally with water again. Later the nitro-p-xylene was dried with anhydrous calcium sulfate. The only boiling point for nitro-p-xylene recorded in the literature is 238.5° to 239°C at 739 mm Hg. The boiling point of the compound made in this work is 241~242°C at atmospheric pressure.

Synthesis of dinitro-p-xylene (DPX)

In order to produce the dinitro-p-xylene, we adopted the procedure for nitration of mononitro-p-xylene, as the reaction is similar to the mononitration of p-xylene. Mononitro-p-xylene can be used for next nitration without purification. The nitro-p-xylene was decanted from the mixed acid then it was added to the flask and heated to a temperature 5~10°C below the desired temperature for the experiment. The agitator was started and the mixed acid added dropwise at such a rate the temperature quickly raised to the desired value where it was controlled for 0.5 h. Then the reaction mixture was poured onto crushed ice, the precipitate filtered off, washed with aqueous sodium bicarbonate and then water. The product was recrystallized from the minimum amount of glacial acetic acid, filtered, washed with methanol and dried under vacuum at 60°C to give DPX. All three dinitro-p-xylenes were formed on direct nitration according to Lellmann [7], who obtained only 2 grams of 2,5-compound from 100 grams of solid product. All other investigators report only the 2,3- and 2,6-dinitro-p-xylenes. In this work we attempted to separate the isomers using successive recrystallizations. The solid product from the nitration is dissolved in ethyl alcohol and the solution evaporated slowly until long pale yellow crystals appeared. These were filtered from the solution, which was returned to the beaker for further evaporation. In this solution the crystals of 2,3-dinitro-p-xylene was obtained. The 2,6- isomer was separated in pure form relatively easily because of its low solubility in cold ethyl alcohol, in which the 2,3-isomer is soluble. In this process we obtained crystals of 2,3-dinitro-p-xylene. MS (m/e): 196 (M+, 100). Analysis for DPX: Calcd.: C 49.24, H 4.19, N 14.17; Found: C 48.98, H 4.08, N 14.28; The FT-IR traces of the 2,6-dinitro-p-xylene and 2,3-dinitro-p-xylene are shown in Figure 11 and Figure 12, respectively.
From Figure 11 and Figure 12 we can observe the mainly absorptions of some function groups are as follows: δC-NO2 559 cm-1, νO-N 710 cm-1, νC-H 883 cm-1, νsNO21389 cm-1, 1285 cm-1,νasNO21533 cm-1, νC-H 3088 cm-1.
Figure 11. The FT-IR figure of 2,6-dinitro-p-xylene
Figure 11. The FT-IR figure of 2,6-dinitro-p-xylene
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Figure 12. The FT-IR figure of 2,3-dinitro-p-xylene
Figure 12. The FT-IR figure of 2,3-dinitro-p-xylene
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Synthesis of trinitro-p-xylene (TPX)

p-Xylene (10 g) was added dropwise over a certain period to a stirred mixture of nitric acid (7 mL), sulphuric acid (25 mL) and water (15 mL) so as not to allow the temperature to exceed 50°C. After the addition, the mixture was poured into a separating funnel so that the bottom layer of residual acid could be removed. The product-containing top layer was added to sulphuric acid (28 mL) and the whole added to a mixture of nitric acid (6.5 mL), sulphuric acid (1 mL) and water (0.5 mL) at 70°C. When the addition was complete, the temperature was raised to 80 °C for 10 min, then slowly increased to 100°C, and finally increased rapidly to 120 °C where it was maintained for 1h. The reaction mixture was then poured onto crushed ice, the precipitate filtered off and washed with aqueous sodium bicarbonate and then water. The product was recrystallized from the minimum amount of glacial acetic acid, filtered, washed with methanol and dried under vacuum at 60 °C to yield TPX (8.5 g), m.p. 140.9 °C. MS (m/e): 241 (M+, 100). Analysis for TPX: Calcd. C 40.35, H 3.05, N 17.17; Found: C 39.83 H 2.91 N 17.43; IR (cm-1): –C-NO2: ν N O 2 a s 1544, ν N O 2 s 1350, -O-NO2: ν N O 2 s 1284, νC-H 3100, 3076, δC-H 875; 1H-NMR (DMSO) δ ppm 8.467 (s, 1H, C6H), 2.476 (s, 3H, CH3), 2.393 (s, 3H, CH3). The D.V.S. factor is defined by Groggins [16] as the actual sulfuric acid divided by the total water present when nitration is completed, both values being on a weight basis. Hence, water introduced with the reactants-mixed acid and hydrocarbon and water formed in the reaction are both accounted for in the D.V.S. Although it might be more scientific to use a mole ratio rather than a weight ratio to express water-sulfuric acid ratio, the fact that analyses of the reactants are given on a weight basis leads to the use of D.V.S. as a plant operating value. The relationship can be calculated from the equations:
D . V . S . = Wt .  of  H 2 SO 4  used Wt .  of  H 2 O at end of reaction = moles H 2 SO 4 × 98 moles H 2 O × 18 = 5.444 moles H 2 SO 4 moles H 2 O  or  Moles H 2 SO 4 Moles H 2 O = 0.1837  D . V . S .
In this work we selected the optimal reaction conditions for the synthesis of nitro-p-xylene that are summarized in Table 1.
Table 1. The optimal reaction conditions for synthesis nitro-p-xylene
Table 1. The optimal reaction conditions for synthesis nitro-p-xylene
p-Xylene Mononitro- Dinitro- Trinitro-
Highest reaction temperature, °C 30 80 120
Nitration time, min. 30 30 60
D.V.S. 3.0 8.0 27.3
HNO3: p-xylene, mole ratio 1.10 1.10 3.55

References

  1. Guisnet, M.; Gnep, N. S.; Morin, S. Micropor. Mesopor. Mat. 2000, 35-36, 47–59.
  2. Aboul-Gheit, A. K.; Abdel-Hamid, S. M.; Emam, E. A. Catalytic para-xylene maximization alkylation of toluene with methanol on platinum loaded zeolite catalysts prepared via different routes. Appl. Catal. A: Gen. 1999, 179, 107–115. [Google Scholar] [CrossRef]
  3. Glinzer, E.; Fitting, R. Ann. 1865, 136, 307–308.
  4. Nolting, E.; Forel, S. Ber. 1885, 18, 2680.
  5. Konowalow, M.; Gurewitsch, Ch. J. Russ. Phys. Chem. Soc. 1905, 27, 537–41, [Chem. Zentr., 1905, 76, II,818].
  6. Batchelder, G. W.; Nagle, W.M.; Vyverberg, J.C.; Willis, J. M. U.S. Patent No. 2,400,904, 1946.
  7. Lellmann, E. Ann. 1885, 228, 250–3.
  8. Giua, M. Gazz. Chim. Ital. 1919, 49, 149.
  9. Davis, T. L. Chemistry of Powder and Explosives; John Wiley. & Sons: New York, 1941; pp. 133-5, 141-150. [Google Scholar]
  10. Groggins, P.H. Unit Processes in Organic Synthesis; McGraw-Hill Book Co.: New York, 1947; pp. 48–51. [Google Scholar]
  11. Shipp, K.G..; Kaplan, L.A. Reaction of a substituted polynitrotoluene II. The generation and reactions of 2,4,6-trinitrobenzylanion. J. Org. Chem. 1966, 31, 857. [Google Scholar] [CrossRef]
  12. Atkin, R.L.; Hollins, R.A.; Wilson, W.S. Synthesis of polynitro compounds. Hexasubstituted benzenes. J. Org. Chem. 1986, 51, 3261–3266. [Google Scholar] [CrossRef]
  13. CCDC number 258942 contains the supplementary crystallographic data for this paper. These data can be obtained free of charge via www.ccdc.cam.ac.uk/conts/retrieving.html (or from the CCDC, 12 Union Road, Cambridge CB2 1EZ, UK; fax: +44 1223 336033; e-mail: [email protected]).
  14. Sheldrick, G. M. SHELXS98 Program for the Solution of Crystal Structure; University of Gottingen: Gottingen, Germany, 1998. [Google Scholar]
  15. Liu, Y.; Zhang, T.; Zhang, J.; Guo, J.; Yu, K. Preparation, Structural Characterization and the Molecular Structure of 2,3,5-trinitro-p-xylene. Struct. Chem. in press. [CrossRef]
  16. Groggins, P. H. Unit Processes in Organic Synthesis; McGraw-Hill Book Co.: New York, 1947; p. 25. [Google Scholar]
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MDPI and ACS Style

Yan-Hong, L.; Tong-Lai, Z.; Jian-Guo, Z.; Jin-Yu, G.; Kai-Bei, Y. Synthesis and Characterization of Nitro-p-xylenes. Molecules 2005, 10, 978-989. https://doi.org/10.3390/10080978

AMA Style

Yan-Hong L, Tong-Lai Z, Jian-Guo Z, Jin-Yu G, Kai-Bei Y. Synthesis and Characterization of Nitro-p-xylenes. Molecules. 2005; 10(8):978-989. https://doi.org/10.3390/10080978

Chicago/Turabian Style

Yan-Hong, L., Z. Tong-Lai, Z. Jian-Guo, G. Jin-Yu, and Y. Kai-Bei. 2005. "Synthesis and Characterization of Nitro-p-xylenes" Molecules 10, no. 8: 978-989. https://doi.org/10.3390/10080978

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