2,6-Dimethoxybenzyl Bromide 2,6-Dimethoxybenzyl Bromide

: The unstable title compound has been characterized for the first time. Its melting point, UV, IR, 1 H and 13 C-NMR and high-resolution mass spectra are presented. The X-ray structure has also been determined and shows a rather long C–Br bond perpendicular to the otherwise planar molecule. Abstract: The unstable title compound has been characterized for the first time. Its melting point, UV, IR, 1 H and 13 C-NMR and high-resolution mass spectra are presented. The X-ray structure has also been determined and shows a rather long C–Br bond perpendicular to the otherwise planar molecule.


Introduction
In the course of the synthesis of a natural product, we recently required 2,6dimethoxy benzyl bromide 1 and were surprised to find that this simple aromatic compound has apparently not been characterised in any way before. The first mention of the compound in the literature seems to be in 1988, when it was briefly evaluated together with other methoxybenzyl bromides as a selective OH-protecting reagent in carbohydrate chemistry [1]. Since then, it has found increasing use both for this application [2,3], and in construction of new ligands [4], organocatalysts [5], antibacterial agents [6], synthetic intermediates [7], insecticides [8] and anticancer agents [9]. However, in all these cases, it is prepared and used immediately without any attempt at isolation or characterisation. The method of preparation is most commonly by reaction of the corresponding alcohol 2 with phosphorus tribromide [6], although treatment of 2 with hydrobromic acid [8], and radical bromination of 2,6-dimethoxytoluene 3 with N-bromosuccinimide [2] have also been used (Scheme 1).

Introduction
In the course of the synthesis of a natural product, we recently required 2,6-dimethoxybenzyl bromide 1 and were surprised to find that this simple aromatic compound has apparently not been characterised in any way before. The first mention of the compound in the literature seems to be in 1988, when it was briefly evaluated together with other methoxybenzyl bromides as a selective OH-protecting reagent in carbohydrate chemistry [1]. Since then, it has found increasing use both for this application [2,3], and in construction of new ligands [4], organocatalysts [5], antibacterial agents [6], synthetic intermediates [7], insecticides [8] and anticancer agents [9]. However, in all these cases, it is prepared and used immediately without any attempt at isolation or characterisation. The method of preparation is most commonly by reaction of the corresponding alcohol 2 with phosphorus tribromide [6], although treatment of 2 with hydrobromic acid [8], and radical bromination of 2,6-dimethoxytoluene 3 with N-bromosuccinimide [2] have also been used (Scheme 1).

Scheme 1. Synthetic routes to compound 1.
This situation is in marked contrast to most of the other isomeric dimethoxybenzyl bromides (Figure 1), where both the 2,3-isomer 4 [10] and the 3,4-isomer 5 [11,12] have been known since the 1920s and have been thoroughly characterised using all the main analytical and spectroscopic methods. The 2,5-isomer 6 was first reported in 1953 [13] and full spectra were subsequently described [14]. The 3,5-isomer 7 was first prepared in 1962 [15] and is the only one of the six isomers to be characterised by X-ray diffraction to date, with both powder [16] and single crystal [17] data available. Interestingly, the 2,4-isomer 8 has a similar lack of characterisation to 1, being mentioned in two patents [18,19] as being generated from the corresponding alcohol and PBr3 and used immediately without isolation, and in terms of data, only the 1 H-NMR chemical shift for its CH2 is available [20]. This situation is in marked contrast to most of the other isomeric dimethoxybenzyl bromides (Figure 1), where both the 2,3-isomer 4 [10] and the 3,4-isomer 5 [11,12] have been known since the 1920s and have been thoroughly characterised using all the main analytical and spectroscopic methods. The 2,5-isomer 6 was first reported in 1953 [13] and full spectra were subsequently described [14]. The 3,5-isomer 7 was first prepared in 1962 [15] and is the only one of the six isomers to be characterised by X-ray diffraction to date, with both powder [16] and single crystal [17] data available. Interestingly, the 2,4-isomer 8 has a similar lack of characterisation to 1, being mentioned in two patents [18,19] as being generated from the corresponding alcohol and PBr 3 and used immediately without isolation, and in terms of data, only the 1 H-NMR chemical shift for its CH 2 is available [20]. We here describe the preparation, isolation and full characterisation of compound 1 including its melting point, UV, IR, 1 H and 13 C-NMR spectra, HRMS and X-ray structure determination. Some observations on the stability and decomposition of this reactive compound are also documented.

Results
Reaction of 2,6-dimethoxybenzyl alcohol, prepared by esterification then LiAlH4 reduction of commercially available 2,6-dimethoxybenzoic acid [21], with 0.33 equivalents of PBr3 in diethyl ether at 0 °C, followed by aqueous work-up, drying of the ether extract and evaporation gave the target compound 1 as colourless crystals, mp 65-67 °C. However, it was quickly discovered that the compound decomposed over a period of hours to days at room temperature to give a dark purple polymeric material, insoluble in any common solvents. The decomposition seemed to be accelerated by light, heat or contact with a nickel spatula and, once initiated, seemed to be autocatalytic so that, once it started, it accelerated rapidly. Despite this, samples of the compound have been stored in a foilcovered flask in a refrigerator at 5 °C for several months without decomposition.
The UV, IR and 1 H and 13 C-NMR spectra could be recorded by working rapidly and with suitable precautions, and the data documented in the Experimental Section and illustrated in the Supplementary Material are in agreement with expectation and also with those for the isomeric compounds of Figure 1. In particular, the UV spectrum consisted of a series of three shoulders at 291, 278 and 246 nm of steadily increasing intensity, while the most prominent peak in the IR spectrum was at 1088 cm -1 , attributable to aromatic C-Br stretch. The NMR spectra showed the expected shielding effect of OMe with 3/5 positions giving signals at δH 6.54 and δC 103.7, respectively. The quaternary carbon at C-1 gave a particularly weak signal at δC 114.4 ppm. High-resolution mass spectrometry gave a signal at m/z 151, corresponding to M + -Br and showing good agreement with the theoretical value. This gives some hint as to the mechanism of decomposition since the carbocation 9 formed by ionisation with loss of Bris significantly stabilised by the two OMe groups (Scheme 2), and we speculate that the main mode of decomposition may be bromide mediated O-demethylation of 9 to give the ortho-quinomethane species 10, which then polymerises. Scheme 2. Suggested mode of decomposition for 1. We here describe the preparation, isolation and full characterisation of compound 1 including its melting point, UV, IR, 1 H and 13 C-NMR spectra, HRMS and X-ray structure determination. Some observations on the stability and decomposition of this reactive compound are also documented.

Results
Reaction of 2,6-dimethoxybenzyl alcohol, prepared by esterification then LiAlH 4 reduction of commercially available 2,6-dimethoxybenzoic acid [21], with 0.33 equivalents of PBr 3 in diethyl ether at 0 • C, followed by aqueous work-up, drying of the ether extract and evaporation gave the target compound 1 as colourless crystals, mp 65-67 • C. However, it was quickly discovered that the compound decomposed over a period of hours to days at room temperature to give a dark purple polymeric material, insoluble in any common solvents. The decomposition seemed to be accelerated by light, heat or contact with a nickel spatula and, once initiated, seemed to be autocatalytic so that, once it started, it accelerated rapidly. Despite this, samples of the compound have been stored in a foil-covered flask in a refrigerator at 5 • C for several months without decomposition.
The UV, IR and 1 H and 13 C-NMR spectra could be recorded by working rapidly and with suitable precautions, and the data documented in the Experimental Section and illustrated in the Supplementary Material are in agreement with expectation and also with those for the isomeric compounds of Figure 1. In particular, the UV spectrum consisted of a series of three shoulders at 291, 278 and 246 nm of steadily increasing intensity, while the most prominent peak in the IR spectrum was at 1088 cm -1 , attributable to aromatic C-Br stretch. The NMR spectra showed the expected shielding effect of OMe with 3/5 positions giving signals at δ H 6.54 and δ C 103.7, respectively. The quaternary carbon at C-1 gave a particularly weak signal at δ C 114.4 ppm. High-resolution mass spectrometry gave a signal at m/z 151, corresponding to M + -Br and showing good agreement with the theoretical value. This gives some hint as to the mechanism of decomposition since the carbocation 9 formed by ionisation with loss of Bris significantly stabilised by the two OMe groups (Scheme 2), and we speculate that the main mode of decomposition may be bromide mediated O-demethylation of 9 to give the ortho-quinomethane species 10, which then polymerises. We here describe the preparation, isolation and full characterisation of compound 1 including its melting point, UV, IR, 1 H and 13 C-NMR spectra, HRMS and X-ray structure determination. Some observations on the stability and decomposition of this reactive compound are also documented.

Results
Reaction of 2,6-dimethoxybenzyl alcohol, prepared by esterification then LiAlH4 reduction of commercially available 2,6-dimethoxybenzoic acid [21], with 0.33 equivalents of PBr3 in diethyl ether at 0 °C, followed by aqueous work-up, drying of the ether extract and evaporation gave the target compound 1 as colourless crystals, mp 65-67 °C. However, it was quickly discovered that the compound decomposed over a period of hours to days at room temperature to give a dark purple polymeric material, insoluble in any common solvents. The decomposition seemed to be accelerated by light, heat or contact with a nickel spatula and, once initiated, seemed to be autocatalytic so that, once it started, it accelerated rapidly. Despite this, samples of the compound have been stored in a foilcovered flask in a refrigerator at 5 °C for several months without decomposition.
The UV, IR and 1 H and 13 C-NMR spectra could be recorded by working rapidly and with suitable precautions, and the data documented in the Experimental Section and illustrated in the Supplementary Material are in agreement with expectation and also with those for the isomeric compounds of Figure 1. In particular, the UV spectrum consisted of a series of three shoulders at 291, 278 and 246 nm of steadily increasing intensity, while the most prominent peak in the IR spectrum was at 1088 cm -1 , attributable to aromatic C-Br stretch. The NMR spectra showed the expected shielding effect of OMe with 3/5 positions giving signals at δH 6.54 and δC 103.7, respectively. The quaternary carbon at C-1 gave a particularly weak signal at δC 114.4 ppm. High-resolution mass spectrometry gave a signal at m/z 151, corresponding to M + -Br and showing good agreement with the theoretical value. This gives some hint as to the mechanism of decomposition since the carbocation 9 formed by ionisation with loss of Bris significantly stabilised by the two OMe groups (Scheme 2), and we speculate that the main mode of decomposition may be bromide mediated O-demethylation of 9 to give the ortho-quinomethane species 10, which then polymerises.  Crystals suitable for X-ray diffraction were obtained directly from the freshly prepared material and quickly mounted while still cold for data collection at 93 K. The resulting molecular structure (Figure 2) shows the two methoxy groups as essentially coplanar with the benzene ring while the CH 2 -Br bond is essentially orthogonal to it. The arrangement of the four molecules in the unit cell is also shown in Figure 2. Crystals suitable for X-ray diffraction were obtained directly from the freshly prepared material and quickly mounted while still cold for data collection at 93 K. The resulting molecular structure (Figure 2) shows the two methoxy groups as essentially coplanar with the benzene ring while the CH2-Br bond is essentially orthogonal to it. The arrangement of the four molecules in the unit cell is also shown in Figure 2. A good number of similar compounds have been crystallographically characterised and a comparison of the key parameters for the Ar-CH2-Br group for a selection of these ( Figure 3) is presented in Table 1. As compared to the unsubstituted benzyl bromide 9 compound 1 shows lengthening of both ring-CH2 and CH2-Br bonds and a torsion angle much closer to 90°. In considering the data for the isomeric 3,5-dimethoxy compound 7, it should be noted that the first set of data [16] is derived from a powder diffraction study, and the discrepancy between this and the single-crystal data [17], as well as all the other values in Table 1, is likely to be due to systematic errors linked to the different technique. The situation for the apparently good model compound 10 is complicated by the fact that there are two separate crystal forms containing, respectively, three and two independent molecules in the unit cell and each molecule has all three CH2Br groups non-equivalent, thus delivering a total of 15 values for each parameter, which actually span the full range of values exhibited by the other compounds in the Table. Nonetheless, it can be seen that the parameters listed for 1 are broadly in line with those of closely similar compounds. but the CH2-Br bond length is among the longest and the ring-CH2-Br torsion angle is among the closest to 90°. A good number of similar compounds have been crystallographically characterised and a comparison of the key parameters for the Ar-CH 2 -Br group for a selection of these ( Figure 3) is presented in Table 1. As compared to the unsubstituted benzyl bromide 9 compound 1 shows lengthening of both ring-CH 2 and CH 2 -Br bonds and a torsion angle much closer to 90 • . In considering the data for the isomeric 3,5-dimethoxy compound 7, it should be noted that the first set of data [16] is derived from a powder diffraction study, and the discrepancy between this and the single-crystal data [17], as well as all the other values in Table 1, is likely to be due to systematic errors linked to the different technique. The situation for the apparently good model compound 10 is complicated by the fact that there are two separate crystal forms containing, respectively, three and two independent molecules in the unit cell and each molecule has all three CH 2 Br groups non-equivalent, thus delivering a total of 15 values for each parameter, which actually span the full range of values exhibited by the other compounds in the Table. Nonetheless, it can be seen that the parameters listed for 1 are broadly in line with those of closely similar compounds. but the CH 2 -Br bond length is among the longest and the ring-CH 2 -Br torsion angle is among the closest to 90 • .
In summary, the simple but unstable compound 2,6-dimethoxybenzyl bromide has been characterised for the first time, with its melting point, UV, IR, 1 H and 13 C-NMR spectra recorded. A correct HRMS measurement was obtained for M + -Br. The X-ray structure was also determined and shows structural parameters in good agreement with similar highly substituted benzyl bromides.  In summary, the simple but unstable compound 2,6-dimethoxybenzyl bromide has been characterised for the first time, with its melting point, UV, IR, 1 H and 13 C-NMR spectra recorded. A correct HRMS measurement was obtained for M + -Br. The X-ray structure was also determined and shows structural parameters in good agreement with similar highly substituted benzyl bromides.

Experimental Section
Melting points were recorded on a Reichert hot-stage microscope (Reichert, Vienna, Austria) and are uncorrected. UV spectra were recorded using a Shimadzu (Milton Keynes, UK) instrument and IR spectra were recorded on a Perkin-Elmer 1420 instrument (Perkin-Elmer, Waltham, MA, USA). NMR spectra were recorded using a Bruker (Bruker, Billerica, MA, USA) AV instrument at 300 MHz ( 1 H) and a Bruker AV III instrument at 125.8 MHz ( 13 C) in CDCl3 with chemical shifts given with respect to Me4Si and coupling constants in Hz. HRMS was recorded using a Thermo Fisher Exactive Orbitrap instrument in ESI mode.

Experimental Section
Melting points were recorded on a Reichert hot-stage microscope (Reichert, Vienna, Austria) and are uncorrected. UV spectra were recorded using a Shimadzu (Milton Keynes, UK) instrument and IR spectra were recorded on a Perkin-Elmer 1420 instrument (Perkin-Elmer, Waltham, MA, USA). NMR spectra were recorded using a Bruker (Bruker, Billerica, MA, USA) AV instrument at 300 MHz ( 1 H) and a Bruker AV III instrument at 125.8 MHz ( 13 C) in CDCl 3 with chemical shifts given with respect to Me 4 Si and coupling constants in Hz. HRMS was recorded using a Thermo Fisher Exactive Orbitrap instrument in ESI mode.
Author Contributions: E.A.S. prepared the compound and obtained the NMR spectra; A.M.Z.S. collected the X-ray data and solved the structure; R.A.A. designed the experiments, ran the IR and UV spectra, analysed the data, and wrote the paper. All authors have read and agreed to the published version of the manuscript.
Funding: This research received no external funding.

Data Availability Statement:
The X-ray data is deposited at CCDC as stated above and all spectroscopic data is in the Supplementary Material.