Source: https://pubs.rsc.org/en/content/articlehtml/2019/re/c8re00209f
Timestamp: 2019-04-18 17:06:59+00:00

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A solvent-free organocatalyzed process for the transesterification of dimethyl carbonate (DMC) with 1,2-diols under scalable continuous flow conditions is presented. Process parameters, such as temperature, residence time, DMC/glycerol molar ratio and catalyst loading are optimized for the carbonation of bio-based glycerol using 1,8-diazabicyclo(5.4.0)undec-7-ene (DBU) as a model organocatalyst. The catalytic performance of DBU is next compared with other homogeneous organic superbases including the proton sponge, Verkade's base, guanidines and phosphazenes. 2-tert-Butyl-1,1,3,3-tetramethylguanidine (Barton's base) stands as the most efficient organocatalyst, providing glycerol carbonate at 87% selectivity and 94% conversion within 2 minutes of residence time at 1 mol% loading. Representative examples of polystyrene-supported (PS) organic superbases of the amidine, guanidine and phosphazene-types are also considered as alternative heterogeneous catalysts. PS superbases typically enable up to 80 h of continuous operation with minor deactivation at elevated flow rates. The methodology is amenable to a library of other 1,2-diols, including biomass-derived substrates. Depending on the unique structural features of both substrates and products, either on-line IR or on-line NMR analytical procedures are implemented for real-time qualitative reaction monitoring. A final demonstrator showcases the transposition of the glycerol carbonation to a pilot-scale continuous flow reactor, affording the target cyclic carbonate with a 68.3 mol per day productivity (∼8 kg per day).
Fig. 1 Synthetic methodologies for the transformation of glycerol into glycerol carbonate.
In this contribution, we describe a solvent- and metal-free process under scalable continuous flow conditions for the upgrading of glycerol into glycerol carbonate. Process parameters – such as residence time, temperature, glycerol/DMC molar ratio and catalyst loading – were thoroughly assessed with DBU as the model homogeneous catalyst. A library of homogeneous organocatalysts, including the proton sponge, Verkade's base, guanidines and phosphazenes, was then investigated using the optimized process conditions. 2-tert-Butyl-1,1,3,3-tetramethylguanidine (Barton's base) appeared as the most promising catalyst, giving a 94% glycerol conversion with an 87% glycerol carbonate selectivity. This result was achieved at 1 mol% loading, 135 °C, with 2 min of residence time and 3 equiv. of DMC. To further improve the cost-efficiency and ease downstream purification, supported organocatalysts – such as polymer-bound DBU, P2-t-Bu phosphazene and tetramethylguanidine – were assessed as well. These heterogeneous organocatalysts proved to exhibit excellent stability over time, as conversion typically decreased by 13–15% after 80 h of operation. The methodology was extended to other 1,2-diols, including biomass-derived substrates, which were converted into the corresponding cyclic carbonates in good to excellent yields. Depending on the unique features of both substrates and products, either on-line IR or on-line NMR analytical procedures were implemented for convenient real-time qualitative reaction monitoring. Upon optimization of process parameters and organocatalysts, the methodology for glycerol carbonate was then applied to a commercial mesofluidic continuous flow reactor to assess the scalability using the best homogeneous catalyst (Barton's base). The conditions were then further applied to a pilot-scale continuous flow reactor, affording glycerol carbonate with a 68.3 mol per day productivity.
Conversion and yield were determined by gas chromatography coupled with flame ionization detection (GC/FID) or high field 1H NMR spectroscopy with mesitylene as the internal standard. Structural identity was confirmed by 1H and 13C NMR spectroscopy conducted on a high field (400 MHz) Bruker Avance spectrometer in CDCl3 or d4-MeOD (ESI†). The chemical shifts are reported in ppm relative to TMS as the internal standard or to the solvent residual peak. GC conversions were determined using external calibration curves established using commercial standards of ethanediol, 1,2-propanediol, 1,2,3-propanetriol, 3-methoxy-1,2-propanediol, 3-tert-butoxy-1,2-propanediol, 1,2-butanediol, 2,3-butanediol, 3-butene-1,2-diol and 1,4-anhydroerythritol. GC yields were determined using external calibration curves established using commercial standards of 1,3-dioxolan-2-one, 4-methyl-1,3-dioxolan-2-one, 4-hydroxymethyl-1,3-dioxolan-2-one, 4-methoxymethyl-1,3-dioxolan-2-one, 4-ethyl-1,3-dioxolan-2-one, 4-vinyl-1,3-dioxolan-2-one and a synthesized sample of methyl ((2-oxo-1,3-dioxolan-4-yl)methyl) carbonate. Selectivity is defined as the ratio between the yield and the conversion. On-line IR reaction monitoring was carried out using a FlowIR™ from Mettler-Toledo. On-line NMR reaction monitoring was carried out using a 43 MHz Spinsolve™ carbon NMR spectrometer from Magritek®. Downstream pressures were regulated using dome-type backpressure regulators (7–11 bar, Zaiput Flow Technologies). Ethanediol, 1,2-propanediol, 1,2,3-propanetriol, 3-methoxy-1,2-propanediol, 3-tert-butoxy-1,2-propanediol, 1,2-butanediol, 2,3-butanediol, 3-butene-1,2-diol, 1,4-anhydroerythritol, dimethyl carbonate (DMC), 1,8-diazabicyclo(5.4.0)undec-7-ene (DBU), 2,8,9-trimethyl-2,5,8,9-tetraaza-1-phosphabicyclo[3.3.3]undecane (Verkade's base), 1,8-bis-(dimethylamino)-naphthalene (DMAN), 1,1,3,3-tetramethylguanidine (TMG), 2-tert-butyl-1,1,3,3-tetramethylguanidine (Barton's base), 1,8-bis(tetramethylguanidino)naphthalene (TMGN), imino-tris-(dimethylamino)phosphorane (P1-H), tert-butylimino-tris(dimethyl-amino)phosphorane (P1-t-Bu), tert-octylimino-tris(dimethylamino)-phosphorane (P1-t-Oct), tert-butylimino-tris(pyrrolidino)-phosphorane (BTPP), 2-tert-butylimino-2-diethylamino-1,3-dimethylperhydro-1,3,2-diazaphosphorine (BEMP), tetramethyl-(tris(dimethylamino)phosphoranylidene)-phosphorictriamid-ethyl-imine (P2-Et), polystyrene-supported phosphazene base P2-t-Bu (1.6 mmol g−1) and polystyrene-supported DBU (1.5–2.5 mmol g−1) were obtained from commercial sources and used as received. Polystyrene-supported TMG, methyl ((2-oxo-1,3-dioxolan-4-yl)methyl) carbonate and 2-benzyl-1,1,3,3-tetramethylguanidine (BnTMG) were prepared following literature procedures (ESI†).
Homogeneous carbonation (microscale). The reactor for the homogeneous carbonation of glycerol (Fig. 2 and Table 3) consisted of a modular continuous flow assembly made of a high purity PFA capillary coil (1/16′′ o.d., 1/32′′ i.d.) equipped with Super Flangeless nuts and ferrules (IDEX/Upchurch Scientific). The reactor for the homogeneous carbonation of diols (Table 3) featured a modular continuous flow assembly consisting of plug-and-play thermoregulated stainless-steel (SS) coils (1.58 mm outer diameter, 500 μm internal diameter) equipped with SS connectors, ferrules and unions (Valco). Feed and collection lines consisted of PEEK tubing (1.58 mm outer diameter, 750 μm internal diameter) equipped with PEEK/ETFE connectors and ferrules (IDEX/Upchurch Scientific). Feed solutions were introduced using high force Chemyx Fusion 6000 syringe pumps equipped with SS syringes and Dupont Kalrez O-rings.
Fig. 2 Simplified continuous flow setup for the homogeneous carbonation of glycerol.
Heterogeneous carbonation (microscale). The reactor for the heterogeneous carbonation of glycerol (Fig. 6b) featured a modular continuous flow assembly consisting of plug-and-play thermoregulated stainless-steel (SS) coils (1.58 mm outer diameter, 500 μm internal diameter) equipped with SS connectors, ferrules and unions (Valco), and a SS packed-bed column (5 cm × 10 mm o.d. × 7.5 mm i.d.). Feed and collection lines consisted of PEEK tubing (1.58 mm outer diameter, 750 μm internal diameter) equipped with PEEK/ETFE connectors and ferrules (IDEX/Upchurch Scientific). Feed solutions were introduced using HPLC pumps, equipped with 316 SS parts and check valves (IDEX/Upchurch Scientific).
Homogeneous carbonation (mesoscale). Mesofluidic lab-scale (13 mL internal volume) and pilot-scale (40 mL internal volume) Corning® Advanced-Flow™ reactors were used to scale out the homogeneous carbonation of glycerol (Fig. 10). The reactor configuration involved 5 glass fluidic modules (FMs, 2.6 mL or 8 mL internal volume each) connected in series. Each fluidic module was designed with a specific number of inlets and integrated by two layers of heat exchangers. The thermoregulation of the glass fluidic modules was carried out with two LAUDA® Proline RP 845 thermostats. Two thermocouples were positioned at critical positions along the thermofluid flow path for temperature monitoring. HPLC-type pumps were used to deliver the feed solutions into the lab-scale mesofluidic reactor through a section of PFA tubing (1/8′′ o.d., 0.03 inch wall thickness). Corning dosing lines (FUJI Technologies™ pumps) were utilized to deliver the feed solutions into the pilot-scale mesofluidic reactor through a section of PFA tubing (1/4′′ o.d.).
Homogeneous carbonation of glycerol (microscale). The syringe pump used to deliver neat glycerol (1) was set to 223 μL min−1 (1 equiv.) and the syringe pump used to deliver the 0.041 M solution of Barton's base in DMC was set to 777 μL min−1 (1 mol% Barton's base, 3 equiv. DMC). Both streams were mixed through a PEEK T-mixer. The homogeneous mixture entered a PFA capillary coil (1/16′′ o.d., 1/32′′ i.d., 2 mL internal volume) heated at 135 °C. The outlet of the capillary coil reactor was connected to a dome-type back-pressure regulator set at 7 bar (Fig. 2). After equilibration, the reactor effluent was collected, quenched with saturated aqueous NH4Cl, diluted with EtOH, and analyzed by GC/FID (82% yield in glycerol carbonate, see Table 2).
a Conditions: 135 °C, 2 min residence time, 3 equiv. DMC, 1 mol% organocatalyst. b Conversion and yield were determined by GC/FID. c 2 mol% organocatalyst.
Heterogeneous carbonation of glycerol (microscale). A preheated (50 °C) feedstock of glycerol (1) was injected through a HPLC pump with a heated-pump head (50 °C) at a flow rate of 0.07 mL min−1 (1 equiv.). The HPLC pump used to deliver neat DMC was set to 0.24 mL min−1 (3 equiv.). Both streams were mixed through a PEEK T-mixer. The mixture was preheated in a SS coil (1.58 mm o.d., 500 μm i.d., 0.5 mL internal volume), and then reacted in a SS column (5 cm × 10 mm o.d. × 7.5 mm i.d.), both heated at 135 °C. The SS column was loaded with 250 mg of PS-P2-t-Bu (1.6 mmol g−1 loading) dispersed with 2.4 g of glass beads (425–600 μm). The reactor effluents were conveyed through an on-line IR spectrometer for reaction monitoring. A dome-type back-pressure regulator was connected downstream and set to 7 bar (Fig. 6b). The reactor effluents were periodically sampled, diluted with EtOH and analyzed by GC/FID to complement the IR data.
Homogeneous carbonation of 2,3-butanediol (microscale). The syringe pump used to deliver neat 2,3-butanediol (4c) was set to 52.5 μL min−1 (1 equiv.) and the syringe pump used to deliver the 0.079 M solution of Barton's base in DMC was set to 148 μL min−1 (2 mol% Barton's base, 3 equiv. DMC). Both streams were mixed through a PEEK T-mixer. The homogeneous mixture entered a SS coil (1.58 mm o.d., 500 μm i.d., 1.6 mL internal volume) heated at 180 °C. The reactor effluents were conveyed through an on-line NMR spectrometer for reaction monitoring. A dome-type back-pressure regulator set at 11 bar was positioned downstream the reactor (Table 3). After equilibration, the reactor effluent was collected and analyzed by high-field 1H NMR in CDCl3 using mesitylene as the internal standard (72% yield, see Table 2).
Conditions A: 135 °C, 2 min residence time, 1 mol% catalyst, 7 bar. Conditions B: 160 °C, 4 min residence time, 2 mol% catalyst, 7 bar. Conditions C: 180 °C, 8 min residence time, 2 mol% catalyst, 11 bar.a Conversion and yield were determined by GC/FID.b Yield, determined by high-field 1H NMR in CDCl3 with mesitylene as the internal standard.c Conversion was determined by GC/FID and yield was determined by high-field 1H NMR in CDCl3 with mesitylene as the internal standard.
Homogeneous carbonation of glycerol (mesofluidic lab-scale). A preheated (50 °C) feedstock of glycerol (1) was injected through a HPLC pump with a heated-pump head (50 °C) at a flow rate of 1.45 mL min−1 (1 equiv.). The HPLC pump used to deliver the 0.041 M solution of DBU in DMC was set to 5.05 mL min−1 (1 mol% DBU, 3 equiv. DMC). Both streams were mixed within the first fluidic module of the Corning® Advanced-Flow™ reactor operated at 135 °C. The mixture was reacted in 4 additional glass fluidic modules connected in series (2.6 mL internal volume each, 2 min residence time) at 135 °C. The outlet of the glass mesofluidic reactor was equipped with a dome-type back-pressure regulator set at 7 bar (Fig. 10). After equilibration, the reactor effluent was collected, quenched with saturated aqueous NH4Cl, diluted with EtOH, and analyzed by GC/FID (74% yield in glycerol carbonate, 21 mol per day productivity).
Homogeneous carbonation of glycerol (mesofluidic pilot-scale). The pump used to deliver the preheated (50 °C) feedstock of glycerol was set to 5.6 g min−1 and the pump used to deliver the 0.041 M solution of Barton's base in DMC was set to 16.6 g min−1 (1 mol% Barton's base, 3 equiv. DMC). Both streams were mixed within the first fluidic module of the Corning® Advanced-Flow™ reactor operated at 135 °C. The mixture was reacted in 4 additional glass fluidic modules connected in series (8 mL internal volume each, 2 min residence time) at 135 °C. The outlet of the glass mesofluidic reactor was equipped with a dome-type back-pressure regulator set at 7 bar (Fig. 10). After equilibration, the reactor effluent was collected, quenched with saturated aqueous NH4Cl, diluted with EtOH, and analyzed by GC/FID (78% yield in glycerol carbonate, 68.3 mol per day productivity).
The investigation commenced with a thorough assessment of the parameters influencing the carbonation of neat glycerol (1) with dimethyl carbonate (DMC). DBU, a known organocatalyst for the carbonation of 1,15,17 was selected as the model catalyst. In a representative experiment, neat 1 and the solution of DBU in DMC were mixed through a T-mixer, and the biphasic mixture entered a heated capillary coil reactor, where it rapidly became homogeneous. A BPR set at 7 bar was inserted downstream the reactor to afford process temperatures above the boiling point of some components of the liquid phase (Fig. 2). The effluent of the reactor was analyzed by off-line GC/FID, and glycerol carbonate (2) was detected as the main product along with methyl ((2-oxo-1,3-dioxolan-4-yl)methyl) carbonate (3) as a minor impurity (ESI†).
In a preliminary set of experiments, a 3 : 1 DMC/glycerol molar ratio with 1 mol% of catalyst was reacted within 2 min of residence time, and the temperature was varied from 95 to 150 °C. The selectivity for 2 varied in the 70–79% range, while the conversion increased from 65% to 96% with the temperature (Fig. 3), and the selectivity for 3 increased from 0.7 to 6%. 135 °C was selected as the best temperature for further optimization, as it gave high conversion (89%) and selectivity (79%), while balancing the energy costs.
Fig. 3 Evolution of the conversion of glycerol (blue dots) and of the selectivity for glycerol carbonate (2) (orange dots) and methyl ((2-oxo-1,3-dioxolan-4-yl)methyl) carbonate (3) (grey dots) as a function of the temperature. Conditions: 2 min residence time, 3 equiv. DMC, 1 mol% DBU.
Next, the influence of the residence time was studied (ESI†). When it was increased from 1 to 2 min, the conversion improved from 78 to 89%. However, a further increase of up to 5 min led to a further increase in conversion (97%), while decreasing the productivity and selectivity for 2 (71–79% range). As the residence time increased, the selectivity for 3 increased from 1.7 to 6.8%. Therefore, the residence time was set at 2 min for further optimization. When the molar ratio between DMC and glycerol increased from 1.5 to 3, the conversion of 1 and selectivity for 2 improved from 80 to 89% and from 72 to 79%, respectively (ESI†). However, increasing the DMC amount up to 5 equiv. did not lead to any further improvement. The selectivity toward 3 followed a similar trend, evolving from 1.5 to 3.8% in the 1.5–3 molar ratio range, and then plateauing at 3.6–4% at a higher DMC excess. Finally, the catalytic loading of DBU was evaluated (Fig. 4).
Fig. 4 Evolution of the conversion of glycerol (blue dots) and of the selectivity for glycerol carbonate (2) (orange dots) and methyl ((2-oxo-1,3-dioxolan-4-yl)methyl) carbonate (3) (grey dots) as a function of the loading in DBU. Conditions: 135 °C, 2 min residence time, 3 equiv. DMC.
This parameter had a critical impact on both conversion and selectivity. An increase from 0.1 to 1 mol% led to an increase in the conversion from 43 to 89%, and the selectivity for 2 decreased in the 79–87% range. At higher loading, the conversion was slightly improved (96% at 3 mol%), and the selectivity remained in the 79–82% range. The selectivity for 3 reached up to 5.3% as the catalyst loading increased from 0.1 to 1.5 mol%, and increased up to 6.6% with 3 mol% DBU. A similar trend was observed with Barton's base as the organocatalyst (ESI†).
With the optimized process conditions under homogeneous continuous flow conditions (135 °C, 2 min, 3 equiv. DMC), we assessed a library of organic superbases as potential catalysts (Fig. 5, Table 2). Catalyst loadings of 0.5, 1, 1.5 and 2 mol% were assessed for the catalysts depicted in Fig. 5 (see also Table 2). A loading of 1 mol% gave the best conversion/selectivity balance (ESI†). The library included proton sponge (DMAN), proazaphosphatrane (Verkade's base), guanidines (TMG, Barton's base, BnTMG and TMGN), and phosphazenes (P1-H, P1-t-Bu, P1-t-Oct, BTPP, BEMP and P2-Et).
Fig. 5 Structure of the organic bases assessed for the carbonation of glycerol. Literature values of the experimental pKBH+ in MeCN are given in parenthesis (a = from ref. 37, b = from ref. 45, c = from ref. 46, d = from reference ref. 47, e = from ref. 48, f = not available).
The proton sponge (DMAN) was the least efficient catalyst, giving a mere 9% glycerol conversion (Table 2, entry 3). Its low pKBH+ value (18.2) accounted for such low conversion. TMG, with the second lowest pKBH+ value (23.3), gave a glycerol conversion of 68% (entry 4), while more basic catalysts gave conversions in the 82–97% range. Similar observations were made by Kelkar et al., who used amines and amidines as organocatalysts for the synthesis of 2 from 1 and DMC: the activity increased with the basicity of the nitrogen base, and amidines were thus better catalysts than amines.15 Similarly, Corma and co-workers assessed P1-t-Bu and P4-t-Bu phosphazenes for the transesterification of vegetable oils with methanol, and reported a direct correlation between the basicity and the activity of the catalyst.38 Our results indicate that in the 23.6–32.9 pKBH+ range, the basicity of the active site is not the only determining factor for activity. For example, Barton's base (pKBH+ = 23.6) is far more active (conv. = 94%) than Verkade's base (pKBH+ = 32.8, conv. = 82%) despite the higher basicity of the latter (entries 2 and 5). Overall, the best results were obtained with Barton's base (entry 5), and sterically hindered phosphazenes such as P1-t-Bu, P1-t-Oct, BTPP, BEMP and P2-Et (entries 9–13), affording glycerol conversions in the 93–97% range and selectivities toward 2 in the 80–87% range. The highest yield (82%) for glycerol carbonate was obtained with Barton's base, and this organocatalyst thus appeared as the most efficient.
To further increase cost-efficiency of the process and ease downstream operation, we envisioned the utilization of supported organocatalysts. Resin-grafted DABCO (1,4-diazabicyclo[2.2.2]octane) and analogs were already reported as efficient heterogeneous catalysts for this reaction.16,18 Here, we assessed the heterogenized version of the best homogeneous catalysts above-mentioned, namely, polystyrene-supported P2-t-Bu (PS-P2-t-Bu) and polystyrene-supported TMG (PS-TMG). Polystyrene-supported DBU (PS-DBU) was utilized as a reference catalyst, as for the homogeneous process. PS-P2-t-Bu and PS-DBU were commercially available, while PS-TMG was prepared from TMG and Merrifield's resin according to a reported procedure (ESI†). In a representative experiment, neat glycerol was mixed with neat DMC through a T-mixer. The biphasic mixture was pre-heated in the first loop, and then reacted through a fixed-bed reactor packed with a dispersion of the PS-organocatalyst in glass beads. The reactor effluents were conveyed toward an on-line IR spectrometer that enabled continuous monitoring of the catalyst's performances over time (Fig. 6b and ESI†). Quantitative data for conversion and yield were obtained from periodic samples of the effluents of the reactor (GC/FID).
Fig. 6 a. Structure of the active sites of the polystyrene-supported organocatalysts assessed for the heterogeneous carbonation of glycerol. b. Simplified continuous flow setup for the heterogeneous carbonation of glycerol.
Fig. 7 Evolution of glycerol conversion (blue dots) and glycerol carbonate selectivity (orange dots) as a function of the WHSV (off-line GC/FID). The WHSV is defined as the mass of glycerol fed per hour and per mass of PS-P2-t-Bu. Conditions: 135 °C, 3 equiv. DMC.
PS-P2-t-Bu, PS-TMG and PS-DBU were then evaluated at a steady WHSV of 20.8 h−1 for prolonged operation times (up to 80 h), to assess their stability. This WHSV was selected since it gave a good balance between conversion and productivity. Using PS-P2-t-Bu, the glycerol conversion decreased from 91% after 3 h of operation to 78% after 33 h and then remained steady for the next 50 h (Fig. 8a). The selectivity was not affected by the operation time, remaining in the 77–84% range. PS-TMG was less active and less stable than its phosphazene counterpart: glycerol conversion decreased from 89% after 1 h of operation to 74% after 25 h (Fig. 8b). The selectivity for 2 remained in the 65–71% range. PS-TMG was also assessed at a lower WHSV (10.5 h−1), and gave steady conversions (97–98%) and selectivities (64–74%) for over 47 h of operation (ESI†). PS-DBU gave a slightly lower selectivity for glycerol carbonate than PS-P2-t-Bu, although its stability over time was quite similar. Glycerol conversion decreased steadily from 93% after 2 h of operation to 78% after 73 h (Fig. 8c). Again, the selectivity for 2 was not affected by the operation time, and varied in the 68–78% range.
Fig. 8 On-line reaction monitoring showing the evolution of the conversion to glycerol carbonate by combining on-line IR qualitative monitoring (orange series, relative intensity of the characteristic vibration band at the 1403 cm−1 band) and off-line quantitative GC/FID (blue dots, conversion of 1). Conditions: 135 °C, 3 equiv. DMC, WHSV = 20.8 h−1, PS-supported organocatalyst = a. PS-P2-t-Bu, b. PS-TMG, c. PS-DBU.
In a representative run, neat diol 4 was mixed with 3 equiv. of DMC and 1 mol% of Barton's base through a static T-mixer, and the mixture was reacted using the optimized operating conditions on glycerol (135 °C, 7 bar, 2 min or residence time) in a coil reactor (conditions A). The diols 4a, b, d, and f with comparable steric and electronic features to 1 underwent transesterification with DMC under conditions A with conversions in the 82–96% range and selectivities toward the corresponding carbonates 5a, b, d, and f in the 79–85% range (entries 2, 3, 5 and 7).
For some diols with higher steric hindrance or specific structural features, low conversions were obtained under conditions A, and reoptimization was required (ESI†). An on-line NMR spectrometer was positioned downstream the reactor for real-time monitoring of the process,55–57 ensuring fast reoptimization (ESI†). Samples were collected downstream, processed and analyzed by GC/FID to obtain quantitative information. Some substrates such as diols 4e, g, and h required 160 °C and a longer residence time (4 min) with 2 mol% of catalyst to reach a conversion in the 63–96% range and selectivity toward the corresponding carbonates 5e, g, and h in the 87–91% range.58 Interestingly, anhydroerythritol carbonate (5h) crystallized upon standing in a fridge at 4 °C overnight from the crude reactor effluent. After filtration and washing with diethyl ether, white needles of 5h were isolated, and their purity was confirmed by high-field NMR (ESI†). Substrate 4c was more demanding and required 8 min of residence time at 180 °C with 2 mol% of Barton's base to afford a 72% yield.
The latter reaction serves as an illustration of on-line low-field NMR optimization. Fig. 9 shows representative spectra acquired during the carbonation of 2,3-butanediol (4c) to 5c. Qualitative assessment of the reaction was carried out by comparing the relative intensities of a characteristic signal of 4c (0.6 ppm, light grey) and of 5c (1 ppm, dark grey).
Fig. 9 On-line NMR reaction monitoring showing the variation of the concentrations in 2,3-butanediol (4c) and 2,3-butylene carbonate (5c). The doublet at 0.6 ppm (light grey) was used to monitor the variation in the concentration of 4c. The doublet at 1 ppm (dark grey) was used to monitor the variation in the concentration of 5c.
Two options were available for reaching the production scales under continuous flow conditions with the abovementioned results, either using a fixed-bed reactor packed with a heterogeneous catalyst or a flow reactor using a homogeneous catalyst. With the best performing heterogeneous catalyst (PS-P2-t-Bu), the long runs (see above) have emphasized that the conversion decreased from ∼90% to 80% for over 30 h and then plateaued at ∼80% for a production campaign of 80 h. With this in mind, plus the cost associated with such a heterogeneous catalyst, the homogenous option is arguably the most appealing option. Indeed, it affords a constant reaction profile and the low catalytic loading can be easily trapped downstream on an acidic heterogeneous material and recycled. The scalability of the homogeneous process was thus evaluated using commercial continuous flow glass reactors (Fig. 10) (Corning® Advanced-Flow™ G1LF and G1 reactors and the best performing homogeneous catalyst, i.e. Barton's base). Based upon the results obtained on the microscale, the best operating conditions were applied first in a mesofluidic reactor of 13 mL total internal volume featuring 5 fluidic modules (2.6 mL internal volume each, Corning® Advanced-Flow™ G1LF) fluidically connected in series and integrated with a heat exchanger. DBU was first selected as a homogeneous catalyst (1 mol%) for direct comparison with the microscale results. Process conditions were directly transposable from the microscale to mesoscale, affording 93% conversion, 74% yield and 79% selectivity toward glycerol carbonate with 2 min of residence time at 135 °C (7 bar). Increasing the residence time to 3 min left the conversion unaffected, although a slight increase in yield (80%) and selectivity (87%) was noticed.
Fig. 10 Photograph of the Corning® Advanced-Flow™ G1LF for the production of glycerol carbonate. I1: inlet for preheated glycerol; I2: inlet for DMC and Barton's base; H: inlet and outlet for the thermofluid; FM: fluidic module; O: reactor outlet; BPR: back pressure regulator.
Aiming for larger productivity, the 2.6 mL internal volume fluidic modules were changed to pilot-scale 8 mL internal volume fluidic modules, thus giving a flow setup of 40 mL total internal volume (Corning® Advanced-Flow™ G1). The same operating parameters (135 °C, 7 bar, 2 min, 1 mol% DBU, 3 equiv. DMC) afforded 92% conversion, 73% yield and 80% selectivity toward glycerol carbonate, thus giving consistent results without reoptimization. The best operating conditions on the pilot scale were next assessed with Barton's base as the homogeneous catalyst. With 3 min of residence time, 97% conversion was obtained, while with only 2 min of residence time, up to 98% conversion with 80% selectivity was obtained for glycerol carbonate. Under these conditions, a 68.3 mol per day productivity (∼8 kg per day) for glycerol carbonate was obtained with a reactor featuring a L × l × h 90 × 30 × 40 cm footprint (frame included, Fig. 10).
This work illustrates a solvent-free organocatalyzed continuous flow process for the transesterification of dimethyl carbonate with various 1,2-diols. A palette of homogeneous organic superbases such as the proton sponge, DBU, Verkade's base, guanidines and phosphazenes were assessed as catalysts for the transesterification on glycerol as a model substrate under microfluidic conditions. 2-tert-Butyl-1,1,3,3-tetramethylguanidine (Barton's base) was identified as the most efficient organocatalyst, affording glycerol carbonate with 87% selectivity and 94% conversion within 2 minutes of residence time at 1 mol% loading under microfluidic conditions at 135 °C under 7 bar of counter-pressure. These conditions surpass all reported homogeneous procedures so far. Alternatively, supported organic superbases were next evaluated as heterogeneous catalysts under flow conditions. Under heterogeneous conditions, microfluidic operation could be maintained for up to 80 h with elevated flow rates, and the conversion typically dropped from 10–15% through minor catalyst deactivation. Upon optimization, the homogeneous strategy was successfully expanded to a library of other 1,2-diols, including biomass-derived substrates. Depending on the unique features of both substrates and products, either on-line IR or on-line NMR analytical procedures were implemented for real-time qualitative reaction monitoring. The most valuable process from the industrial perspective, i.e. the transesterification toward glycerol carbonate, was next applied under mesofluidic conditions. In less than one day, the microfluidic conditions were successively applied to lab-scale and then finally pilot-scale continuous flow reactors without reoptimization, affording the target cyclic carbonate with a productivity of 68.3 mol per day (∼8 kg per day).
This work was supported by the University of Liège (Welcome Grant WG-13/03, JCMM). ZW acknowledges the Department of Education (Hubei Province, China) and the Hubei Polytechnic University for their financial support.
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‡ Current address: Hubei Key laboratory of Mine Environmental Pollution Control and Remediation, School of Chemistry and Chemical Engineering, Hubei Polytechnic University, Huangshi, 435003, Hubei, China.

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