JoVE Journal > Chemistry
Summary
Abstract
Introduction
Protocol
Results
Discussion
Disclosures
Acknowledgements
Materials
References
화학

Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers

Published: December 16, 2022
doi:
10.3791/64182
, , ,
1School of Polymer Science and Polymer Engineering,University of Akron

Summary

Here, we describe protocols for the preparation of trans-cyclobutane fused cyclooctenes (tCBCO), their polymerization to prepare depolymerizable olefinic polymers, and the depolymerization of these polymers under mild conditions. Additionally, protocols for the preparation of depolymerizable networks and compression molding of rigid linear plastics based on this system are described.

Abstract

The growing consumption of synthetic polymers and the accumulation of polymer waste have led to a pressing need for new routes to sustainable materials. Achieving a closed-loop polymer economy via chemical recycling to monomer (CRM) is one such promising route. Our group recently reported a new CRM system based on polymers prepared by ring-opening metathesis polymerization (ROMP) of trans-cyclobutane fused cyclooctene (tCBCO) monomers. This system offers several key advantages, including the ease of polymerization at ambient temperatures, quantitative depolymerization to monomers under mild conditions, and a broad range of functionalities and thermomechanical properties. Here, we outline detailed protocols for the preparation of tCBCO-based monomers and their corresponding polymers, including the preparation of elastic polymer networks and compression molding of linear thermoplastic polymers. We also outline the preparation of high ring strain E-alkene tCBCO monomers and their living polymerization. Finally, the procedures for the depolymerization of linear polymers and polymer networks are also demonstrated.

Introduction

The versatile and robust nature of synthetic polymers has made them a ubiquitous fixture of modern human existence. On the flip side, the same robust and environmentally resistant properties make polymer waste exceedingly persistent. This, together with the fact that a large fraction of all synthetic polymers ever made has ended up in landfills1, has raised legitimate concerns about their environmental effects2. Additionally, the open-loop nature of the traditional polymer economy has caused a steady consumption of petrochemical resources and a mounting carbon footprint3. Promising routes to a closed-loop polymer economy are, thus, highly sought after.

Chemical recycling to monomer (CRM) is one such route. The advantage of CRM over traditional recycling is that it leads to the regeneration of monomers that can be used to manufacture pristine polymers, as opposed to mechanical recycling of materials with deteriorating properties over multiple processing cycles. Polymers based on ring-opening polymerizations have appeared as especially attractive routes to CRM materials4. The thermodynamics of polymerization is typically an interplay between two opposing factors: the enthalpy of polymerization (ΔHp, which is typically negative and favors polymerization) and the entropy of polymerization (ΔSp, which is also typically negative but disfavors polymerization), with the ceiling temperature (Tc) being the temperature at which these two factors balance each other out5. For a polymer to be capable of CRM under practical and economically beneficial conditions, the right balance of ΔHp and ΔSp must be achieved. Cyclic monomers allow a convenient means to tune these factors via the selection of the appropriate ring size and geometry, since here, ΔHp is primarily determined by the ring strain of the cyclic monomers4,5. As a result, CRM polymers with a wide variety of monomers have been reported of late6,7,8,9,10,11. Out of these systems, ROMP polymers prepared from cyclopentenes are particularly promising due to the rather cheap starting material required and the hydrolytic and thermal stability of the polymers. Additionally, in the absence of a metathesis catalyst, the depolymerization is kinetically unfeasible, affording high thermal stability despite a low Tc12. However, cyclopentenes (and other monomers based on small cyclic structures) pose a key challenge-they cannot be readily functionalized, as the presence of functional groups on the backbone can affect the thermodynamics of polymerization in drastic, and sometimes unpredictable, ways13,14.

Recently, we reported a system that overcomes some of these challenges15. Inspired by examples of low-strain fused ring cyclooctenes in the literature16,17, a new CRM system was designed based on ROMP polymers of trans-cyclobutane fused cyclooctenes (tCBCO) (Figure 1A). The tCBCO monomers could be prepared at a gram scale from the [2+2] photo cycloadduct of maleic anhydride and 1,5-cyclooctadiene, which could be readily functionalized to achieve a diverse set of substituents (Figure 1B). The resulting monomers had ring strains comparable to cyclopentene (~5 kcal·mol−1, as calculated using DFT). Thermodynamic studies revealed a low ΔHp (−1.7 kcal·mol−1 to −2.8 kcal·mol−1), which was offset by a low ΔSp (−3.6 kcal·mol−1·K−1 to −4.9 kcal·mol−1·K−1), allowing the preparation of high molecular weight polymers (at high monomer concentrations) and near quantitative depolymerization (>90%, under dilute conditions) at ambient temperatures in the presence of Grubbs II catalyst (G2). It was also demonstrated that materials with diverse thermomechanical properties could be obtained while preserving the ease of polymerization/depolymerization. This ability was further exploited to prepare a soft elastomeric network (which could also be readily depolymerized), as well as a rigid thermoplastic (with tensile properties comparable to polystyrene).

One drawback with this system was the need for high monomer concentrations to access high molecular weight polymers. At the same time, due to extensive chain transfer and cyclization reactions, the polymerization was uncontrolled in nature. This was addressed in a subsequent work via photochemical isomerization of the Z-alkene in the tCBCO monomers to prepare highly strained E-alkene tCBCO monomers18. These monomers could be rapidly polymerized in a living manner at low initial monomer concentrations (≥25 mM) in the presence of Grubbs I catalyst (G1) and excess triphenylphosphine (PPh3). The polymers could then be depolymerized to yield the Z-alkene form of the monomers. This has created opportunities to access new depolymerizable polymer architectures, including block copolymers and graft/bottlebrush copolymers.

In this work, detailed protocols are outlined for the synthesis of tCBCO monomers with different functional groups and their polymerization, as well as the depolymerization of the resulting polymers. Additionally, protocols for the preparation of dogbone samples of a soft elastomeric network and their depolymerization, as well as compression molding of the N-phenylimide substituted rigid thermoplastic polymer, are also described. Finally, protocols for the photoisomerization of a tCBCO monomer to its strained E-alkene tCBCO form and its subsequent living ROMP are also discussed.

Protocol

NOTE: The protocols outlined below are detailed forms of experimental procedures reported previously15,18,19. Characterization of the small molecules and polymers has been reported previously15,18. Additionally, syntheses of monomers and polymers and depolymerization of polymers should be performed inside a fume hood with appropriate personal protective equipment (PPE), including nitrile gloves, safety glasses, and a lab coat.

1. tCBCO monomer preparation15

  1. [2+2] photoaddition
    1. To a quartz tube, add maleic anhydride (5.4 g, 55.1 mmol, 1 equiv.), cyclooctadiene (7.42 mL, 6.55 g, 61 mmol, 1.1 equiv.), and 150 mL of dry acetone.
    2. Seal the quartz flask with a rubber septum and insert a 6-in needle connected to the N2 on a Schlenk line, and a smaller bleed needle. Stir the solution on a magnetic stir plate while bubbling with N2 for ~30 min. Remove the needles following this.
    3. Equip the photoreactor with 300 nm lamps, and place the flask in it, clamped to a vertical support. Make sure to loosely cover the top of the photoreactor to shield the outside from UV radiation and turn on the cooling fan and UV lamps.
    4. After irradiating overnight, concentrate the mixture on a rotavap until most of the solvent is removed (heating bath of the rotavap set at ~40 °C, a vacuum of ~400-500 mbar). Some insoluble by-products may also be found attached to the wall of the quartz tube.
    5. Use the crude compound 1 obtained after solvent removal for the next step without further purification.
  2. Methyl ester-acid 2
    1. Suspend the crude compound 1 in 150 mL of methanol in a single neck round-bottom flask equipped with a condenser.
    2. Reflux the mixture in an oil bath over a stirring hotplate for 5 h and then allow it to cool down to room temperature (RT).
    3. Filter the resulting suspension and concentrate the filtrate on a rotavap (heating bath at ~45 °C, vacuum <300 mbar). During the reflux, the reaction suspension gradually becomes a homogeneous clear system with a chunk of insoluble side products.
    4. Purify the crude compound 2 through column chromatography using 3:7 ethyl acetate/hexane as the eluent (a general procedure for column chromatography is provided in section 2).
    5. Further, purify product 2 by recrystallization (recrystallization is performed using established techniques20) from a saturated solution in ethyl acetate (EA)/hexanes (~30% v/v EA) to remove isomers from the photoreaction, yielding the methyl ester-acid 2 as a crystalline white powder (overall yield: 1.7 g, ~12.9%).
  3. Dimethyl ester monomer M1
    1. To a 50 mL round-bottom flask equipped, with a stir bar, add methyl ester-acid 2 (600 mg, 2.52 mmol, 1 equiv.), 4-dimethylaminopyridine DMAP (61 mg, 0.5 mmol, 0.2 equiv.), methanol (0.2 mL, 0.161 mg, 5.04 mmol, 2 equiv.), and dry dichloromethane DCM (25 mL).
    2. Place the flask in an ice bath and add 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide hydrochloride (EDC∙HCl; 966 mg, 5.04 mmol, 2 equiv.) into the solution.
    3. Allow the mixture to warm to RT and stir on a magnetic stir plate overnight.
    4. Dilute the mixture with dichloromethane (DCM), add to a 250 mL separatory funnel together with brine (about 1/2 the volume of the DCM solution), and agitate the mixture; collect the organic phase (this brine wash helps remove aqueous impurities and water in the organic phase).
    5. Dry over sodium sulfate (Na2SO4): Place the solution in a conical flask and add Na2SO4 in portions while swirling the flask; repeat this until any Na2SO4 added further does not clump together.
    6. Filter this solution via gravity filtration through a filter paper (grade 2, pore size ~8 µm) placed in a funnel. Concentrate the solution on a rotavap with the heating bath at 40 °C and under a vacuum of ~650-700 mbar (decrease the vacuum as the solution concentrates and solvent evaporation slows down but ensure that the solution does not boil aggressively to avoid splashing and contamination of the rotavap fixtures).
    7. Purify the crude product via column chromatography, using a 1:4 EA/hexanes mixture as eluent, and concentrate on a rotavap (heating bath at 40 °C, 240-300 mbar vacuum) to obtain compound M1 as a white solid (509 mg, yield: 80%).
  4. Diacid 4
    1. To a 50 mL round-bottom flask equipped with a stir bar, add a solution of sodium hydroxide (NaOH) (1.68 g, 42 mmol, 16.7 equiv.) in water (20 mL) followed by 600 mg of methyl ester-acid 2 (600 mg, 2.52 mmol, 1 equiv.).
    2. Stir the reaction mixture at 60 °C for ~14 h.
    3. Once the reaction is complete, cool to RT and place the flask in an ice bath; add 3 M HCl until the solution is neutralized (as verified using a strip of pH paper).
    4. Extract the mixture with ~150 mL of EA (x5) in a separatory funnel and dry the organic layer over Na2SO4 (for the drying procedure, see the synthesis of M1).
    5. Remove the Na2SO4 by gravity filtration, and wash the residue trapped in the funnel with additional EA (x3).
    6. Concentrate on a rotavap (heating bath at ~40 °C, ~150-200 mbar vacuum, decreasing the vacuum to ensure a steady rate of solvent evaporation) to yield the diacid 3 as a white solid (yield: 470 mg, ~83.2%)
  5. Dibutyl ester monomer 5
    1. To a 50 mL round-bottom flask equipped with a stir bar, add diacid 4 (941 mg, 4.20 mmol, 1 equiv.), 4-dimethylaminopyridine (DMAP; 205.5 mg, 1.68 mmol, 0.4 equiv.), n-butanol (0.845.7 mL, 684.9 mg, 9.24 mmol, 2.2 equiv.), and dry DCM (60 mL).
    2. Cool the flask in an ice bath and add EDC∙HCl (3220.06 mg, 16.8 mmol, 4.0 equiv.) into the solution.
    3. Allow the mixture to warm to RT and stir overnight (~12 h) for the completion of the reaction.
    4. Dilute the mixture with ~120 mL of DCM, and wash with ~200 mL of brine in a 500 mL separatory funnel (to perform a brine wash, see the procedure for the synthesis of M1).
    5. Dry over Na2SO4, filter (to dry and filter the solution, see the procedure for the synthesis of M1), and concentrate on a rotavap (heating bath at ~40 °C and a vacuum of ~600-700 mbar).
    6. Purify the crude product mixture via column chromatography, using a 1:9 EA/hexanes mixture as eluent.
    7. Remove the solvent on a rotavap (heating bath at ~40 °C, ~240-300 mbar vacuum) to obtain the product M2 as a clear, colorless oil (yield: 540 mg, 38.3%).
  6. Anhydride 1
    1. To a 50 mL round-bottom flask equipped with a stir bar, add the diacid 3 (2.00 g, 8.92 mmol, 1 equiv.) and 20 mL of acetic anhydride.
    2. Heat the suspension to reflux (~140 °C) and keep it at that temperature overnight (around 14 h).
    3. To remove acetic anhydride, perform vacuum distillation.
      1. To the flask with the reaction mixture, attach a short path distillation apparatus with a receiving flask, and connect it to the vacuum (with the vacuum line closed initially). Place the reaction flask in an oil bath and turn on the vacuum (a vacuum below 1,000 mTorr is preferable).
      2. Collect any vapors that come over at RT, increasing the temperature gradually ~10 °C at a time (the upper limit will depend on the strength of the vacuum) until the reaction mixture is dry.
    4. Use the anhydride 1 for the next step directly without further purification.
  7. Imide monomer M3
    1. Dissolve the anhydride 1 (1.84 g, 8.92 mmol, 1.0 equiv.) in acetone (8 mL), and add aniline (1.63 mL, 17.84 mmol, 2.0 equiv.) dropwise.
    2. Allow the reaction to proceed for about 3 h followed by suction filtration. To perform suction filtration, place a Büchner funnel on an Erlenmeyer flask with a barb and connect it to the vacuum. Turn on the vacuum and filter the reaction mixture as usual.
    3. Wash the solid with a small amount of acetone and dry in a vacuum to obtain the amic acid as a white solid (yield: 2.5 g, 72%).
    4. Add the amic acid along with sodium acetate (1.10 g, 13.38 mmol, 1.5 equiv.) to a 50 mL round-bottom flask, followed by 15 mL of acetic anhydride.
    5. Stir the resulting suspension at 100 °C overnight (it will gradually become clear).
    6. Pour the mixture into 100 mL of cold water and allow to stir for 30 min.
    7. Perform suction filtration and wash the white residue with 50 mL of water 3x, then redissolve it in 100 mL of DCM and dry over Na2SO4 (to dry and filter the solution, see the procedure for the synthesis of M1).
    8. After filtration and removal of the solvent using a rotavap (heating bath at ~40 °C and a vacuum of ~600-700 mbar), purify the crude product via column chromatography using DCM as eluent and further purify via recrystallization20 from toluene solution to yield imide monomer M3 as white crystals (yield: 1.2 g, ~47.6%).
  8. Crosslinker XL
    1. To a round-bottom flask equipped with a stir bar, add ester-acid 2 (624.0 mg, 2.62 mmol, 1.0 equiv.), DMAP (64.1 mg, 0.5 mmol, 0.2 equiv.), 1,4-butanediol (111.8 mg, 1.24 mmol, 0.47 equiv.), and dry DCM (50 mL).
    2. Place the flask in an ice bath and add EDC∙HCl (1000.0 mg, 5.22 mmol, 2.0 equiv.) into the solution.
    3. Allow the mixture to warm to RT and stir overnight.
    4. Dilute the mixture with ~100 mL of DCM, and wash with ~150 mL of brine in a separatory funnel (to perform a brine wash, look at the procedure for the synthesis of M1).
    5. Dry over Na2SO4, filter (to dry and filter the solution, see the procedure for the synthesis of M1), and concentrate on a rotavap.
    6. Purify the crude product mixture via column chromatography, using a 3:7 EA/hexanes mixture as eluent.
    7. Remove the solvent on a rotavap and using a high vacuum (heating bath at ~40 °C, ~240-300 mbar vacuum) to obtain the crosslinker XL as a white solid (yield: 239 mg, ~32.0 %).

2. Column chromatography

NOTE: The following is a general procedure for column chromatography as performed for the compounds described herein.

  1. Prepare the crude product for loading: Dissolve the crude product in a small amount of eluent, add ~2x-3x the weight of the crude product in silica, and rotavap to remove solvent until the mixture forms a free-flowing powder.
  2. Clamp a glass column containing a 24/40 ground glass joint on the top vertically and add a cotton plug to it to prevent the silica from leaking.
  3. Weigh out ~40x-60x the weight of the crude product in silica, prepare a slurry in the eluent, and pour this into the glass column.
  4. Drain the column until the solvent reaches the top of the silica and gently tap the column to pack the silica.
  5. Load the crude product mixture from step 2.1 into the column using a funnel and add the eluent into the column.
  6. Collect the fractions in 20 mL test tubes and monitor with thin layer chromatography (TLC) to identify fractions containing pure isolated products21.
    ​NOTE: The column size is determined by the amount of silica being used. For silica loading of ~40-100 g, a column with a 28 mm diameter is used. For larger loadings, a 40 mm diameter column is used.

3. Photochemical Isomerization18

NOTE: The photoisomerization was adapted from a literature procedure22.

  1. To a circulation column, add cotton and silver nitrate (AgNO3)-impregnated silica gel22 (2.84 g of AgNO3, 16.72 mmol, 2 equiv.). Fill the rest of the column with untreated silica gel to prevent the AgNO3 from leaking, followed by adding another piece of cotton.
  2. Wrap the column with aluminum foil and connect with tubing on either end. Connect one end of the column to a metering pump for circulation, with another piece of tubing coming out of the metering pump.
  3. Put either end of the tubing into a flask with 200 mL of 2:3 v/v Et2O/hexane and circulate for 2 h to pack the column tight and check any possible leaking.
  4. Meanwhile, dissolve M1 (2.81 g, 8.36 mmol, 1 equiv.) and methyl benzoate (2.27 g, 16.72 mmol, 2 equiv.) in a 2:3 v/v diethyl ether (Et2O)/hexane solvent mixture in a quartz tube. Equip the photoreaction chamber with 254 nm wavelength lamps.
  5. After confirming that the column is not leaking, replace the flask with the quartz tube, place it in the photoreaction chamber, and continue circulation (flow rate of ~10 mL/min) with the quartz tube under irradiation for 16 h. The reaction setup at this stage is shown in Figure 3.
    NOTE: The circulation column should be oriented such that the reaction mixture flows first through the AgNO3-impregnated silica gel, followed by the untreated silica gel sequentially.
  6. Pull the tubing up above the solution level after turning off the photoreactor and circulate for an additional 1 h to dry the column. Meanwhile, pack another column with a silica gel layer at the bottom and the AgNO3-impregnated silica gel (2.84 g) at the top.
  7. Empty the circulation column and load its contents to the silica column packed in step 3.6. Collect and concentrate the solution from the quartz tube; also add this to the silica column packed in step 3.6.
  8. Wash the column with 2:3 v/v Et2O/hexane (5x the volume of the stationary phase) to collect methyl benzoate and M1, followed by washing with acetone (5x the volume of the stationary phase) to collect EM1 silver ion complex.
  9. After acetone is removed on a rotavap, add a mixture of 200 mL of DCM and 200 mL of concentrated aqueous ammonia to the residue and stir for 15 min.
  10. Collect the organic phase, wash it with water and brine solution in a separatory funnel. Dry the organic phase over Na2SO4, filter, and concentrate the filtrate.
  11. Purify the crude mixture via column chromatography using a 2:3 Et2O/hexane mixture as the eluent. Remove the solvent on a rotavap and dry under a high vacuum while placed in a liquid nitrogen bath to obtain pure EM1 as a white solid (yield: 0.93 g, ~33%).NOTE: The liquid nitrogen bath is used here to freeze-dry the monomer. A dry ice/acetone bath may also be used for this purpose; the use of cryoprotective gloves is advised.

4. Polymer synthesis

  1. Synthesis of linear polymers by conventional ROMP15
    NOTE: Polymers were synthesized through ring-opening metathesis polymerization (ROMP) of corresponding monomers via an identical procedure. The procedure is described below using P1 as an example.
    1. Dissolve dimethyl ester monomer M1 (459 mg, 1.82 mmol, 1 equiv.) in DCM (400 µL) in a 3-dram vial equipped with a stir bar.
    2. To the monomer solution, add 59 µL of a Grubbs II catalyst (G2) stock solution (concentration: 52.37 mg/mL, amount of G2: 3.09 mg, 0.00364 mmol, 0.002 equiv.) in DCM.
    3. Allow the mixture to stir for 6 h at RT and quench by adding ethyl vinyl ether (300 µL) and stirring for another 30 min.
    4. Dilute the mixture with 5 mL of DCM and add the catalyst scavenger (see the Table of Materials for details) particles (350 mg).
    5. After stirring overnight, filter the suspension through a Celite plug and concentrate on a rotavap (water bath at ~40 °C, 600-700 mbar vacuum).
    6. After precipitating twice in cold methanol and drying in a vacuum, obtain isolated polymer P1 as a white solid.
  2. Synthesis of linear polymers by living ROMP18
    NOTE: Polymerization is conducted in an N2-filled glovebox. Stock solutions of EM1, PPh3 (triphenylphosphine), and G1 in THF (tetrahydrofuran) are prepared in the glovebox. All vials and stir bars should be dried in an oven overnight before polymerization. Also, ensure that the working surfaces are free of G1 since even small amounts of the catalyst may lead to unintended initiation of polymerization.
    1. Prepare stock solutions for EM1, PPh3, and G1 in THF, respectively.
    2. To a vial with a stir bar, add EM1 (517 mg, 1.19 mmol, 1.0 equiv.) and PPh3 (60.5 mg, 0.18 mmol, 0.15 equiv.) from their stock solutions, respectively.
    3. Add additional THF such that the monomer concentration is 0.25 M.
    4. Add G1 (3.16 mg, 2.97 µmol, 0.0025 equiv.), and allow the mixture to stir for 10 min.
    5. Add ethyl vinyl ether (1 mL) to quench the polymerization and stir the mixture for an additional 30 min. Precipitate the polymer thrice in methanol and dry on a vacuum line overnight.
  3. Synthesis of polymer network PN115
    1. Add tCBCO monomer M2 (660 mg, 1.8 mmol, 1 equiv.) and crosslinker XL (106.2 mg, 0.2 mmol, 0.11 equiv.) to a 4-dram glass vial. Add DCM (500 µL) to this and dissolve using a vortex mixer.
    2. Add G2 (3.4 mg, 0.004 mmol, 0.0022 equiv.) to this and agitate manually to ensure dissolution.
    3. Using a glass pipette, add the solution to a polytetrafluoroethylene (PTFE) mold with six cavities (overall cavity dimensions: length 25 mm, width 8.35 mm, and depth 0.8 mm; gauge dimensions: length 5 mm, width 2 mm) (Figure 4B). Allow the network to cure at RT (24 h) and at −6 °C for 24 h.
    4. Carefully remove the sample from the mold (a spatula may be used to pry a corner of the sample out of the cavity, and a pair of tweezers may be used to remove it). Submerge the sample in a 20 mL vial with ~5 mL of ethyl vinyl ether for 4 h.
    5. Place the prepared sample in a cellulose thimble and place it in a Soxhlet extraction apparatus.
    6. Affix the Soxhlet extractor onto a 500 mL round-bottom flask with 250 mL of CHCl3 (chloroform) and place it in an oil bath. Attach a condenser to the top of the Soxhlet extractor.
    7. Cover the arm of the extractor directing the flow of vapors from the flask to the condenser with aluminum foil for insulation. Allow the solvent to reflux for 14 h
    8. Remove the sample from the thimble, place it on a piece of paper towel placed on a clean surface, cover (a small box with a lid may be used for this purpose), and allow the solvent to evaporate under ambient conditions for ~6 h.
      NOTE: Covering the sample is important to ensure gradual evaporation and prevent cracking of the sample as it dries.
    9. Place the sample in a 20 mL vial and place it under a vacuum to dry completely, weighing periodically until no weight loss is detectable.

5. Depolymerization

  1. Depolymerization of linear polymer (P1)19
    NOTE: Below is the general procedure for the depolymerization of linear tCBCO-based polymers.
    1. Place the polymer P1 (30 mg, 0.119 mmol., 1 equiv.) in a 3-dram glass vial and dissolve it in 4706 µL of CDCl3 (deuterated chloroform).
    2. Weigh G2 (3 mg, 0.0035 mmol., 0.0297 equiv.) in a 1-dram glass vial and add 148.6 µL of CDCl3 to dissolve it.
    3. Using a micropipette, add 50 µL of the solution of G2 to the solution of P1. The total concentration of olefinic groups must be 25 mM. Split the vial's contents into three different vials, corresponding to three replicates.
    4. Place the vials in a water bath at 30 °C for ~16 h. Then, add 50 µL of ethyl vinyl ether to this to quench G2
      NOTE: The extent of depolymerization may be obtained using 1H NMR spectroscopy from the ratio of the integration of the monomer olefin signal (5.5-5.8 ppm) to the sum of monomer and polymer/oligomer olefin signals (5.2-5.3 ppm).
  2. Depolymerization of the polymer network (PN1)15
    1. Calculate the olefinic groups per gram of polymer network. In the below example, the material consists of 90 mol% butyl ester monomer M2 (M.W. = 366.47 g/mol) and 10 mol% crosslinker XL (M.W. = 530.65 g/mol). This results in PN1 with 382.9 g/mol of olefin groups (or 2.61 mmol olefin groups per gram of PN1).
    2. Place the polymer network PN1 (17.7 mg, 0.046 mmol, 1 equiv.) in a 1-dram glass vial and add 1.8 mL of CDCl3 to it.
    3. Weigh G2 (5 mg) in a 1-dram glass vial and add 256.1 µL of CDCl3 to dissolve it.
    4. Add 40 µL of the solution of G2 (corresponding to 0.92 µmol or 2 mol% of G2) to the vial with PN1 submerged in CDCl3. The total concentration of olefinic groups must be 25 mM.
    5. Place the vial with PN1 and G2 in a water bath at 50 °C for ~2 h. Then, add 100 µL of ethyl vinyl ether to this mixture to quench G2.
      ​NOTE: The extent of depolymerization may be obtained using 1H NMR spectroscopy from the ratio of the integration of the monomer olefin signal (5.5-5.8 ppm) to the sum of monomer and polymer/oligomer olefin signals (5.2-5.3 ppm).

6. Preparation of tensile testing specimens for P315

  1. Dissolve P3 (1 g) in dichloromethane (3 mL) with butylated hydroxytoluene (BHT) (500 ppm with respect to the polymer) added to it.
  2. Place the solution on a Petri dish lined with a polytetrafluoroethylene (PTFE) sheet and allow it to dry under ambient conditions (8 h). Place the Petri dish in a vacuum oven at 70 °C under vacuum overnight (~16 h).
  3. Remove from the oven and allow the Petri dish to cool to RT. Remove the polymer from the PTFE sheet and crush it into smaller pieces
  4. Preheat the top and bottom plates of a carver press to 150 °C and allow the temperature to equilibrate for 20 min. To specify the temperature set-point, press and hold the * button and increase or decrease the set point using the buttons with the upward or downward pointing arrows, respectively. Release the buttons for the set point to be fixed.
  5. Cover a steel plate (100 mm x 150 mm x 1 mm) with a PTFE sheet and place the steel dogbone mold (F) on this. Fill the cavities of the mold with the polymer P3.
    NOTE: Overall dimensions of the mold cavity: length 20 mm, width 7 mm, and depth 1 mm; gauge dimensions: length 10 mm, width 3 mm.
  6. Cover the mold with a PTFE sheet and another steel plate of the same dimensions as step 6.5.
    NOTE: Underfilling the mold cavities can lead to bubbles or defects in the dogbone samples.
  7. Place the above mold assembly in the heated carver press and apply a load of about ~7,000 lb using the hand crank on the carver press.
  8. Allow the mold to reach the desired temperature for 10 min followed by another 10 min for compression molding to be complete. Release the platens of the press and remove the mold assembly.
    NOTE: The mold will be very hot; use heat-resistant gloves and tongs to handle it.
  9. Cool the mold assembly by running under cold water; remove the mold from the steel plates and PTFE sheet. Push out the samples by hand.

Representative Results

Discussed here are representative results previously published15,18,19. Figure 5 shows the GPC traces for polymer P1 prepared by conventional ROMP with G2 (red curve)15 and living ROMP of EM1 with G1/PPh3 (black)18. The polymer prepared by living ROMP has a much narrower molecular weight distribution (Mn = 114.9 KDa, Ð = 1.17) versus the rather broad distribution seen for the polymer prepared by conventional ROMP with G2 (Mn = 142 KDa, Ð = 1.55).

1H NMR spectra for the depolymerization of linear (P1) and crosslinked (PN1) polymers are given in Figure 6. The extent of depolymerization of P1 is measured by calculating the ratio of the integral of the peaks corresponding to monomeric olefinic protons with respect to the sum of the peak integrals of the monomer and residual oligomer olefinic protons (as indicated in Figure 6A). Under the dilute conditions and in the presence of 1 mol% G2, P1 is depolymerized nearly quantitatively (~93%). The extent of depolymerization of PN1 is calculated similarly and amounts to ~94% (Figure 6B). It must be noted here that, for PN1, "monomers" refers to the mixture of monofunctional monomer and crosslinkers (M2 and XL, respectively) obtained after depolymerization.

Figure 7 shows the representative tensile curves (these data are from previously published work15) for polymer P3 and networks PN1. The presence of the flexible butyl chains in M2 causes PN1 to be a soft, elastomeric material with an ultimate tensile strain of ~0.64 MPa, modulus of ~ 0.76 MPa, and strain at break of ~226%.

On the other hand, polymer P3 with the rigid phenyl imide substituent behaves like a rigid glassy material with an ultimate tensile strength of ~41.4 MPa and strain at break of ~3.4%. Tensile testing was performed for P3 with an Instron Universal Testing Frame, while that for PN1 was performed with a homemade tensile tester, both at a crosshead speed of 5 mm·min−1.

Figure 1
Figure 1: tCBCO monomers for depolymerizable olefinic polymers. (A) tCBCO monomers for chemically recyclable polymers. (B) Synthesis of tCBCO monomers. Photochemical [2 + 2] cycloaddition of 1,5-cyclooctadiene and maleic anhydride affords the anhydride 1, which can be readily converted to M1 and XL, M2, and M3 through conditions (i), (ii), and (iii), respectively. (i) M1: MeOH, reflux; MeOH, EDC, DMAP, DCM; XL: 1,4-butanediol, EDC, DMAP, DCM. (ii) M2: NaOH, H2O, 60 °C; 1-butanol, EDC, DMAP, DCM. (iii) M3: aniline, acetone; sodium acetate, acetic anhydride, 100 °C. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Reaction schemes for small molecule and polymer synthesis outlined in this work. (A) Synthesis of tCBCO small molecules and monomers. (B) Synthesis of P1 by conventional ROMP. (C) Synthesis of P1 by living ROMP. Please click here to view a larger version of this figure.

Figure 3
Figure 3. Reaction setup for photochemical isomerization of M1. The photoisomerization of M1 세스 EM1 involves irradiation under flow conditions, and the setup consists of a photoreactor housing the quartz reaction tube, a column packed with AgNO3-impregnated silica (to trap the product), and a metering pump to enable the flow of the reaction mixture. Please click here to view a larger version of this figure.

Figure 4
Figure 4: Molds used for compression molding of P3 and preparation of PN1. (A) Steel mold for compression molding of P3 and (B) PTFE mold for curing elastomer network PN1. Please click here to view a larger version of this figure.

Figure 5
Figure 5: GPC traces for polymer. GPC traces for polymer P1 prepared by living ROMP in the presence of G1 and PPh3 (black) and conventional ROMP in the presence of G2 (red). This figure has been prepared from previously published data (red trace from Sathe et al.15, black trace from Chen et al.18). Please click here to view a larger version of this figure.

Figure 6
Figure 6: Depolymerization of tCBCO based polymers. (A) Depolymerization reaction scheme and stacked partial 1H NMR spectra of (B) polymer P1 after depolymerization (black), polymer P1 before depolymerization (blue), and monomer M1 (red) and (C) network PN1 after depolymerization (black), crosslinker XL (blue), and monomer M2 (red). This figure has been prepared from previously published data (data for B are from Sathe et al.19, data for C are from Sathe et al.15). Please click here to view a larger version of this figure.

Figure 7
Figure 7: Stress vs. strain curves. (A) Polymer network PN1 and (B) polymer P3. This figure has been prepared from previously published data from Sathe et al.15. Please click here to view a larger version of this figure.

Discussion

The tCBCO monomers can be prepared from a common precursor: the [2+2] photocycloadduct of maleic anhydride and 1,5-cyclooctadiene, anhydride 1. Since the crude anhydride 1 is difficult to purify but can be hydrolyzed readily, the crude photoreaction mixture is subjected to methanolysis conditions to yield the readily isolable methyl ester-acid 2. The recrystallization of 2 after column chromatography is key to obtaining the pure trans-cyclobutane isomer of 2. 2 can be readily derivatized to prepare several different tCBCO monomers as outlined here, including the diester monomers M1 and M2, imide monomer M3, and ester crosslinker XL. Additionally, the final esterification step in the preparation of M2 and XL can lead to the formation of a side product that, we hypothesize, differs only in the relative stereochemistry of the ester groups (cis- for M2 and XL vs. trans- for the side products). Being only slightly lower in polarity than the desired products, care must be taken during the purification of M2 and XL so as to ensure efficient separation and minimize the loss of product. Typically, performing column chromatography under gravity (instead of flash chromatography) yields satisfactory results in this case.

The preparation of the highly strained monomer with the trans-cyclooctene, EM1, provides access to depolymerizable polymers with controlled molecular weight distribution. To achieve this, a photochemical isomerization method employing flow chemistry is utilized. This method shows higher yield and functional group tolerance compared to conventional batch-type photoisomerization. In this flow system, silver nitrate is used to immobilize EM1 in a column. The constant removal of EM1 drives the equilibrium in the irradiated reaction mixture toward EM1 and prevents its photodegradation. Active silver nitrate and proper polarity of the solvent mixture are critical for optimal results. Additionally, the pressure buildup can cause leakages; thus, pre-circulation before irradiation is necessary to locate any leakages. Due to the silver nitrate silica gel and Et2O/hexane solvent mixture, this method is limited to compounds with relatively low polarity and sufficiently high solubility in Et2O/hexane. Further, the trans-olefins in these monomers are reactive and prone to dimerization/decomposition in the presence of acidic impurities23. Additionally, if the monomer is not isolable as a solid, it may be stored as a dilute solution or with a small amount of BHT (~3%-5%) added to prevent radical-induced side reactions; these trans-olefin monomers may also be refrigerated to further prevent degradation24.

The tCBCO monomers can be polymerized to high molecular weights at ambient temperatures by ring-opening metathesis polymerization (ROMP) in the presence of G2. A rather high monomer concentration (~2 M) is needed to achieve this, owing to the low ring strain of the tCBCO monomers. If the monomers prove difficult to dissolve in the solvent at such high concentrations, sonication in an ultrasound bath may be helpful. Under these conditions, the polymerization can be performed to conversions >80% and high molecular weights (Mn > 100 kDa), albeit with broad dispersities (Đ > 1.5)15.

Monomer EM1, on the other hand, can be polymerized to a high conversion in a short time, even at low initial monomer concentrations. We attribute this to the high ring strain in EM1, resulting in a higher driving force for its polymerization. Depolymerization and cross-metathesis are suppressed by using an excess amount of PPh3 with respect to G1, allowing polymerization to proceed to high conversions while maintaining low Đ (<1.2). The polymerization shows a living character and can be applied for the synthesis of block copolymers18. The technique is fairly straightforward and robust enough that it can be conducted under ambient conditions by the simple addition of stock solutions. One important note, however, is that PPh3 must be purified (to remove oxidized PPh3 and other impurities) and stored under nitrogen (the purification may be done by recrystallization from ethyl acetate); additionally, care should be taken to dry the glassware before performing this polymerization.

The depolymerization of linear and crosslinked polymers based on this system under mild conditions is also demonstrated. It is interesting that this depolymerization is not restricted to linear polymers only-polymer networks prepared with this system can also be readily depolymerized. This is likely because, while the local concentrations of olefinic groups in the swollen network may be high, chain scission events in the presence of catalyst aid in the degradation and dissolution of the network, following which the fragments further undergo depolymerization. It is critical to quench the catalyst with ethyl vinyl ether after depolymerization prior to evaporating the solvent since the extent of depolymerization may be affected if the active catalyst is still present in the system.

The versatility of this system is further cemented by the range of properties accessible. Here, the preparation of a soft rubbery network, as well as a rigid glassy plastic with the same depolymerizable core, is demonstrated. The preparation of network PN1 may be challenging since it is rather fragile in the swollen state, requiring careful handling when removing it from the mold. Additionally, when performing Soxhlet extraction, highly volatile solvents (like dichloromethane) should be avoided since the rapid evaporation of such solvents may lead to warping and fracture of the sample. Additionally, to avoid such fracture, the swollen network should be allowed to dry in a covered container to slow the evaporation of the solvent. If the dissolution of P3 in DCM during the preparation of dogbone samples proves difficult, an additional solvent may be added in small increments. Further, to avoid defects while preparing dogbone samples with P3, the underfilling of mold cavities should be avoided. High-temperature processing of P3 can also lead to oxidative degradation due to the presence of olefinic groups in the backbone. To prevent this, butylated hydroxytoluene (BHT) may be added to the polymer.

The versatile nature of the tCBCO system lends itself to a diverse range of thermomechanical properties through facile functionalization, which can facilitate the introduction of chemical recyclability to areas where it has been as yet limited, like high-performance thermosets and composites. Additionally, the ability to access living polymerization with this system drastically expands the scope of depolymerizable polymer architectures that can be prepared, including block copolymers and bottlebrush and graft polymers.

Disclosures

The authors have nothing to disclose.

Acknowledgements

We acknowledge funding support from the University of Akron and the National Science Foundation under grant DMR-2042494.

Materials

1 and 3 dram vials VWR 66011-041, 66011-100
1,4-butanediol Sigma-Aldrich 240559-100G
1,5-cyclooctadiene ACROS AC297120010
1-butanol Fisher A399-1
20 mL scintillation vials VWR 66022-081
Acetic Anhydride Alfa-Aesar AAL042950B
Acetone Fisher A18-20
Aluminum backed TLC plates Silicycle TLA-R10011B-323
Ammonium hydroxide Fisher A669-212
Aniline TCI A0463500G
BD precisionglide (18 G) Fisher
Chloroform Fisher C298-4
Column for circulation (to be packed with silver nitrate treated silica gel) Approximately 1 cm radius and 25 cm long, with inner thread on either end
d-Chloroform Cambridge Isotopes DLM-7-100
Dichloromethane VWR BDH1113-19L
EDC.HCl; 3-(3-dimethylaminopropyl)-1-ethyl-carbodiimide hydrochloride Chemimpex 00050
Ethyl Acetate Fisher E145-20
Ethyl Vinyl Ether Sigma-Aldrich 422177-250ML
Glass chromatography columns Fabricated in-house D = 20 mm, L= 450 mm and D = 40 mm, L = 450 mm The columns are fitted with a teflon stopcock at one end and a 24/40 ground glass joint to accommodate a solvent reservoir if needed.
Grubbs Catalyst 1st Generation (M102) Sigma-Aldrich 579726-1G
Grubbs Catalyst 2nd Generation (M204) Sigma-Aldrich 569747-100MG
Hexanes Fisher H292-20
Hydraulic press Carver Instruments #3912 Coupled with temperature control modules (see below)
Hydrochloric acid Fisher AA87617K4
Maleic Anhydride ACROS AC125240010
Methanol Fisher A412-20
Micro essential Hydrion pH paper (1-13 pH) Fisher 14-850-120
Normject Luer Lock syringes (1, 3 and 10 mL) VWR 89174-491, 53547-014 and 53547-010
Photoreactor chamber Rayonet RPR-100
QuadraPure TU (catalyst scavenger) Sigma-Aldrich 655422-5G
Quartz tubes Favricated in-house D=2", L=12.5" and D=1.5", L=10.5"
Rotavap Buchi
SciLog Accu Digital Metering Pump MP- 40 Parker 500 mL capacity
Siliaflash Irregular Silica, F60 Silicycle R10030B-25KG
Silver Nitrate ACROS AC197680050
Sodium hydroxide VWR BDH9292-2.5KG
Steel Mold Fabricated in-house Overall dimensions of mold cavity: length 20 mm, width 7 mm and depth 1 mm; gauge dimensions: length 10 mm, width 3 mm)
Steel Plates Fabricated in-house 100 mm x 150 mm x 1 mm
Teflon Mold (6-cavities) Fabricated in-house Overall cavity dimensions: length 25 mm, width 8.35 mm and depth 0.8 mm; gauge dimensions: length 5 mm, width 2 mm)
Teflon Sheets (0.005" thick) McMaster-Carr 8569K61
Temperature Control Modules Omega C9000A and C9000 °C units (two modules, one for top and one for bottom)
Triphenyl Phosphine TCI T0519500G
UV lamps Rayonet RPR2537A and RPR3000A
Vacuum pump Welch Duoseal
Whatman Filter Paper (grade 2) VWR 09-810F filter paper
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References

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Tags

Depolymerizable Olefinic PolymersFused-ring Cyclooctene MonomersChemical RecyclingHydrocarbon BackbonePhotochemistryColumn ChromatographySilver Nitrate-impregnated Silica Gel

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Sathe, D., Zhou, J., Chen, H., Wang, J. Depolymerizable Olefinic Polymers Based on Fused-Ring Cyclooctene Monomers. J. Vis. Exp. (190), e64182, doi:10.3791/64182 (2022).
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