Electronic upplementary Material (EI) for ChemComm. This journal is The Royal ociety of Chemistry 2016 upporting Information Allyl orates: A Novel Class of Polyhomologation Initiators De Wang, Nikos Hadjichristidis* King Abdullah University of cience and Technology (KAUT), Physical ciences and Engineering Division, KAUT Catalysis Center, Polymer ynthesis Laboratory, Thuwal 23955, Kingdom of audi Arabia E-mail: nikolaos.hadjichristidis@kaust.edu.sa Experiment ection Instruments: High temperature size exclusion chromatography (HT-EC) measurements were carried out on a Viscoteck HT-GPC module 350 instrument with two PLgel 10 μm MIXED- columns, using 1,2,4- trichlorobenzene (TC) as eluent at a flow rate of 0.8 ml/min at 150 ºC or on an Agilent PL-GPC 220 with one PLgel 10 μm MIXED- column using TC as eluent at a flow rate of 1.0 ml/min at 150 ºC. oth systems were calibrated by versus P standards. The 1 H NMR spectra were recorded with a ruker AVANCE III-500 or 600 spectrometer. 11 NMR spectra were recorded with a ruker AVANCE III-600 spectrometer. Materials enzyltri-n-butylammonium chloride (98%, Alfa Aesar) and trimethylamine N-oxide dihydrate (TA) (>99%, Fluka) were used as received. odium hydride (60% dispersion in mineral oil, Acros) was washed with petroleum ether (40-60 ºC) prior to use. Methanol (99%, Fisher), dichloromethane (>99%, Fisher) were obtained from Fisher and used as received. Tetrahydrofuran (99%, Fisher) and toluene (99.7%, Fluka) were distilled from sodium prior to use. Initiator 2 used in this paper either bought from Aldrich or synthesized follow the literature. 1 The initiator bought from Aldrich was distilled one time prior to use. The advantages of the monofunctional borate initiators
A m poly(sustituted methylenes) crosslinked or left-over vinyls PM-ased Architectures H 3 hydroboration Inter- or intramolecular hydroboration H 2 polymer with more than three vinyl side groups X X H X: blocking group X2 X 2 X 2 X 2 PM-ased Architectures C R H (Hpin) R alkene borate CH 2 ()Me 2 polyhomologation R m H A-Alknye n (n = 1, 2, 3...) A H excess polymeric multi-boron containing intiators CH 2 ()Me 2 polyhomologation A() n ( is polymethylene) no need to purify initiator (Hpin does not initiate polyhomologation) no side reactions(one active with two blocked sites) easy speratation of PE-based polymer and starting polymer cheme 1 The advantage of a monofunctional compared to the di- and trifunctional hydroboration initiators precursors towards the synthesis of well-defined PM-based complex macromolecular architectures Until now borane (trifunctional) and thexyl hydroborane (difunctional) were used to attach PM branches on the backbone through hydroboration and polyhomologation. However, since intermolecular and intramolecular hydroboration reactions are possible, either cross-linked polymers or polymers with left-over double bonds will be formed. This problem could only be solved with a monofunctional hydroborane (cheme 1, ). Inspired by this monofunctional hydroborane strategy, new borate containing initiators leading to PM-based macromolecular architectures is under investigation. For example, alkene borates generated from hydroboration with alkyne are applied in polyhomologation (cheme 1, C). The potential of this strategy is limited only by our imagination. ynthesis of Initiator 2
r + Mg + H ref. 1 THF, rt, 3 h 2 The following procedure is the general procedure for the preparation of Allylpinacolboronate 2: A 25 ml pre-dried flask equipped with a stirring bar was charged with magnesium turnings (0.08 g, 3.3 mmol) and fitted with a rubber septum. Under argon protection, dry THF was injected to the flask followed by PinH (0.40 ml, 2.74 mmol). To the above mixture allyl bromide (0.23 ml, 2.74 mmol) was added dropwise with constant stirring over 10 minutes at room temperature. After 30 min of stirring at this temperature, another 1 equiv. of allyl bromide was added to the mixture. After two hours stirring at room temperature, the magnesium turnings were fully consumed. Then the mixture was diluted with hexane (10 ml) and quenched with aqueous 0.5 M HCl (10 ml) under 0 o C. After 15 mins of stirring the reaction mixture was transferred to a separatory funnel and extracted with hexanes (twice, 2x20 ml). The combined organic layers were dried over anhydrous Na 2 4, filtered and after chromatography (or distilled at room temperature under 1 Torr), a clear colorless oil was obtained in 85% yield (391 mg). Initiator 11 was synthesized follow the same procedure by using crotyl bromide instead of allyl bromide.
a b c d d c CDCl b a 3 H 2 * * Figure 1 1 H NMR spectrum of initiator 2 (CDCl 3, 25 o C, 600 MHz) Figure 2 11 NMR spectrum of initiator 2 (CDCl 3, 25 o C, 600 MHz)
DP NMR = 213 Figure 3 1 H NMR spectrum of polymer 3 (full spectrum, d 8 -toluene, 90 o C, 600 MHz, DP NMR =213 by NMR) H a H a H b n H c H c H H a :H b :H c = 2:1:2 H c H b H a Figure 4 1 H NMR spectrum of polymer 3 (partly enlarged, d 8 -toluene, 90 o C, 600 MHz)
32.9 ppm pin initiator 2 Polymeric borate crude polymer without any purification or oxidation 22.7 ppm Figure 5 11 NMR spectra of crude polymer 3 before oxidation/hydrolysis compared with the initiator 2 (d 8 - toluene, 25 o C, 600 MHz, baseline correction) 2 pin 2 + toluene, 80-120 o C excess 1 N Polymer eq. 1 H + N Polymer toluene, 80-120 o C eq. 2 Hpin excess 1 cheme 2 Using 2 pin 2 or Hpin to initiate the polyhomologation of ylide monomer 1 The polymerization of ylide 1 with 2 pin 2 doesn t give PM even at 120 o C. This can be attributed to the high stability of - and - bonds of 2 pin 2, having as consequence the blockage of the methylene insertion (EI, cheme 2, eq.1). imilarly, in the case of Hpin no polymer was produced, meaning that both -H bond and - do not promote polyhomologation (EI, cheme 2, eq. 2). This is most likely due to the low initiation ability of Hpin or it react with strong basicity of sulfoxonium methylide 1 to generate unknown borate complex that not able to further initiation of polyhomologation.
b c n a d polymer 12 H c a&b d d 8 -toluene d 8 -toluene * * * H 2 * Figure 6 1 H NMR spectrum of polymer 12 (d 8 -toluene, 90 o C, 600 MHz) Table 1 Influence of solvent and temperature on borate initiated polyhomologation Entry a DP cal b DP NMR c solvent T ( o C) Time(min) PDI d 1 30 185 toluene rt - e 3.78 2 30 166 toluene 60 40 f 1.51 3 30 - g Chlorobenzene/toluene 100 15 1.77 4 30 385 toluene 90 45 h 1.22 a All polymerization were carried out using allylic borate 1. b DP cal is the degree of polymerization, calculated from [M]/[I]. c DP NMR were determined by 1 H NMR (d 8 -toluene, 90 o C, 600MHz). d PDI were determined versus polystyrene standards by high temperature GPC (TC as solvent at 150 o C). e tirring for 3 days. f Heating the mixture of initiator and monomer at 60 o C for 10 minutes and then increased the temperature to 80 o C for 30 minutes. g The chain-end groups were difficult to be detected because of high molecular weight. h The mixture of initiator and monomer stirring at room temperature for 30 minutes and then at 90 o C for 15 minutes.
(1) (2) 2 1 toluene room temperature, 3 days. TA. 2H 2 n H 1 TA. 2H 2 toluene, 60-80 o n C H 2 3 Ylide monomer 1 in toluene under stirring for 10 minutes at 60 o C, addition of borate 2 and increasing the temperature to 80 o C 3 rt. 3 days 60-80 o C PDI HT-GPC = 3.78 PDI HT-GPC = 1.51 Retension Time (min) (3) 2 1 Chlorobenzene/toluene 100 o C TA. 2H 2 3 n H M n,gpc = 218 K PDI HT-GPC = 1.77 Retension Time (min) cheme 3 orate 2 initiated polyhomologation at room temperature, 80 o C and 100 o C with corresponding HT- GPC traces (TC, 150 o C) The polymerization of ylide 1 (3.0 mmol) with 2 (0.1 mmol) at room temperature (DP cal = 30) was incomplete even after 3 days. The reaction mixture was cloudy and a white solid precipitated by addition of the non-solvent ethanol (DP NMR = 185, PDI HT-GPC = 3.78, EI, cheme 3, eq.1). Heating the mixture (monomer 1, 3.0 mmol; allyl borate 2, 0.1 mmol) in toluene at 60 o C for 10 minutes, then increasing the temperature to 80 o C the reaction mixture became neutral within 30 minutes (ph = 7.0), indicating the complete consumption of monomer 1. After oxidation/hydrolysis, a polymer 3 with a relative narrow PDI but higher molecular weight than the calculated one was obtained (DP NMR = 166, PDI HT-GPC = 1.51, EI, cheme 3, eq.2). We also observed that the reaction mixture turns cloudy in toluene at 80 o C, meaning that the high PDI maybe caused due to the poor solubility of the high molecular weight PM in toluene at 80 o C. To identify if the heterogeneity is the source of the higher than the calculated value of molecular weight and the broad molecular distribution, a mixture of chlorobenzene and toluene was used as solvent at 100 o C. The polyhomologation reaction proceeded smoothly and homogeneously, however the molecular weight and PDI were also uncontroled (M n,ht-gpc = 218 kg/mol, PDI HT- GPC = 1.77, EI, cheme 3, eq.3).
2 toluene, T o C [ylide]:[] = 120:1 1 n H ylide concentration (mol/l) 60 o C time (min) Figure 7 Influence of the temperature on the borate initiated polyhomologation of ylide monomer 1 2 1 + 1) toluene, rt 2) toluene, 90 o C TA. 2H 2 n polymer 3 H M n,nmr = 5.4*10 3 g/mol PDI GPC = 1.22 Retension Time (min) cheme 4 Two-step polyhomologation reaction initiated by allylic borate
pin polymeric borate complex 60 o C 40 o C r.t. Zwitterionic intermediate -20 o C Figure 8 11 NMR spectra of initiator 2 with ylide monomer 1 ([I]/[M] = 1/1) at different temperatures (d 8 -toluene, 600 MHz). pin Initiator polymeric borate species zwitterionic intermediate (ate complex) 90 o C 80 o C 40 o C peak of NMR tube rt Figure 9 11 NMR spectra of initiator 2 with ylide monomer 1 ([I]/[M] = 1/10) at different temperatures (d 8 - toluene, 600 MHz).
Intensity ratio: Decreased Intensity ratio: Increased [M]/[] = 50/1 [M]/[] = 20/1 [M]/[] = 5/1 [] Figure 10 11 NMR spectra of ylide monomer with initiator at different concentrations ([M]/[], C 6 D 6, 25 o C, 600MHz, baseline correction) Ph phenyl pinacolborate 1 toluene, 90 o C or 120 o C [M]/[I] = 50/1 no polymer n-hexanyl pinacolborate 1 toluene, 90 o C [M]/[I] = 50/1 high molecular weight PM M n,ht-gpc = 494 kg/mol PDI HT-GPC = 2.1 Retension time (min) cheme 5 ubstituted borates initiators for polyhomologation of ylide monomer 1
T m : 86.75 C Crystallinity: 45.17 % (Table 1, entry 1) Tm : 125.86 C Crystallinity: 63.71 % (Table 2, entry 3) Temperature ( o C) Figure 11 DC thermographs of heterobifunctional polymer 3 (Table 1, entry 1 and 3). For low molecular weight (Table 1, entry 1, M n,nmr = 2.3 kg/mol) polymer 3, melting temperature (T m ) is 86.75 o C with crystallinity 45.17%. WIncreasing the molecular weight (Table 1, entry 1, M n,nmr = 13.1 kg/mol), the melting temperature (T m ) increased 125.86 o C with crystallinity of 63.71%. These values of T m are confirm the linear nature of the low molecular weight and high molecular weight polymers. CatH H 1 toluene, 80 o C TA. 2H 2 n H quantative yield, PE-H M n,ht-gpc = 16.8 K PDI GPC = 1.54 stabilizer Retension Volume (ml) Figure 12 Catecholborane (CatH) initiated polyhomologation of ylide monomer 1 in toluene at 80 o C
Initial experiments using catecholborane (CatH) to initiate polyhomologation of dimethylsulfoxonium methylide 1 in toluene at 80 o C, were successful (all ylide monomer consumed within 15 min, M n,ht-gpc = 16.8 kg/mol, PDI GPC = 1.54). In the 1 H NMR spectrum of the polymer the fingerprint of aryl protons are absent, meaning that - bonds are inactive (EI, Figure 11). H R R excess ylide TA R n H "R = functional group or polymeric group" cheme 6 Proposed work on catecholborane (CatR) initiated polyhomologation of ylide monomer Reference: 1 J. W. Clary, T. J. Rettenmaier, R. nelling, W. rykes, J. anwell, W. T. Wipke,. ingaram, J. rg. Chem., 2011, 76, 9602-9610.