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Received 1 Sep 2011 | Accepted 14 Nov 2011 | Published 13 Dec 2011 DOI: 10.1038/ncomms1596

Tandem synthesis of alternating polyesters from renewable resources

Carine Robert1, Frdric de Montigny1 & Christophe M. Thomas1

The vast majority of commodity materials are obtained from petrochemical feedstocks. These resources will plausibly be depleted within the next 100 years, and the peak in global oil production is estimated to occur within the next few decades. In this regard, biomass represents an abundant carbon-neutral renewable resource for the production of polymers. Here we report a new strategy, based on tandem catalysis, to obtain alternating polyesters from renewable materials. Commercially available complexes are found to be efcient catalysts for the cyclization of dicarboxylic acids followed by alternating copolymerization of the resulting anhydrides with epoxides. This operationally simple method is an attractive strategy for the production of new biodegradable polyesters.

1 Chimie ParisTech, UMR CNRS 7223 , 11 rue Pierre et Marie Curie, 75231 Paris Cedex 05 , France . Correspondence and requests for materials should be addressed to C.M.T. (email: [email protected] ) .

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NATURE COMMUNICATIONS | DOI: 10.1038/ncomms1596

The vast majority of commodity materials are obtained from fossil fuels 1 . However, these resources are limited and many studies predict that all fossil resources will be depleted within

a few centuries 25 . In this regard, biomass represents an abundant carbon-neutral renewable resource for the production of biomaterials 612. Many of these renewable resource polymers can also be rendered biodegradable under the appropriate conditions 1,13,14. However, except for polylactide, their high cost hampers their widespread use as bulk polymeric materials, relative to conventional petroleum-based plastics 15 . Recognizing that the raw material cost accounts for up to 50 % of the overall production cost of biodegradable polymers 12 , several research groups have directed investigative eorts towards the synthesis of new renewable monomers and the catalytic conversion of these monomers into their corresponding polymers, such as polyesters. Generally, aliphatic polyesters are obtained by either polycondensation or ring-opening polymerization of cyclic esters ( Fig. 1 ) 16. Th e latter route restricts the polymer architectures to those of the cyclic esters that are available 17. Although the nearly unlimited choice of diols and diacids gives access to a much larger range of polymer properties, their direct use in polycondensation reactions is energy intensive and requires drastic conditions to drive the reaction towards high conversion and very accurate comonomer stoichiometries to obtain high-molecular-weight products. In this overall context, organic acids have been suggested as important renewable building blocks because they are available in a minimum number of steps from biorenery carbohydrate streams 18 . Among them, dicarboxylic acids have received attention as platform chemicals and their potential as monomer precursors is a major challenge that deserves to be explored, even if their overall production cost still remains to be reduced in order to be competitive with petrochemical-derived chemicals 19.

Tandem catalysis is one of the strategies used by nature for building macromolecules 20 . Living organisms generally synthesize macromolecules by in vivo enzyme-catalyzed chain growth polymerization reactions using activated monomers that have been formed within cells during complex metabolic processes 21. For instance, aliphatic polyesters, such as polyhydroxyalkanoates, are synthesized from renewable, low-cost feedstocks (for example, sugars or fatty acids) under mild conditions. However, these biological processes rely on highly complex biocatalysts, such as polyhydroxyalkanoate synthases, thus limiting their industrial applications. In the same spirit, we have initiated a research eort to synthesize aliphatic

polyesters via an auto-tandem catalytic transformation, where activated monomers (that is, cyclic anhydrides) are synthesized from dicarboxylic acids and subsequently copolymerized with epoxides ( Fig. 1 ). Auto-tandem and assisted tandem catalyses, which make multiple use of a single (pre)catalyst, are more effi cient in catalyst utilization than orthogonal catalysis, which requires a dierent catalyst for each transformation 22 . Although orthogonal tandem catalysis has already been employed for polymer synthesis 23,24, there is no example to date in the literature in which a single metal complex is able to connect two independent catalytic cycles for the production of polymers 25.

Developing a tandem catalytic system is a diffi cult task, which requires an eective ligand framework for achieving high activity and control during the polymerization reaction and stabilization of the metal centre towards the solvent, substrate, and reaction side products and preventing decomposition of the active species 26. As pointed out by Jacobsen, salen catalysts (H 2 salen=N,N -bis(3,5-di- tert-butylsalicylidene)-1,2-cyclohexanediimine) can be regarded as privileged structures and as useful platforms for the discovery of new reactions 27. We hypothesized that commercially available metal complexes based on the specic tetradentate salen ligand would have the potential to act as auto-tandem catalysts given their unique robustness and versatility 28 , as well as the documented performance of their chromium counterparts for the synthesis of polycarbonates or polyesters 2934. Herein we introduce a practical route to biodegradable polyesters by way of an auto-tandem reaction using simple commercial catalysts. Th is process provides direct access to anhydrides and polymers in high yields.

ResultsCyclization step. The rst objective of our tandem approach is the synthesis of cyclic anhydrides from dicarboxylic acids. This cyclization is a known transformation, which can only be achieved upon dehydration of the starting compound under acidic conditions and at high temperatures. Accordingly there is a need for a process for the synthesis of cyclic anhydrides, which is fast and, which produces cyclic anhydrides in high yield. Recently Bartoli 35 reported effi cient protocols for the preparation of esters from the reaction of carboxylic acids with primary, aromatic and secondary alcohols in the presence of dialkyl dicarbonates under weak Lewis acid catalysis. The mechanism involved a double addition of the acid to the dicarbonate, aording a carboxylic anhydride and an alcohol. The nal esters arose

R3

HO OH

O

O

O

R2

R4

R4 ROP

Polycondensation

Polyester

HO

OH

O

O

Cyclic esters

n

R1 R2

R1

O

R3

O

R3

R4

O

O O

R1 R2

Figure 1 | Synthetic approaches to aliphatic polyesters. Aliphatic polyesters are obtained by either polycondensation of diols and diacids, ring-opening polymerization of cyclic esters or copolymerization of cyclic anhydrides with epoxides.

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from the attack of the alcohols on the anhydrides. Inspired by these previous ndings, we envisaged that salen-based catalysts might provide the basis for a multifunctional catalytic system that opens direct access to cyclic anhydrides with high selectivity and exibility starting from dicarboxylic acids ( Figs 2, 3 ).

The catalytic performances of the dierent salen complexes were evaluated in tetrahydrofuran (THF) in the presence of commercially available dialkyl dicarbonates. Representative results are summarized in Table 1 . We rst investigated the chromium(III) system 1 . However, the reaction of 100 equiv. of succinic acid with di- tert-butyl dicarbonate (Boc 2 O) in the presence of 1 at 40C was unsuccessful. When succinic acid and diethyl dicarbonate (Eoc 2O)

were allowed to react with complex 1 in THF at 40C (1mol%), succinic anhydride (SA) was obtained in 12 % yield in 50 h. Gratifyingly, in the presence of dimethyl dicarbonate (Moc 2 O), SA was detected in 100 % yield aer 10

h. As a control experiment the reaction was performed using a complex in the absence of dicarbonate or using a dicarbonate without a complex, and no reaction product could be isolated aer an even longer period of time. We also observed that the addition of cocatalyst [PPN]Cl ([PPN] + = bis(triphenylphosphoranylidene)iminium) increased the catalytic activity (entry 4). Th ese results indicate that the chromate

complexes derived from (salen)CrCl and onium salt should be the active species 36 . It has already been demonstrated that this type of Lewis basic cocatalyst reversibly coordinates to the metal centre, increases the electron density on the metal and labilizes the trans ligand to it 37.Th erefore a more electron-rich metal centre is more effi cient for this reaction, which is in accordance with Bartoli s observations that the reaction pathway is inuenced by the Lewis acidity and that weak Lewis acids are preferable for this reaction 35. Under the same reaction conditions we were also able to synthesize glutaric (GA), adipic (AA), itaconic (IA), pimelic (PA) and camphoric (CA) anhydrides (entries 5 9). However, for succinic, adipic, glutaric and pimelic acids, we observed that ester formation might occur from attack of alcohol to the anhydride. Th us the reaction had to be stopped before the formation of ester from the corresponding anhydride. For instance, in the presence of complex 1,pimelic anhydride was detected in 97 % yield a er 30 min at room temperature, together with the corresponding monoester (3 % ). Surprisingly in the case of camphoric ( Supplementary Figs S1 S4 ) and itaconic anhydrides no ester formation was detected (entries 8 9). Therefore, under these conditions, strict control of the reaction time was not necessary, as no alcoholysis of the anhydride was observed even aer a prolonged reaction time. To avoid alcoholysis of the anhydrides complex 2 was tested as a cyclization catalyst under the same reaction conditions and ester formation was also detected aer the reaction (entry 10). However, the reaction of 100 equiv. of pimelic acid with Boc 2 O (instead of Moc 2 O) in the presence of 2 at 50C was quantitative and showed no evidence of esterication by 1H

NMR spectroscopy, owing to the much lower nucleophility of tertiobutanol (entry 11). By using the other salen derivatives 34, we were also able to completely convert the camphoric acid into the correspondinganhydride(entries1314).Th us, the cyclization of dicarboxylic acids with commercially available dicarbonates can be carried out under mild conditions, is rapid in processing and suitable for the preparation of relevant monomers. Only volatile byproducts are removed between the anhydride formation step and the copolymerization step so that the resulting monomers are ready for polymerization without purication; thus, a wide range of aliphatic polyesters can be synthesized for dierent applications.

H H

M

tBu tBu

N N

O

But tBu

1: M = CrCl

2: M = AlCl

3: M = Co

4: M = MnCl

O

Figure 2 | Metal-based complexes used. Commercially available metal complexes based on the tetradentate salen ligand are useful platforms for the synthesis of aliphatic polyesters.

O O

O

O O

O

O

O

R2

R4

HO

OH

RO

O OR

O

R3

R4

O

O

2 ROH, 2 CO2

n

R1 R2

R1 R2

R1

O

R3

O

O O

IA

O

O

O O

O

O O

SA GA

O O

O O

O

O

O

O

AA

PA CA

O

O

PO

CHO

O

O

PiO

LO

Figure 3 | Tandem synthesis of polyesters from epoxides and dicarboxylic acids. Salen complexes are efcient catalysts for cyclization of dicarboxylic acids followed by alternating copolymerization of the resulting anhydrides with epoxides.

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Polymerization step. With an effi cient and quantitative synthesis of cyclic anhydrides in hand, we investigated the alternating copolymerization of a series of anhydrides and epoxides using complexes 14. Th e results are summarized in Table 2 . The copolymerizations were performed either in bulk (entries 1 8, 16 18) or in a toluene solution (entries 9 15). Neat conditions were optimal for reactions performed without toluene. Th e resultant polymers reveal narrow molecular-weight distributions and experimental number-average

molecular masses ( Mn ) close to the theoretical ones. However, in some cases, experimental Mn values do not correspond well with calculated Mn values. Th is mismatch possibly arises from the presence of trace amounts of hydrolyzed anhydride, as already reported by Coates and co-workers 34 . To evaluate the feasibility of the overall process, we conducted preliminary experiments with the chromium-based catalyst 1 , camphoric acid as a model substrate and 1500 equiv. of propylene oxide (PO) as an inexpensive comonomer 3840. The Cr(salen) complex was not an eective initiator without co-catalyst (entry 1). However, in the presence of 1 equiv. of PPNCl, this complex was found to be an active initiator for the copolymerization of PO and CA to aord poly(propylene camphorate) ( Supplementary Figs S5 S8 ) with high Mn and narrow molecular weight distribution (entry 2). In agreement with previous observations 4143, we considered that copolymerization takes place via a mechanism similar to the one reported for the alternating copolymerization of epoxide with CO 2.Th e formation of the anionic six coordinate species of the form trans-(salen)CrX2 occurs upon treating (salen)CrCl with PPNCl. Th e next step in the process involves binding and subsequent ring opening of the cyclic ether monomer. Th e role of the Lewis base cocatalyst is to labilize the metal-nucleophile bond of either the initiator or growing polymer chain towards heterolytic bond cleavage 36 . We then explored other anhydrides as comonomers and found that SA copolymerizes with PO (entry 3) ( Supplementary Figs S9 S12 ). In addition glutaric anhydride and pimelic anhydride react with PO to give polyesters with a moderate Mn (entries45)(Supplementary FigsS13S20).

Although the Mn(salen) complex 4 displayed poor reactivity (entry 8) 44, the screen did reveal the rather surprising result that the cobalt and aluminium analogues catalyzed the alternating copolymerization with similarly good reactivity (entries 6 7). Other epoxides, including cyclohexene oxide (CHO), limonene oxide (LO) and pinene oxide (PiO) are also viable monomers for copolymerization with CA ( Supplementary Figs S21 S28 ); in that case, higher temperature and a longer reaction time are required (entries 9 18). In the

Table 1 | Cyclization of dicarboxylic acids.

Entry Complex Anhydride [PPNCl]/[M]

Dicarbonate Time(h)

Yield (%)*

1 1 SA Boc2O 13 0

2 1 SA Eoc 2O 50 12

3 1 SA Moc2O 10 100

4 1 SA 1 Moc2O 8 100

5 1 GA 1 Moc2O 3 100

6 1 AA 1 Moc2O 6 95

7 1 PA 1 Moc2O 0.5 97

8 1 IA 1 Moc2O 7.5 100[p79]

9 1 CA 1 Moc2O 1 100 10 2 PA 1 Moc2O 0.5 97

11 2 PA 1 Boc2O 10 100 12 2 CA 1 Moc2O 1 100 13 3 CA 1 Moc2O 1 100 14 4 CA 1 Moc2O 1.5 100

Abbreviations: AA, adipic anhydride; CA, camphoric anhydride; GA, glutaric anhydride; IA, itaconic anhydride; PA, pimelic anhydride; SA, succinic anhydride .

All reactions performed in tetrahydrofuran with [anhydride]/[M]=100 at [anhydride]=1M and [dicarbonate]=[anhydride] at 40C.

*As determined by the integration of 1H NMR. 5% ester. Reaction performed at room temperature. 3% ester. [p79]18% isomer (that is, citraconic anhydride).

Reaction performed at 50C.

Table 2 | Tandem synthesis of aliphatic polyesters.

Entry Complex Anhydride Epoxide [PPNCl]/[M]

[A]/[E] Temperature (C)

Time (h) Yield (%)* Mn

PDI

(gmol1 )

1 1 CA PO 15 30 24 <5 ND ND 2 1 CA PO 1 15 30 24 100 16,900 1.2 3 1 SA PO 1 13.5 30 7.5 82 5,100 1.1 4 1 GA PO 1 13.5 30 6 70 3,700 1.1 5 1 PA PO 1.5 13.5 30 7.5 76 5,200 1.3 6 2 CA PO 1 15 30 20 68 9,500 1.2 7 3 CA PO 1 15 30 6.5 33 5,700 1.1 8 4 CA PO 1 15 30 20 17 4,300 1.1 9 1 CA CHO 2 1 70 36 26 8,500 1.2 10 3 CA CHO 2 1 70 36 48 6,300 1.6 11 2 CA CHO 2 1 70 36 59 8,900 1.3 12 3 CA LO 2 1 100 28 29 8,500 1.2 13 2 CA LO 2 1 100 28 85 9,700 1.2 14 2 CA LO 1 1 100 120 12 5,900 1.1 15 2 CA LO 5 1 100 24 74 10,300 1.3 16 2 CA LO 5 10 100 9 100 8,100 1.3 17 [p79] 2 GA PiO 5 5 100 2 29 8,400 1.2 18 2 CA LO 2 4 100 45 47 27,000 1.2

Abbreviations: CA, camphoric anhydride; GA, glutaric anhydride; PA, pimelic anhydride; SA, succinic anhydride; .

All reactions were performed after the cyclization step with [anhydride] / [M]=100 (except for entries 17 and 18).

*As determined by the integration of 1H NMR.Mn and PDI ( Mw/Mn) of the polymer determined by SEC-RI in tetrahydrofuran at room temperature using polystyrene standards.

Not determined. Reaction performed in toluene. [p79]Reaction performed with [anhydride]/[M]=200.

Reaction performed with [anhydride]/[M]=300.

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Table 3 | Alternating copolymerization of epoxides and isolated cyclic anhydrides.

Entry Complex Anhydride Epoxide [PPNCl]/[M]

[A]/[E] Temperature (C)

Time (h) Yield* (%) Mn (gmol1 )

PDI

1 1 SA PO 1 13.5 30 8.5 88 6300 1.1

2 1 GA PO 1 13.5 30 6.5 72 4400 1.6

Abbreviation: GA, glutaric anhydride.

All reactions performed with [anhydride]/[M]=100. *As determined by the integration of 1H NMR.Mn and PDI ( Mw/Mn) of the polymer determined by SEC-RI in tetrahydrofuran at room temperature using polystyrene standards.

presence of 2 equiv. of PPNCl in toluene, the Al(III) complex 2 and the Co(II) complex 3 were more eective catalysts than the chromium analogue 1 for the copolymerization of CHO and CA. This prompted us to investigate the catalytic behaviour of 2 and 3 for the copolymerization of CA and LO. Less reactive alicyclic epoxides, such as -PiO or LO, are particularly interesting substrates based on biorenewable resources. In particular the pendant functionality of LO provides an opportunity to tune the properties of the resulting polyester through postpolymerization modication of the pendant vinyl groups. In that case the aluminium derivative 2 was found to be much more active than the cobalt catalyst 3, as it converted 85 % monomers in 28 h versus 29 % in 28 h for 3 (entries 12, 13). Optimization of the molar ratio between aluminium complex and [PPN]Cl revealed that the highest activity was achieved when using more than 2 equiv. of [PPN]Cl (entries 13, 15 18). Other counteranions for [PPN] + , such as azide, acetate and peruorobenzoate, can be also employed without a signicant inuence on catalytic activity. Th is is in accordance with previous studies that demonstrated that the formation of the six coordinate anion trans-(salen)MX2 occurs more easily with at least 2 equiv. of PPNCl. 36 Notably, the combination based on aluminium complex 2and 5equiv. of PPNCl in bulk LO was also very reactive (entry 16). Finally it was interesting to observe that aluminium complex 2 is also active for the copolymerization of glutaric anhydride and PiO; neat conditions were optimal for this reaction. To the best of our knowledge, this is the rst copolymer synthesized from PiO (entry 17).

As control experiments, we performed polymerization reactions using a clean combination of isolated anhydrides with epoxides in the presence of the precatalyst ( Table 3 ). Interestingly, we observed that direct synthesis gives polymers with similar molecular weights and approximate rates as the tandem system ( Table 2 , entries 3 4). Th ese results suggest that the active species formed during the copolymerization process might be the same species in the overall tandem process (that is, trans-(salen)MX2 ).

Discussion

We have introduced a new class of tandem catalysts for the synthesis of biodegradable polyesters. Insight into the mechanism of individual catalytic cycles, and the resulting ability to control turnover frequencies need to be further developed in this context. The discovery of effi cient and selective tandem catalysts for the synthesis of renewable polymers is a crucial requirement for the sustained growth of the chemical industry. Increasingly important will also be the stereoselective catalysts that provide key enantiomerically pure monomers for the design and preparation of novel stereoregular macromolecules as promising advanced commodity materials in a sustainable development context. Th ese results suggest a number of new avenues for next generation renewable polymers.

Methods

Materials. (+)-Limonene oxide (mixture of cis and trans), propylene oxide , CHO and-PiO (all purchased from Aldrich ) were stirred over calcium hydride, put through three freeze-pump-thaw cycles, then vacuum transferred under argon (twice) and stored in a glovebox. (1 R,3S)-(+)-Camphoric acid, glutaric acid (purchased from Aldrich ), pimelic acid and succinic acid (purchased from

Janssen Chimica ) were recrystallized three times with THF / pentane or methylene chloride / diethyl ether, dried overnight under vacuum and then storedin the glovebox. Dimethyl dicarbonate , diethyl dicarbonate and di- tertio-butyl dicarbonate (purchased from Aldrich ) are degassed by freeze-thaw-vacuum cycles and stored in the freezer of the glovebox. (1 R,2R)-()-[1,2,-Cyclohexanediamino-N,N-bis(3,5-di-tertio-butylsalicylidene)]chromium(III) chloride, aluminium(III) chloride and manganese (III) chloride were purchased from Strem Chemicals and used as received in the glovebox. (1 R,2R)-()-[1,2,-Cyclohexanediamino-N,N-bis(3,5-di- tertio-butylsalicylidene)]cobalt(II) was purchased from Aldrich, and used as received in the glovebox. Bis(triphenylphosphoranylidene)ammonium chloride (purchased from Fluka ) was recrystallized twice with acetone / pentane or methylene chloride / pentane, dried overnight under vacuum and then stored in the freezer of the glovebox.

Tandem procedure. A Schlenk ask was charged with a solution of the catalyst (10mol), PPNCl (6mg, 10mol), dicarboxylic acid (1 mmol) and dimethyl dicarbonate (1mmol, 110l, 134 mg) in 1 ml of THF. Th e solution was stirred at 40 C. A er the allocated reaction time, the reaction was checked by 1H NMR spectroscopy, which indicated complete and selective conversion of the starting dicarboxylic acid. When the conversion is complete, volatiles are removed under vacuum overnight. Th e complex was directly engaged in polymerization a er the addition of a solution of epoxide in the appropriate ratio in toluene. Th e reaction was stirred at the desired temperature for the desired reaction time. A er a small sample of the crude material was removed for characterization, the reaction was quenched with acidic methanol (0.5 ml), and the polymer was precipitated with excess of pentane. Th e polymer was then dried in vacuo to constant weight.

Measurements . All manipulations requiring dry atmosphere were performed under a puried argon atmosphere using standard Schlenk techniques or in a glove-box. Solvents (toluene, pentane, THF) were freshly distilled from Na / K alloy under nitrogen and degassed thoroughly by freeze-thaw-vacuum cycles before use. Deuterated solvents ( benzene- d6, toluene-d8, THF- d8/99.5% D, Eurisotop) were freshly distilled from sodium / potassium amalgam under argon and degassed before use.

NMR spectra were recorded on Bruker Avance-300 , Avance-400 and Avance-600 spectrometers. 1H and 13C chemical shi s are reported in p.p.m. versus SiMe 4 and were determined by reference to the residual solvent peaks. Assignment of signals was made from multinuclear 1D ( 1H, 13C{1H}) and 2D (correlation spectroscopy, heteronuclear multiple quantum coherence, heteronuclear multiple bond correlation) NMR experiments. Gel permeation chromatography analyses were carried out using a Waters instrument GPCV 2000 , equipped with an ultraviolet and a viscometry detectors. Th e columns used are Styragel columns (two HT6E and one HT2) lled with 10 m styrene-divinyl benzene gel balls. Th e number average molecular masses ( Mn) and polydispersity index ( Mw/Mn) of the resultant polymers were calculated with reference to a polystyrene calibration. IR analyses were carried out using a FT / IR-4100 Jasco instrument , with a ATR PRO450-S, a TGR detector ,2 mm per sec scanning speed and a resolution of 16 cm 1.

References

1. Okada, M. Chemical syntheses of biodegradable polymers.Prog. Polym. Sci. 27, 87133 (2002).

2. Rass-Hansen, J., Falsig, H., Jorgensen, B. & Christensen, C. H. Bioethanol or feedstock?J. Chem. Technol. Biotechnol. 82, 329333 (2007).

3. Weisz, P. B. Basic choices and constraints on long-term energy supplies.Phys. Today 57, 4752 (2004).

4. Williams, C. K. & Hillmyer, M. A. Polymers from renewable resources: a perspective for a special issue of polymer reviews . Polymer Rev. 48, 110 (2008).

5. Zaldivar, J., Nielsen, J. & Olsson, L. Fuel ethanol production from lignocellulose: a challenge for metabolic engineering and process integration . Appl. Microbiol. Biotechnol. 56, 1734 (2001).

6. Poliako, M. & Licence, P. Green chemistry.Nature 450, 810812 (2007).7. Ragauskas, A. J. et al. Th e path forward for biofuels and biomaterials . Science 311, 484489 (2006).

8. Gner, F. S., Yagci, Y. & Erciyes, A. T. Polymers from triglyceride oils.Prog. Polym. Sci. 31, 633670 (2006).

5

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9. Jenck, J. F., Agterberg, F. & Droescher, M. J. Products and processes for a sustainable chemical industry: a review of achievements and prospects . Green Chem. 6, 544556 (2004).

10.Corma, A., Iborra, S. & Velty, A. Chemical routes for the transformation of biomass into chemicals . Chem. Rev. 107, 24112502 (2007).

11. Biermann, U. et al. New syntheses with oils and fats as renewable raw materials for the chemical industry . Angew. Chem. 39, 22062224 (2000).

12.Lucia, L. A., Argyropoulos, D. S., Adamopoulos, L. & Gaspar, A. R. Chemicals and energy from biomass . Can. J. Chem. 84, 960970 (2006).

13.Amass, W., Amass, A. & Tighe, B. A review of biodegradable polymers: uses, current developments in the synthesis and characterization of biodegradable polyesters, blends of biodegradable polymers and recent advances in biodegradation studies.Polym. Int. 47, 89144 (1998).

14.Chiellini, E. & Solaro, R. Biodegradable polymeric materials.Adv. Mater. 8, 305313 (1996).

15.Platel, R. H., Hodgson, L. M. & Williams, C. K. Biocompatible initiators for lactide polymerization.Polym. Rev. 48, 1163 (2008).

16. Th omas, C. M. Stereocontrolled ring-opening polymerization of cyclic esters: synthesis of new polyester microstructures . Chem. Soc. Rev. 39, 165173 (2010).

17. Kramer, J. W. et al. Polymerization of enantiopure monomers using syndiospecic catalysts: a new approach to sequence control in polymer synthesis.J. Am. Chem. Soc. 131, 1604216044 (2009).

18. Sauer, M., Porro, D., Mattanovich, D. & Branduardi, P. Microbial production of organic acids: expanding the markets . Trends Biotechnol. 26, 100108 (2008).

19.Bechthold, I., Bretz, K., Kabasci, S., Kopitzky, R. & Springer, A. Succinic acid: a new platform chemical for biobased polymers from renewable resources . Chem. Eng. Technol. 31, 647654 (2008).

20.Lutz, J.- F. A controlled sequence of events.Nat. Chem. 2, 8485 (2010).21.Gross, R. A., Ganesh, M. & Lu, W. Enzyme-catalysis breathes new life into polyester condensation polymerizations . Trends Biotechnol. 28, 435443 (2010).

22.Jones, S. B., Simmons, B., Mastracchio, A. & MacMillan, D. W. C. Collective synthesis of natural products by means of organocascade catalysis . Nature 475, 183188 (2011).

23.Komon, Z. J. A. & Bazan, G. C. Synthesis of branched polyethylene by tandem catalysis.Macromol. Rapid Commun. 22, 467478 (2001).

24.Dunn, E. W. & Coates, G. W. Carbonylative polymerization of propylene oxide: a multicatalytic approach to the synthesis of poly(3-hydroxybutyrate) . J. Am. Chem. Soc. 132, 1141211413 (2010).

25.Wasilke, J.- C., Obrey, S. J., Baker, R. T. & Bazan, G. C. Concurrent tandem catalysis.Chem. Rev. 105, 10011020 (2005).

26. Goldman, A. S. et al. Catalytic alkane metathesis by tandem alkane dehydrogenation-olen metathesis.Science 312, 257261 (2006).

27.Yoon, T. P. & Jacobsen, E. N. Privileged chiral catalysts.Science 299, 16911693 (2003).

28.Tokunaga, M., Larrow, J. F., Kakiuchi, F. & Jacobsen, E. N.Asymmetric catalysis with water: effi cient kinetic resolution of terminal epoxides by means of catalytic hydrolysis.Science 277, 936938 (1997).

29. Brul, E., Guo, J., Coates, G. W. & Th omas, C. M. Metal-catalyzed synthesis of alternating copolymers.Macromol. Rapid Commun. 32, 169185 (2011).

30.DiCiccio, A. M. & Coates, G. W. Ring-opening copolymerization of maleic anhydride with epoxides: a chain-growth approach to unsaturated polyesters . J. Am. Chem. Soc. 133, 1072410727 (2011).31. Huijser, S. et al. Ring-opening co- and terpolymerization of an alicyclic oxirane with carboxylic acid anhydrides and CO 2 in the presence of chromium porphyrinato and salen catalysts . Macromolecules 44, 11321139(2011).

32.Aida, T. & Inoue, S. Catalytic reaction on both sides of a metalloporphyrin plane. Alternating copolymerization of phthalic anhydride and epoxypropane

with an aluminum porphyrin-quaternary salt system . J. Am. Chem. Soc. 107, 13581364 (1985).33. Maeda, Y. et al. Ring-opening copolymerization of succinic anhydride with ethylene oxide initiated by magnesium diethoxide . Polymer 38, 47194725 (1997).

34.Jeske, R. C., DiCiccio, A. M. & Coates, G. W. Alternating copolymerization of epoxides and cyclic anhydrides: an improved route to aliphatic polyesters . J. Am. Chem. Soc. 129, 1133011331 (2007).35. Bartoli, G. et al. Reaction of dicarbonates with carboxylic acids catalyzed by weak Lewis acids: general method for the synthesis of anhydrides and esters . Synthesis 22, 34893496 (2007).

36.Darensbourg, D. J., Mackiewicz, R. M., Phelps, A. L. & Billodeaux, D. R. Copolymerization of CO 2 and epoxides catalyzed by metal salen complexes .

Acc. Chem. Res. 37, 836844 (2004).37.Cohen, C. T. & Coates, G. W. Alternating copolymerization of propylene oxide and carbon dioxide with highly effi cient and selective (salen)Co(III) catalysts: eect of ligand and cocatalyst variation . J. Polym. Sci. Part A: Polym. Chem. 44, 51825191 (2006).

38.Lee, B. Y. & Cyriac, A. Polymer synthesis: making the gradient.Nat. Chem. 3, 505507 (2011).

39. Aparicio, S. & Alcalde, R. Th e green solvent ethyl lactate: an experimental and theoretical characterization.Green Chem. 11, 6578 (2009).

40. Yu, Z. et al. A new route for the synthesis of propylene oxide from bio-glycerol derivated propylene glycol.Chem. Commun.39343936 (2009).

41. Lu, X. B. et al. Design of highly active binary catalyst systems for CO 2/epoxide copolymerization: polymer selectivity, enantioselectivity, and stereochemistry control.J. Am. Chem. Soc. 128, 16641674 (2006).

42.Cohen, C. T., Chu, T. & Coates, G. W. Cobalt catalysts for the alternating copolymerization of propylene oxide and carbon dioxide: combining high activity and selectivity.J. Am. Chem. Soc. 127, 1086910878 (2005).

43.Nakano, K., Tatsumi, G. & Nozaki, K. Synthesis of sulfur-rich polymers: copolymerization of episulde with carbon disulde by using PPNCl/ (salph)Cr(III)Cl System.J. Am. Chem. Soc. 129, 1511615117 (2007).

44.Jacobsen, E. N. Asymmetric catalysis of epoxide ring-opening reactions.Acc. Chem. Res. 33, 421431 (2000).

Acknowledgements

We thank Dr R. Gauvin, Dr M. Tschan and Dr T. Malherbe for critical discussions and reading of the manuscript. We are grateful to CNRS, ENSCP and R gion le-de-France for nancial support.

Author contributions

C.M.T. designed the experiments, analysed the data and wrote the paper. C.R. performed the experiments. C.R. and F.M. analysed the data. All authors discussed the results and commented on the manuscript.

Additional information

Supplementary Information accompanies this paper at http://www.nature.com/ naturecommunications

Competing nancial interests: Th e authors declare no competing nancial interests.

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How to cite this article: Robert, C. et al. Tandem synthesis of alternating polyesters from renewable resources. Nat. Commun. 2:586 doi: 10.1038 / ncomms1596 (2011).

License: Th is work is licensed under a Creative Commons Attribution-NonCommercial-Share Alike 3.0 Unported License. To view a copy of this license, visit http:// creativecommons.org/licenses/by-nc-sa/3.0/

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