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Faujasite catalyzed nitrodeiodination of iodopyrazoles
Catalysis Communications 42 (2013) 35–39
Contents lists available at ScienceDirect
Catalysis Communications journal homepage: www.elsevier.com/locate/catcom
Short Communication
Faujasite catalyzed nitrodeiodination of iodopyrazoles P. Ravi ⁎, Surya P. Tewari Advanced Centre of Research in High Energy Materials, University of Hyderabad, Hyderabad 500 046, India
a r t i c l e
i n f o
Article history: Received 21 May 2013 Received in revised form 11 July 2013 Accepted 17 July 2013 Available online 26 July 2013
a b s t r a c t Nitrodeiodination of iodopyrazoles using nitric acid/Faujasite has been investigated. The present procedure is simple, rapid and convenient and requires no sulfuric acid or oleum and may be applied for the synthesis of several nitropyrazoles in good yields in drug and pharmaceutical industries. © 2013 Elsevier B.V. All rights reserved.
Keywords: Faujasite Iodopyrazoles Heterogeneous catalysis Nitropyrazoles
1. Introduction Nitropyrazoles have been used as biologically active compounds including antibiotics or their analogues, agrochemicals, dyestuffs, phosphores, non-linear optical materials and recently as energetic materials [1]. The presence of nitro group in the pyrazole ring considerably enlarges the possibility of functionalization of various types of pyrazole derivatives [2]. The methods to synthesize nitropyrazoles are diverse and depend upon the nature of substituent groups in the pyrazole ring, the electron density distribution in it, nitration mixtures, nitration conditions, and so on. Pyrazoles are nitrated with fuming nitric acid, nitricsulfuric acid, nitric acid-acetic anhydride, nitric acid-trifluoro acetic anhydride or nitromethane-nitronium tetrafluoroborate. In many cases, it is impossible to introduce NO2 group into the desired position of the pyrazole ring and therefore indirect methods are used. Hüttel and Büchele [3] described the rearrangement of N-nitropyrazoles into 4nitropyrazoles in cold sulfuric acid solution. Janssen et al. synthesized 3(5),4-dinitropyrazole from 3(5)-nitropyrazole under Morgan– Ackerman nitration conditions [4,5]. 1-Methyl-3(5)-nitropyrazole, 1-methyl-4-nitropyrazole and 1-methyl-3(5),4-dinitropyrazole were synthesized from 1-methylpyrazole refluxing in nitric–sulfuric acid mixture [6–8]. N-Nitropyrazoles in anisole, xylene, benzonitrile, chlorobenzene, nitrobenzene, n-decane, mesitylene, N-methylformamide, or propylene glycol at 120–190 °C for 3–7 h were rearranged into 3nitropyrazole, 3(5),4-dinitropyrazole and 3,5-dinitropyrazole [6–8]. CNitropyrazoles were formed quantitatively and in some instances denitration of N-nitropyrazoles during thermal isomerization was observed. The oxidative iodination of pyrazoles prior to nitration is a
⁎ Corresponding author. Tel.: +91 40 23134303; fax: +91 40 23012800. E-mail address: [email protected] (P. Ravi). 1566-7367/$ – see front matter © 2013 Elsevier B.V. All rights reserved. http://dx.doi.org/10.1016/j.catcom.2013.07.032
desirable route to prepare C-polynitropyrazoles in higher yields. We have synthesized 3(5),4-dinitropyrazole and 3,4,5-trinitropyrazole in good yields from 3(5),4-diiodopyrazole and 3,4,5-triiodopyrazole respectively using fuming nitric acid and nitric–sulfuric acid mixture [9,10]. The traditional nitration methodologies usually suffer from low yields, starting material availability, harsh conditions, and/or difficulty to separate isomer formation prompted researchers to search for the alternative methodologies. The limitations and drawbacks of usual methods such as tedious work-up, strongly acidic media, oxidation ability of reagents (e.g., nitric acid), thermal isomerizations and safety problems can be avoided using metal nitrates impregnated on solid supports. The supported metal nitrates such as Bi(NO3)3.5H2O/SiO2 [11,12], AgNO3/BF3 [13], Cu(NO3)2/clay [14], Ce(NH4)2(NO3)6/H2SO4/SiO2 [15], Fe(NO3)3/clay [16] and metal nitrates/clay activated by acetic anhydride [17] have been used for the nitration of aromatic compounds. We have used HNO3/silica and HNO3/silica-sulfuric acid for the nitrolysis of iodopyrazoles [10]. It was demonstrated that nitrogen (IV) oxide in the presence of Faujasite nitrates both pyrazole and N-nitropyrazole [18]. Faujasite is easier to handle because it holds the acidity internally, readily separable from the products by simple filtration, recyclable and requires milder reaction conditions. Unlike the more hazardous acid catalysts (e.g., sulfuric acid, hydrofluoric acid, solid phosphoric acid, etc.,) Faujasite is recyclable with greater ease and lower expense, leading to less waste and fewer byproducts. Furthermore more hazardous strong acids, many steps, low yields and much waste can be avoided and greater returns shall be achieved. To the best our knowledge synthesis of nitropyrazoles from iodopyrazoles using nitric acid over Faujasite catalyst (H-form) has not been reported elsewhere. We report herein the synthesis of nitropyrazoles in good to higher yields from iodopyrazoles using nitric acid/Faujasite at room temperature for the first time.
36
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
2. Experimental section
3. Results and discussion
2.1. General
Faujasites due to their high degree of hydration, high selectivity, exceptional stability and low density are extremely useful as catalysts in many organic reactions. The framework of Faujasite structure is open with complete sodalite-type cages and with very large cavities having 12-membered ring openings [19,20]. The reactions are known to take place within the pores of catalyst, which allows a greater degree of product control. The solid catalyst accommodates up to 260 molecules of H2O per unit cell. We have chosen Faujasite (H-form) as catalyst for the nitrolysis (i.e., nitrodeiodination) of iodopyrazoles. Fuajasite was activated at 120 °C for 6 h before used in the nitrolysis. The iodopyrazole together with nitric acid/Fuajasite in THF have been stirred and the evaporation of solvent under vacuum comprises the reaction conditions for successful and regiospecific nitration. To establish the optimum conditions several reactions were performed on 4-iodopyrazole (1a) and 4-iodo-1-methypyrazole (1b) as the model substrates varying the amounts of Fuajasite at room temperature (Scheme 1). We found that there was no remarkable change in the yields of 2a and 2b when the reactions prolonged or increased the amount of catalyst. The replacement of iodine proceeded easily in nitric acid over Fuajasite. Table 1 summarizes the nitrodeiodination of series of iodopyrazoles and their corresponding nitropyrazoles. Generally, pyrazoles are nitrated in the 4-position facilitated by electron-donating and retarded by electron-withdrawing groups. The substrates with electron-donating groups readily underwent nitration in excellent yields (72%) and the deactivated substrates underwent nitration in good yields (N 60%). The free 3- and 5-positions of pyrazoles are strongly deactivated by the nitro group in the 4-position thus the yields are lower despite of harsh conditions and the nature of nitration mixture. On the other hand 1-phenylpyrazole and its analogues underwent substitution in the 4-position of the pyrazole ring [18]. 1-Phenyl4-iodopyrazole (7a), 1-(p-nitrophenyl)-4-iodopyrazole (8a) and 1benzyl-4-iodopyrazole (9a) nitrolysed into 1-phenyl-4-nitropyrazole (7b), 1-(p-nitrophenyl)-4-nitropyrazole (8b) and 1-benzyl-4-nitropyrazole (9b) respectively. Diiodopyrazoles (3c and 5c) and triiodopyrazoles (10a and 11a) were also nitrolysed into dinitro pyrazoles (4 and 6) and trinitropyrazoles (10b and 11b) respectively in good yields. Dinitropyrazoles are utterly deactivated by vicinal nitro groups thus hindering the substitution in the 5-position of pyrazole ring. The presence of vicinal nitro groups in 4 and 6 deactivated the 5-position and consequently the nitrolysis has not been observed rather quantitative iodopyrazoles were recovered. 3,4,5-Trinitropyrazole (10b) is neither hygroscopic nor highly acidic in nature [19]. It displays low sensitivity to external stimuli and outstanding thermal and chemical stability of nitrated aromatic compounds. The exceptional stability/or low sensitivity of 10b is because of its low acidity (pKa 2.35). 1-Methyl-3,4,5-trinitropyrazole (11b) has been considered as the next generation melt-cast explosive [9]. The product obtained after the nitrolysis of 3,4,5-triiodo-1-
All the reagents and solvents were obtained from Merck, Alfa-Aesar or Aldrich and used without further purification. Thin layer chromatography (silica gel GF-254 type) was routinely used to monitor the progress of reactions. Melting points were recorded by a capillary melting point apparatus and were uncorrected. IR spectra were recorded on Perkin Elmer FT-IR-1600 spectrophotometer in KBr matrix. The signals are reported in wave numbers (cm−1). 1H NMR and 13C NMR spectra were recorded on 300 MHz Varian instrument with DMSO-d6 and CDCl3 solvents. The chemical shift values are reported in δ units (ppm) relative to TMS as an internal standard. GC-MS was carried out with glass columns packed with 3% OV-17 on Chromosorb W (100–120 mesh) treated with DMCS in a Varian 1400 instrument fitted with flame ionization detector, nitrogen being used as carrier gas. Faujasite (H-form, SiO2/Al2O3 mole ratio of 80, surface area of 780 m2/g) and nitric acid (d 1.52 g/cm3) were used for the nitrolysis of iodopyrazoles. 2.1.1. General procedure for the synthesis of mononitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (250 mg) was added. Nitric acid (d 1.52 g/cm3, 10 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted repeatedly with dichloromethane. The solvent was removed under vacuum to obtain nitropyrazole. 2.1.2. General procedure for the synthesis of dinitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (500 mg) was added. Nitric acid (d 1.52 g/cm3, 20 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted with dichloromethane. The solvent was removed under reduced pressure to get dinitropyrazole. 2.1.2.1. 1-Methyl-3(5),4-dinitropyrazole (6). IR, υ (KBr) cm−1: 1551, 1533, 1522, 1371 and 1342 (C–NO2); 2994(C–H). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 4.04(s, 3-H); 8.33 (s, 5-H). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 38.3 (t, CH3); 147 (C-3); 127 (C-4); 133 (C-5). EI-MS: m/z 172 (M+•). Anal. calcd for C4H4N4O4 C 27.91; H 2.30; N 32.52; found C 27.88; H 2.34; N 32.54. 2.1.3. General procedure for the synthesis of trinitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (500 mg) was added. Nitric acid (d 1.52 g/cm3, 30 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted with dichloromethane. The solvent was removed under vacuum to obtain trinitropyrazole. 2.1.3.1. 3,4,5-trinitropyrazole (10b). IR, υ (KBr) cm−1: 1554, 1521, 1445, 1413, 1371, 1346 and 1284 (C–NO2); 3145 (N–H). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 12.1(s, 1H, NH). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 123 (C-4); 144 (C-3); 347 (C-5). EI-MS: m/z 203 (M+•). Anal. calcd for C3HN5O6 C 17.71; H 0.54; N 34.54; found C 17.72; H 0.46; N 34.44. 2.1.3.2. 1-Methyl-3,4,5-trinitropyrazole (11b). IR, υ (KBr) cm−1: 1552, 1532, 1454, 1384, 1323(C–NO2); 2994 (CH3). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 4.3 (s, 3H). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 43.5 (t, CH3); 124 (t, C4); 136 (t, C3); 148 (t, C5). EI-MS: m/z 217 (M+). Anal. calcd for C4H3N5O6 C 22.15; H 1.35; N 32.22; found C 22.5; H 1.3.
Scheme 1. Faujasite catalyzed nitrodeiodination of iodopyrazoles.
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
37
Table 1 Faujasite (H-form) catalyzed nitrodeiodination of iodopyrazoles. Entry
Substrate
Product
Time (h)
Yield (%)
m.p (°C) Found
Literature
1
3.5
72
164–165
162–164[3]
2
3.5
64
92–93
91–92[8]
3
3
73
135–136
134–136[4]
4
3.5
65
187–188
186–187[4]
5
3
73
126–127
124–127[5]
6
3
68
16–162
160–162[3]
7
3
57
96–97
97–98[5,6]
8
3.5
65
87–88
87–89[4]
9
3.5
62
86–87
87–89[4]
10
4
57
20–21
21–22[8]
11
4
64
20–21
21–22[8]
(continued on next page)
38
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
Table 1 (continued) Entry
Substrate
Product
Time (h)
Yield (%)
m.p (°C) Found
Literature
12
3.5
62
126–127
125–126[7]
13
3.5
61
161–162
162–163[7]
14
3.5
63
92–93
91–92[21]
15
3.5
72
88–89
87–89[4]
16
3.5
63
20–21
21–22[8]
17
5
68
190–191
188–190[22]
18
5
63
91–92
91–93[22]
methylpyrazole (11a) has been found to contain b8% yields of 3,5diiodo-4-nitropyrazole and 5-iodo-3,4-nitropyrazole. The nitrolysis of 11a with nitric acid for 3.5 h gave higher yield (63%) of trinitropyrazole (11b). In order to ascertain the generality of nitrodeiodination and its applicability to the synthesis of nitropyrazoles we have nitrolysed 3a–c, 10a and 11a and found that the vicinal electron-withdrawing groups had not prevented nitrolysis in the 4-, or 3(5)-position in the pyrazole ring. The nitrolysis of iodopyrazoles for 3 to 5 h showed the absence of starting compounds. It has been found that nitrolysis of iodonitropyrazoles (5a and 5b) required more time and only yielded 6 at 57% and 64% respectively. The determination of position of the nitro group was based on the variation in the reactivity towards electronwithdrawing groups in the 3(5)- or 4-position of the ring and the comparison of IR, 1H NMR, 13C NMR and mass spectra of nitropyrazoles. Lastly we also have tested the catalyst recycling on the nitrodeiodiantion of 1a and 1b. After filtration, washing with methanol, and heating at 120 °C
for 12 h Faujasite was reused and showed good activity for the synthesis of nitropyrazoles.
4. Conclusions We have used nitric acid/Faujasite (H-form) for the nitrolysis of iodopyrazoles and obtained nitropyrazoles in good to higher yields at room temperature. The present procedure appears to be attractive for the synthesis of nitropyrazoles and their derivatives in drug and pharmaceutical industries. Exceptionally higher yield of nitropyrazoles has been obtained however, compounds 2a, 2b, 4, and 6 found to be extremely resistant to nitrolysis. The nitrolysis of iodopyrazoles takes place only when Faujasite is added or the polyiodopyrazoles are heated with nitric acid. The failure to synthesize nitropyrazoles or partially nitrodeiodinated compounds is presumably due to the use of relatively less concentrated nitric acid.
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
Acknowledgements We gratefully acknowledged the Defence Research Development Organisation, India for financial support through the Advanced Centre of Research in High Energy Materials. References [1] L. Larina, L. Lopyrev, Nitroazoles: Synthesis, Structure and Applications, Springer, 2009. [2] S.A. Shevelev, I.L. Dalinger, T.K. Shkineva, B.J. Ugrak, V.I. Guleskaya, M. Kanishchev, Russian Chemical Bulletin International Edition 42 (1993) 1063–1068. [3] R. Hüttel, F. Büchele, Chemische Berichte 88 (1955) 1586–1590. [4] J.W.A.M. Janssen, H.J. Koeners, C.G. Kruse, C.L. Habraken, Journal of Organic Chemistry 38 (1973) 1777–1782. [5] J.T. Morgan, I. Ackerman, Journal of the Chemical Society 123 (1923) 1308–1313. [6] M.R. Grimmett, S.R. Hartshorn, K. Schofield, J.B. Weston, Journal of the Chemical Society, Perkin Transactions 2 (1972) 1654–1660. [7] K.-C. Chang, M.R. Grimmett, D.D. Ward, R.R. Weavers, Australian Journal of Chemistry 32 (1979) 1727–1734. [8] M.R. Grimmett, K.H.R. Lim, Australian Journal of Chemistry 31 (1978) 689–691.
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[9] P. Ravi, C.K. Reddy, A. Saikia, G.M. Gore, S.P. Tewari, A.K. Sikder, Propellants, Explosives, Pyrotechnics 37 (2012) 167–171. [10] P. Ravi, G.M. Gore, A.K. Sikder, S.P. Tewari, Synthetic Communications 142 (2012) 3463–3471. [11] H. Suzuki, T. Ikegami, Y. Matano, Synthesis 3 (1997) 249–267. [12] N.M. Leonard, L.C. Wieland, R.S. Mohan, Tetrahedron 58 (2002) 8373–8397. [13] G.A. Olah, A.P. Fung, S.C. Narang, J.A. Olah, Journal of Organic Chemistry 46 (1981) 3533–3537. [14] B. Gigantee, A.O. Prazeres, M.J. Marcelo-Curto, A. Cornelis, P. Laszlo, Journal of Organic Chemistry 60 (1992) 3445–3447. [15] J.M. Mellor, S. Mittoo, R. Parkes, R.W. Millar, Tetrahedron 56 (2000) 8019–8024. [16] A. Cornelis, P. Laszlo, Journal of Organic Chemistry 48 (1983) 4771–4772. [17] A. Cornelis, L. Delaude, A. Gerstman, P. Laszlo, Tetrahedron Letters 29 (1988) 5909–5912. [18] R.P. Claridge, L.N. Lancaster, R.W. Millar, R.B. Moodie, J.P.B. Sandall, Journal of the Chemical Society, Perkin Transactions 2 (2001) 197–200. [19] A. Iijima, Pure and Applied Chemistry 52 (1980) 2115–2130. [20] J. Cejka, H. Van Bekkum, A. Corma, F. Schuth, Introduction to Zeolite Science and Practice, 3rd edn, Elsevier, Amsterdam. [21] A.G. Burton, A.R. Katritzky, M. Konya, H.O. Tarhan, Journal of the Chemical Society, Perkin Transactions 2 (1974) 389–394. [22] G. Herve, C. Roussel, H. Graindorg, Angewandte Chemie International Edition 49 (2010) 3177–3181.
Contents lists available at ScienceDirect
Catalysis Communications journal homepage: www.elsevier.com/locate/catcom
Short Communication
Faujasite catalyzed nitrodeiodination of iodopyrazoles P. Ravi ⁎, Surya P. Tewari Advanced Centre of Research in High Energy Materials, University of Hyderabad, Hyderabad 500 046, India
a r t i c l e
i n f o
Article history: Received 21 May 2013 Received in revised form 11 July 2013 Accepted 17 July 2013 Available online 26 July 2013
a b s t r a c t Nitrodeiodination of iodopyrazoles using nitric acid/Faujasite has been investigated. The present procedure is simple, rapid and convenient and requires no sulfuric acid or oleum and may be applied for the synthesis of several nitropyrazoles in good yields in drug and pharmaceutical industries. © 2013 Elsevier B.V. All rights reserved.
Keywords: Faujasite Iodopyrazoles Heterogeneous catalysis Nitropyrazoles
1. Introduction Nitropyrazoles have been used as biologically active compounds including antibiotics or their analogues, agrochemicals, dyestuffs, phosphores, non-linear optical materials and recently as energetic materials [1]. The presence of nitro group in the pyrazole ring considerably enlarges the possibility of functionalization of various types of pyrazole derivatives [2]. The methods to synthesize nitropyrazoles are diverse and depend upon the nature of substituent groups in the pyrazole ring, the electron density distribution in it, nitration mixtures, nitration conditions, and so on. Pyrazoles are nitrated with fuming nitric acid, nitricsulfuric acid, nitric acid-acetic anhydride, nitric acid-trifluoro acetic anhydride or nitromethane-nitronium tetrafluoroborate. In many cases, it is impossible to introduce NO2 group into the desired position of the pyrazole ring and therefore indirect methods are used. Hüttel and Büchele [3] described the rearrangement of N-nitropyrazoles into 4nitropyrazoles in cold sulfuric acid solution. Janssen et al. synthesized 3(5),4-dinitropyrazole from 3(5)-nitropyrazole under Morgan– Ackerman nitration conditions [4,5]. 1-Methyl-3(5)-nitropyrazole, 1-methyl-4-nitropyrazole and 1-methyl-3(5),4-dinitropyrazole were synthesized from 1-methylpyrazole refluxing in nitric–sulfuric acid mixture [6–8]. N-Nitropyrazoles in anisole, xylene, benzonitrile, chlorobenzene, nitrobenzene, n-decane, mesitylene, N-methylformamide, or propylene glycol at 120–190 °C for 3–7 h were rearranged into 3nitropyrazole, 3(5),4-dinitropyrazole and 3,5-dinitropyrazole [6–8]. CNitropyrazoles were formed quantitatively and in some instances denitration of N-nitropyrazoles during thermal isomerization was observed. The oxidative iodination of pyrazoles prior to nitration is a
⁎ Corresponding author. Tel.: +91 40 23134303; fax: +91 40 23012800. E-mail address: [email protected] (P. Ravi). 1566-7367/$ – see front matter © 2013 Elsevier B.V. All rights reserved. http://dx.doi.org/10.1016/j.catcom.2013.07.032
desirable route to prepare C-polynitropyrazoles in higher yields. We have synthesized 3(5),4-dinitropyrazole and 3,4,5-trinitropyrazole in good yields from 3(5),4-diiodopyrazole and 3,4,5-triiodopyrazole respectively using fuming nitric acid and nitric–sulfuric acid mixture [9,10]. The traditional nitration methodologies usually suffer from low yields, starting material availability, harsh conditions, and/or difficulty to separate isomer formation prompted researchers to search for the alternative methodologies. The limitations and drawbacks of usual methods such as tedious work-up, strongly acidic media, oxidation ability of reagents (e.g., nitric acid), thermal isomerizations and safety problems can be avoided using metal nitrates impregnated on solid supports. The supported metal nitrates such as Bi(NO3)3.5H2O/SiO2 [11,12], AgNO3/BF3 [13], Cu(NO3)2/clay [14], Ce(NH4)2(NO3)6/H2SO4/SiO2 [15], Fe(NO3)3/clay [16] and metal nitrates/clay activated by acetic anhydride [17] have been used for the nitration of aromatic compounds. We have used HNO3/silica and HNO3/silica-sulfuric acid for the nitrolysis of iodopyrazoles [10]. It was demonstrated that nitrogen (IV) oxide in the presence of Faujasite nitrates both pyrazole and N-nitropyrazole [18]. Faujasite is easier to handle because it holds the acidity internally, readily separable from the products by simple filtration, recyclable and requires milder reaction conditions. Unlike the more hazardous acid catalysts (e.g., sulfuric acid, hydrofluoric acid, solid phosphoric acid, etc.,) Faujasite is recyclable with greater ease and lower expense, leading to less waste and fewer byproducts. Furthermore more hazardous strong acids, many steps, low yields and much waste can be avoided and greater returns shall be achieved. To the best our knowledge synthesis of nitropyrazoles from iodopyrazoles using nitric acid over Faujasite catalyst (H-form) has not been reported elsewhere. We report herein the synthesis of nitropyrazoles in good to higher yields from iodopyrazoles using nitric acid/Faujasite at room temperature for the first time.
36
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
2. Experimental section
3. Results and discussion
2.1. General
Faujasites due to their high degree of hydration, high selectivity, exceptional stability and low density are extremely useful as catalysts in many organic reactions. The framework of Faujasite structure is open with complete sodalite-type cages and with very large cavities having 12-membered ring openings [19,20]. The reactions are known to take place within the pores of catalyst, which allows a greater degree of product control. The solid catalyst accommodates up to 260 molecules of H2O per unit cell. We have chosen Faujasite (H-form) as catalyst for the nitrolysis (i.e., nitrodeiodination) of iodopyrazoles. Fuajasite was activated at 120 °C for 6 h before used in the nitrolysis. The iodopyrazole together with nitric acid/Fuajasite in THF have been stirred and the evaporation of solvent under vacuum comprises the reaction conditions for successful and regiospecific nitration. To establish the optimum conditions several reactions were performed on 4-iodopyrazole (1a) and 4-iodo-1-methypyrazole (1b) as the model substrates varying the amounts of Fuajasite at room temperature (Scheme 1). We found that there was no remarkable change in the yields of 2a and 2b when the reactions prolonged or increased the amount of catalyst. The replacement of iodine proceeded easily in nitric acid over Fuajasite. Table 1 summarizes the nitrodeiodination of series of iodopyrazoles and their corresponding nitropyrazoles. Generally, pyrazoles are nitrated in the 4-position facilitated by electron-donating and retarded by electron-withdrawing groups. The substrates with electron-donating groups readily underwent nitration in excellent yields (72%) and the deactivated substrates underwent nitration in good yields (N 60%). The free 3- and 5-positions of pyrazoles are strongly deactivated by the nitro group in the 4-position thus the yields are lower despite of harsh conditions and the nature of nitration mixture. On the other hand 1-phenylpyrazole and its analogues underwent substitution in the 4-position of the pyrazole ring [18]. 1-Phenyl4-iodopyrazole (7a), 1-(p-nitrophenyl)-4-iodopyrazole (8a) and 1benzyl-4-iodopyrazole (9a) nitrolysed into 1-phenyl-4-nitropyrazole (7b), 1-(p-nitrophenyl)-4-nitropyrazole (8b) and 1-benzyl-4-nitropyrazole (9b) respectively. Diiodopyrazoles (3c and 5c) and triiodopyrazoles (10a and 11a) were also nitrolysed into dinitro pyrazoles (4 and 6) and trinitropyrazoles (10b and 11b) respectively in good yields. Dinitropyrazoles are utterly deactivated by vicinal nitro groups thus hindering the substitution in the 5-position of pyrazole ring. The presence of vicinal nitro groups in 4 and 6 deactivated the 5-position and consequently the nitrolysis has not been observed rather quantitative iodopyrazoles were recovered. 3,4,5-Trinitropyrazole (10b) is neither hygroscopic nor highly acidic in nature [19]. It displays low sensitivity to external stimuli and outstanding thermal and chemical stability of nitrated aromatic compounds. The exceptional stability/or low sensitivity of 10b is because of its low acidity (pKa 2.35). 1-Methyl-3,4,5-trinitropyrazole (11b) has been considered as the next generation melt-cast explosive [9]. The product obtained after the nitrolysis of 3,4,5-triiodo-1-
All the reagents and solvents were obtained from Merck, Alfa-Aesar or Aldrich and used without further purification. Thin layer chromatography (silica gel GF-254 type) was routinely used to monitor the progress of reactions. Melting points were recorded by a capillary melting point apparatus and were uncorrected. IR spectra were recorded on Perkin Elmer FT-IR-1600 spectrophotometer in KBr matrix. The signals are reported in wave numbers (cm−1). 1H NMR and 13C NMR spectra were recorded on 300 MHz Varian instrument with DMSO-d6 and CDCl3 solvents. The chemical shift values are reported in δ units (ppm) relative to TMS as an internal standard. GC-MS was carried out with glass columns packed with 3% OV-17 on Chromosorb W (100–120 mesh) treated with DMCS in a Varian 1400 instrument fitted with flame ionization detector, nitrogen being used as carrier gas. Faujasite (H-form, SiO2/Al2O3 mole ratio of 80, surface area of 780 m2/g) and nitric acid (d 1.52 g/cm3) were used for the nitrolysis of iodopyrazoles. 2.1.1. General procedure for the synthesis of mononitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (250 mg) was added. Nitric acid (d 1.52 g/cm3, 10 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted repeatedly with dichloromethane. The solvent was removed under vacuum to obtain nitropyrazole. 2.1.2. General procedure for the synthesis of dinitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (500 mg) was added. Nitric acid (d 1.52 g/cm3, 20 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted with dichloromethane. The solvent was removed under reduced pressure to get dinitropyrazole. 2.1.2.1. 1-Methyl-3(5),4-dinitropyrazole (6). IR, υ (KBr) cm−1: 1551, 1533, 1522, 1371 and 1342 (C–NO2); 2994(C–H). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 4.04(s, 3-H); 8.33 (s, 5-H). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 38.3 (t, CH3); 147 (C-3); 127 (C-4); 133 (C-5). EI-MS: m/z 172 (M+•). Anal. calcd for C4H4N4O4 C 27.91; H 2.30; N 32.52; found C 27.88; H 2.34; N 32.54. 2.1.3. General procedure for the synthesis of trinitropyrazoles To iodopyrazole (1 mmol) dissolved in THF (10 mL), Fuajasite (500 mg) was added. Nitric acid (d 1.52 g/cm3, 30 mL) was added slowly and the mixture was stirred at room temperature for required time. The catalyst was recovered by filtration and the filtrate was extracted with dichloromethane. The solvent was removed under vacuum to obtain trinitropyrazole. 2.1.3.1. 3,4,5-trinitropyrazole (10b). IR, υ (KBr) cm−1: 1554, 1521, 1445, 1413, 1371, 1346 and 1284 (C–NO2); 3145 (N–H). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 12.1(s, 1H, NH). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 123 (C-4); 144 (C-3); 347 (C-5). EI-MS: m/z 203 (M+•). Anal. calcd for C3HN5O6 C 17.71; H 0.54; N 34.54; found C 17.72; H 0.46; N 34.44. 2.1.3.2. 1-Methyl-3,4,5-trinitropyrazole (11b). IR, υ (KBr) cm−1: 1552, 1532, 1454, 1384, 1323(C–NO2); 2994 (CH3). 1H NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 4.3 (s, 3H). 13C NMR (300 MHz, CDCl3, 300 K) δ (ppm) = 43.5 (t, CH3); 124 (t, C4); 136 (t, C3); 148 (t, C5). EI-MS: m/z 217 (M+). Anal. calcd for C4H3N5O6 C 22.15; H 1.35; N 32.22; found C 22.5; H 1.3.
Scheme 1. Faujasite catalyzed nitrodeiodination of iodopyrazoles.
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
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Table 1 Faujasite (H-form) catalyzed nitrodeiodination of iodopyrazoles. Entry
Substrate
Product
Time (h)
Yield (%)
m.p (°C) Found
Literature
1
3.5
72
164–165
162–164[3]
2
3.5
64
92–93
91–92[8]
3
3
73
135–136
134–136[4]
4
3.5
65
187–188
186–187[4]
5
3
73
126–127
124–127[5]
6
3
68
16–162
160–162[3]
7
3
57
96–97
97–98[5,6]
8
3.5
65
87–88
87–89[4]
9
3.5
62
86–87
87–89[4]
10
4
57
20–21
21–22[8]
11
4
64
20–21
21–22[8]
(continued on next page)
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P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
Table 1 (continued) Entry
Substrate
Product
Time (h)
Yield (%)
m.p (°C) Found
Literature
12
3.5
62
126–127
125–126[7]
13
3.5
61
161–162
162–163[7]
14
3.5
63
92–93
91–92[21]
15
3.5
72
88–89
87–89[4]
16
3.5
63
20–21
21–22[8]
17
5
68
190–191
188–190[22]
18
5
63
91–92
91–93[22]
methylpyrazole (11a) has been found to contain b8% yields of 3,5diiodo-4-nitropyrazole and 5-iodo-3,4-nitropyrazole. The nitrolysis of 11a with nitric acid for 3.5 h gave higher yield (63%) of trinitropyrazole (11b). In order to ascertain the generality of nitrodeiodination and its applicability to the synthesis of nitropyrazoles we have nitrolysed 3a–c, 10a and 11a and found that the vicinal electron-withdrawing groups had not prevented nitrolysis in the 4-, or 3(5)-position in the pyrazole ring. The nitrolysis of iodopyrazoles for 3 to 5 h showed the absence of starting compounds. It has been found that nitrolysis of iodonitropyrazoles (5a and 5b) required more time and only yielded 6 at 57% and 64% respectively. The determination of position of the nitro group was based on the variation in the reactivity towards electronwithdrawing groups in the 3(5)- or 4-position of the ring and the comparison of IR, 1H NMR, 13C NMR and mass spectra of nitropyrazoles. Lastly we also have tested the catalyst recycling on the nitrodeiodiantion of 1a and 1b. After filtration, washing with methanol, and heating at 120 °C
for 12 h Faujasite was reused and showed good activity for the synthesis of nitropyrazoles.
4. Conclusions We have used nitric acid/Faujasite (H-form) for the nitrolysis of iodopyrazoles and obtained nitropyrazoles in good to higher yields at room temperature. The present procedure appears to be attractive for the synthesis of nitropyrazoles and their derivatives in drug and pharmaceutical industries. Exceptionally higher yield of nitropyrazoles has been obtained however, compounds 2a, 2b, 4, and 6 found to be extremely resistant to nitrolysis. The nitrolysis of iodopyrazoles takes place only when Faujasite is added or the polyiodopyrazoles are heated with nitric acid. The failure to synthesize nitropyrazoles or partially nitrodeiodinated compounds is presumably due to the use of relatively less concentrated nitric acid.
P. Ravi, S.P. Tewari / Catalysis Communications 42 (2013) 35–39
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