Easy and Safe Preparations of (Diacetoxyiodo) arenes from Iodoarenes, with Urea-Hydrogen Peroxide Adduct (UHP) as the Oxidant and the Fully Interpreted ¹H- and ¹³C-NMR Spectra of the Products

Abstract

An easy and safe, though only moderately effective method is presented for preparing (diacetoxyiodo)arenes, ArI(OAc)₂, from iodoarenes, ArI, using the commercially available and easily handled urea-hydrogen peroxide adduct (UHP) as the oxidant. The reactions take place in anhydrous AcOH/Ac₂O/AcONa (a catalyst) mixtures, at 40 ºC for 3.5 h to afford the purified ArI(OAc)₂ in 37-78% yields. The fully interpreted ¹H- and ¹³C-NMR spectra of the ArI(OAc)₂ products are reported.

Introduction

(Diacetoxyiodo)arenes, ArI(OAc)₂, and particularly the parent compound (diacetoxyiodo)benzene, PhI(OAc)₂, have been known for a long time [1,2]. They are used in organic synthesis as potent, often chemoselective, oxidizing agents. They are also used for facile syntheses of several classes of aromatic hypervalent iodine compounds, e.g. [bis(trifluoroacetoxy)iodo]arenes, [hydroxy(tosyloxy)iodo]arenes, aromatic iodonium salts [3], etc. In our two latest reviews [4,5] we relate and explain our previous novel syntheses of ArI(OAc)₂ from corresponding ArI, as well our novel aromatic iodination methods, and preparations of several classes of aromatic hypervalent iodine compounds, easily attainable from aromatic iodides; particularly see ref. 4, pp. 1343-1345 and 1352-1354.

During the course of our systematic studies on effective and easy preparations of ArI(OAc)₂ from the corresponding ArI [4,5], we have devised several methods for their syntheses. In this work we have oxidized seven iodoarenes (Table 1) in anhydrous AcOH/Ac₂O mixtures; the reactions did not proceed in the absence of sodium acetate, AcONa (used in a stoichiometric quantity) – cf. our former work [6], where its presence in the reaction mixtures was also indispensable. The reactions took place as follows:

$$\text{ArI}+\left[\text{urea}\right]···{\text{H}}_2{\text{O}}_2 {\displaystyle \underset{{\displaystyle \stackrel{ }{3.5 \text{h} ; 40°\text{C}}}}{\overset{{\displaystyle \underset{ }{\text{AcOH}/{\text{Ac}}_2\text{O}/\text{AcONa}}}}{\to }}} \text{ArI}{\left(\text{OAc}\right)}_2+\left[\text{acetylurea}\right]+{\text{H}}_2\text{O}$$

In our opinion, the novel method presented in this paper is easy and safe, albeit only moderately effective (yields are in the 37-78% range). For the first time, we have used UHP as the oxidant. This compound, which is now commercially available, may be considered a “dry carrier” of the unstable and hazardous hydrogen peroxide. The UHP solid is easy to handle, safe and stable at room temperature. Its ability to release oxidative species in water and organic media has made it a useful reagent in organic synthesis [7].

Experimental

General

Melting points submitted in the Table 1 are uncorrected. All the reagents were purchased from Aldrich or Lancaster and were used without further purification. The NMR spectra were run in CDCl₃ solutions at room temperature, with TMS as an internal standard; the spectra were recorded on a Brucker AVANCE DMX 400 spectrometer. To obtain better assignments, also ¹H – ¹³C NMR correlation spectra were recorded.

Optimized Procedure for Preparing (Diacetoxyiodo)arenes from Iodoarenes:

Urea-Hydrogen Peroxide adduct, 98% (3.02 g, 31.5 mmol, 350% excess) was added portionwise to a stirred mixture of glacial AcOH (24 mL) with Ac₂O (9 mL). An appropriate iodoarene (7 mmol) was slowly added, the solution was cooled to 10-15 °C, and powdered AcONa (1.26 g, 15 mmol) was suspended. Stirring at 40 °C was continued for 3.5 h. After cooling, water (35 mL) was slowly added with stirring. The precipitated ArI(OAc)₂ were collected by filtration, washed on the filter with a cold (5-10 °C) 10% aq. AcOH, and air-dried in the dark; if necessary, they were recrystallized from AcOEt/Ac₂O (9:1, v/v). The oily or semisolid products were extracted with CH₂Cl₂, the combined extracts were dried over anhydrous Na₂SO₄ and filtered, the solvent was distilled off under vacuum, and the solidified residues were recrystallized from AcOEt/Ac₂O (9:1).The purities and homogeneities of the purified ArI(OAc)₂ were firstly checked by TLC, and next confirmed by their melting points, all close to those reported in the literature (Table 1). Their chemical structures were fully supported by the ¹H- NMR (Table 2) and ¹³C-NMR (Table 3) spectra (in CDCl₃).

Table 1. Final yields and melting points (uncorrected) of the purified (diacetoxyiodo)-arenes obtained from the corresponding iodoarenes.

Substrate	Product	Yield (%)	Mp (°C)	Lit. Mp (°C)
C6H5I	C6H5I(OAc)2	44	161-162	161-163 [6]
3-FC6H4I	3-FC6H4I(OAc)2	37	143-145	144-145 [8]
4-FC6H4I	4-FC6H4I(OAc)2	78	177-180	179 [8]
2-MeC6H4I	2-MeC6H4I(OAc)2	64	142-147	140-142 [6]
2,4-Me2C6H3I	2,4-Me2C6H3I(OAc)2	69	126-128	128 [9]
2-MeOC6H4I	2-MeOC6H4I(OAc)2	48	145-147	147-149 [6]
3-MeOC6H4I	3-MeOC6H4I(OAc)2	57	130-132	133-135 [6]

Table 1. Final yields and melting points (uncorrected) of the purified (diacetoxyiodo)-arenes obtained from the corresponding iodoarenes.

Substrate	Product	Yield (%)	Mp (°C)	Lit. Mp (°C)
C6H5I	C6H5I(OAc)2	44	161-162	161-163 [6]
3-FC6H4I	3-FC6H4I(OAc)2	37	143-145	144-145 [8]
4-FC6H4I	4-FC6H4I(OAc)2	78	177-180	179 [8]
2-MeC6H4I	2-MeC6H4I(OAc)2	64	142-147	140-142 [6]
2,4-Me2C6H3I	2,4-Me2C6H3I(OAc)2	69	126-128	128 [9]
2-MeOC6H4I	2-MeOC6H4I(OAc)2	48	145-147	147-149 [6]
3-MeOC6H4I	3-MeOC6H4I(OAc)2	57	130-132	133-135 [6]

Table 2. ¹H-NMR chemical shifts for pure (diacetoxyiodo)arenes. Cf. our present experimental values with those previously reported [11].

Product	Chemical shifts δ (ppm)
	H2	H3	H4	H5	H6	OCH3	CH3(o)	CH3(p)	CH3in OAc
C6H5I(OAc)2	8.10	7.50	7.60	7.50	8.10	-	-	-	2.01
	d	t	t	t	d				s
3-FC6H4I(OAc)2	7.29	-	7.84	7.51	7.84	-	-	-	2.02
	d		t	m	t				s
4-FC6H4I(OAc)2	8.09	7.19	-	7.19	8.09	-	-	-	2.02
	d	t		t	d				s
2-MeC6H4I(OAc)2	-	7.52	7.52	7.26	8.17	-	2.72	-	1.98
		d	t	t	d		s		s
2,4-Me2C6H3I(OAc)2	-	7.31	-	7.05	8.04	-	2.68	2.40	1.98
		s		d	d		s	s	s
2-MeOC6H4I(OAc)2	-	7.16	7.59	7.04	8.14	3.99	-	-	1.97
		d	t	t	d	s			s
3-MeOC6H4I(OAc)2	7.65	-	7.10	7.41	7.67	3.87	-	-	2.02
	s		d	t	s	s			s

Table 2. ¹H-NMR chemical shifts for pure (diacetoxyiodo)arenes. Cf. our present experimental values with those previously reported [11].

Product	Chemical shifts δ (ppm)
	H2	H3	H4	H5	H6	OCH3	CH3(o)	CH3(p)	CH3in OAc
C6H5I(OAc)2	8.10	7.50	7.60	7.50	8.10	-	-	-	2.01
	d	t	t	t	d				s
3-FC6H4I(OAc)2	7.29	-	7.84	7.51	7.84	-	-	-	2.02
	d		t	m	t				s
4-FC6H4I(OAc)2	8.09	7.19	-	7.19	8.09	-	-	-	2.02
	d	t		t	d				s
2-MeC6H4I(OAc)2	-	7.52	7.52	7.26	8.17	-	2.72	-	1.98
		d	t	t	d		s		s
2,4-Me2C6H3I(OAc)2	-	7.31	-	7.05	8.04	-	2.68	2.40	1.98
		s		d	d		s	s	s
2-MeOC6H4I(OAc)2	-	7.16	7.59	7.04	8.14	3.99	-	-	1.97
		d	t	t	d	s			s
3-MeOC6H4I(OAc)2	7.65	-	7.10	7.41	7.67	3.87	-	-	2.02
	s		d	t	s	s			s

Table 3. ¹³C NMR chemical shifts for pure (diacetoxyiodo)arenes and coupling constants J _{¹⁹F−¹³C} and J _{¹⁹F−C−¹³C} (Hz). Cf. our present experimental values with those previously reported incompletely [10, 12].

Product	Chemical shifts of aromatic C atoms in δ (ppm)
	C1	C2	C3	C4	C5	C6
C6H5I(OAc)2	121.58	134.94	130.96	131.74	130.96	134.94
	s	s	s	s	s	s
3-FC6H4I(OAc)2	120.65	122.56	161.33	119.26	132.33	130.87
	s	s	d	d	s	s
		J = 24.6	J = 253.0	J = 20.7
4-FC6H4I(OAc)2	115.64	137.74	118.59	164.63	118.82	135.95
	s	s	d	d	d	s
			J = 22.6	J = 253.7	J = 22.6
2-MeC6H4I(OAc)2	127.29	140.72	128.51	130.97	132.82	137.30
	s	s	s	s	s	s
2,4-Me2C6H3I(OAc)2	124.09	143.73	131.78	140.66	129.40	137.32
	s	s	s	s	s	s
2-MeOC6H4I(OAc)2	113.63	156.46	112.33	134.70	122.91	137.94
	s	s	s	s	s	s
3-MeOC6H4I(OAc)2	121.62	120.68	160.72	118.14	131.73	127.25
	s	s	s	s	s	s

Product	Chemical shifts of aromatic C atoms in δ (ppm)
	C1	C2	C3	C4	C5	C6
C6H5I(OAc)2	121.58	134.94	130.96	131.74	130.96	134.94
	s	s	s	s	s	s
3-FC6H4I(OAc)2	120.65	122.56	161.33	119.26	132.33	130.87
	s	s	d	d	s	s
		J = 24.6	J = 253.0	J = 20.7
4-FC6H4I(OAc)2	115.64	137.74	118.59	164.63	118.82	135.95
	s	s	d	d	d	s
			J = 22.6	J = 253.7	J = 22.6
2-MeC6H4I(OAc)2	127.29	140.72	128.51	130.97	132.82	137.30
	s	s	s	s	s	s
2,4-Me2C6H3I(OAc)2	124.09	143.73	131.78	140.66	129.40	137.32
	s	s	s	s	s	s
2-MeOC6H4I(OAc)2	113.63	156.46	112.33	134.70	122.91	137.94
	s	s	s	s	s	s
3-MeOC6H4I(OAc)2	121.62	120.68	160.72	118.14	131.73	127.25
	s	s	s	s	s	s

Product	Chemical shifts of C atoms in substituents in δ (ppm)
	CH3 (o)	CH3 (p)	OCH3	CH3 in OAc	C=O in OAc
C6H5I(OAc)2	-	-	-	20.36	176.39
				s	s
3-FC6H4I(OAc)2	-	-	-	20.51	176.76
				s	s
4-FC6H4I(OAc)2	-	-	-	20.47	176.66
				s	s
2-MeC6H4I(OAc)2	25.68	-	-	20.42	176.53
	s			s	s
2,4-Me2C6H3I(OAc)2	25.56	21.64	-	20.52	176.57
	s	s		s	s
2-MeOC6H4I(OAc)2	-	-	57.06	20.54	176.82
			s	s	s
3-MeOC6H4I(OAc)2	-	-	55.92	20.56	176.64
			s	s	s

Product	Chemical shifts of C atoms in substituents in δ (ppm)
	CH3 (o)	CH3 (p)	OCH3	CH3 in OAc	C=O in OAc
C6H5I(OAc)2	-	-	-	20.36	176.39
				s	s
3-FC6H4I(OAc)2	-	-	-	20.51	176.76
				s	s
4-FC6H4I(OAc)2	-	-	-	20.47	176.66
				s	s
2-MeC6H4I(OAc)2	25.68	-	-	20.42	176.53
	s			s	s
2,4-Me2C6H3I(OAc)2	25.56	21.64	-	20.52	176.57
	s	s		s	s
2-MeOC6H4I(OAc)2	-	-	57.06	20.54	176.82
			s	s	s
3-MeOC6H4I(OAc)2	-	-	55.92	20.56	176.64
			s	s	s