Xuehui
Liu
,
Xu
Zhao
,
Wenli
An
,
Rongcheng
Du
,
Gang
Wu
,
Shimei
Xu
*,
Fan
Zhang
and
Yu-Zhong
Wang
*
The Collaborative Innovation Center for Eco-Friendly and Fire-Safety Polymeric Materials (MoE), National Engineering Laboratory of Eco-Friendly Polymeric Materials (Sichuan), College of Architecture and Environment, State Key Laboratory of Polymer Materials Engineering, College of Chemistry, Sichuan University, Chengdu 610064, China. E-mail: yzwang@scu.edu.cn; xushimei@scu.edu.cn
First published on 30th September 2022
A new family of supramolecular materials is exploited from waste thermosets via a one-step retrosynthetic approach, which exhibits distinguished adhesion properties in dry/wet environments, good corrosion resistance and dynamic reversibility. This work opens up a wide design space for supramolecular materials with excellent performances and proposes a new strategy for efficient utilization of hybrid degraded products.
New conceptsExploiting novel and high-performance materials from post-consumer wastes is an innovative and far-reaching work whereas it has been manifested to be extremely challenging. Herein, we demonstrate upcycling of waste thermosets into supramolecular materials based on low-molecular-weight molecules via one-step oxidation, thus realizing the long-term circulation of commercial polymers from petrochemical resources, which is rarely reported. Driven by supramolecular interactions, degraded products even with a complex composition are directly and efficiently reutilized without sophisticated separation/purification. It is so different from traditional recovery strategies, which focus on reconstructing new products using covalent bonds after breaking waste polymers, on most occasions, with low utilization. Our method realizes for the first time the reconstruction of small-molecule degraded products using non-covalent bonds on the basis of full use of the wastes. What is more, this waste-based material exhibits distinguished adhesion properties in dry/wet environments. It can act as a sealing and oil–water separation material based on spontaneous formation of a solidified layer in air or at the oil/water interface. This work is of great significance not only in waste recovery where degraded products are fully used with a high value being added but also in designing unprecedented supramolecular materials where distinguished and unique performance is obtained. |
Epoxy resin (EP), as a typical thermoset, has been used widely in different industrial applications, including adhesives and paintings, electronics, wind blades, due to its excellent performance. Previously, the recovery strategies mainly focused on breaking down thermosets to recycle reinforcing fibers but neglected further utilization of the degraded products.19–21 Recent developments reported that the degraded products can be used as additive components, but the performances of final materials might be weakened in high addition of degraded products.22–24 Furthermore, dense cross-linked networks and various C–C, C–O and C–N bonds of EP make it extremely difficult to recover chemicals or polymers with high purity and quality. Several EP recovery examples to recycle raw chemicals such as bisphenol A have been reported but with limited productivity.25,26 Consequently, diverse structures, complicated separation/purification processes and incomplete reutilization of the degraded products lead to a huge waste of energy and resources and even cause severe secondary pollution. In particular, for commercial plastics which contain various additives, such as plasticizers, flame retardants and so on, it is more difficult to make full use of the degraded products. To address these problems and challenges, some new strategies are highly desired.
Molecular building blocks of modern polymeric materials are connected by covalent bonds or noncovalent interactions. The polymers cross-linked by covalent bonds generally require structural units with strict screening and an appropriate design. It often leads to multi-step processing and high cost. By contrast, supramolecular materials are generated by assembling molecules into larger structures via noncovalent interactions, while introducing unique and fascinating properties, such as dynamic reversibility, adaptivity and stimulus responsiveness to the materials.27,28 Now, it is an extremely promising and emerging area in materials chemistry.29 The functional groups of the molecular building blocks are the key to realize this goal. This may provide a new opportunity for high-value and efficient utilization of degraded products with complex compositions. Yet, the approaches to construct supramolecular systems are still based on fresh structural units, and the utilization of renewable resources is very challenging.
Herein, we demonstrate the conversion of waste amine-cured EP into a high-performance supramolecular material, which not only uses a new and universal upcycling method by introducing supramolecular interactions into the reconstruction of degraded products but also introduces a viable path to construct supramolecular materials. The new strategy converts waste materials directly into new high-performance materials, avoiding complex and energy-consuming separation. To our best knowledge, this is the first report on supramolecule reconstruction instead of traditional chemical reconstruction, which makes full use of degraded products. Our approach used hydrogen peroxide alone as a reaction reagent to decompose waste EP without the assistance of additional catalysts or organic solvents. The degraded amine-cured EP (DEP) was easily separated from water solution by filtering due to its insolubility. During the degradation process, OH radicals attack the C–N cross-linking points to break the three-dimensional networks in EP, while the disconnected epoxy units are oxidized into oligomers with ketones or carboxyl groups. This end-functionalized DEP with intermolecular hydrogen bonds can be directly used as a novel low-molecular-weight monomer (LMWM)-based supramolecular adhesive. It exhibits excellent and reversible adhesion properties for various substrates and good corrosion resistance to water, acid, and salt and alkane organic solvents. Even DEP also shows strong adhesion properties under aqueous conditions with a maximum lap-shear strength of 5.8 MPa, which is higher than those of most of the underwater adhesives previously reported. The success of this work provides new insights into upcycling of plastic wastes and opens up a new path for designing supramolecular materials.
The results of gel permeation chromatography (GPC) show that the weight-average molecular weight of DEP is 709 with a polydispersity index of 1.69 (Fig. S4, ESI†), indicating that DEP can be a monomer or a multimer. The possible molecular structures of DEP were investigated by electrospray ionization mass spectrometry, and it shows that the compounds in DEP were similar to the monomers, dimers and trimers of diglycidyl ether of bisphenol A (DGEBA). This finding further confirms that EP is degraded through the cleavage of C–N cross-linked points. Different from the molecular ions of DGEBA, oligomers rich in hydroxyl, carboxyl, amino and nitro functional groups are clearly detected in DEP (Fig. S5 and S6, ESI†). From the molecular fragments, hydroxyl groups tend to oxidize, and ketone/aldehyde and carboxyl groups are produced. Amino groups may be oxidized to nitro groups. Additionally, pyrolysis-GC/MS was used to determine the structure of the final decomposed products. The signal of the phenolic derivative from DEP is observed after pyrolysis at 700 °C, proving that the benzene rings are retained during the degradation process (Fig. S7, ESI†).
According to the above results, the possible decomposition mechanism of the amine-cured EP in H2O2 is proposed (Fig. 1c). First, hydroxyl radicals from H2O2 mainly attacked C–N bonds to form compounds containing hydroxyl and amino groups, without destroying benzene rings and other resin skeleton structures. Owing to strong oxidation capacity of H2O2, the secondary and primary hydroxyl groups could be further oxidized to form ketones or carboxyl groups, respectively. Besides, amino groups can also be oxidized to nitro groups. Therefore, the cross-linked network in amine-cured EP was transformed into linear short chains, which can be dissolved in DMF (Fig. S8h, ESI†). But it was interesting to find that DEP particles stick together to form solid blocks after the reaction due to abundant hydrogen bonds formed in DEP. To verify the above mechanism, comparative reactions were designed by adding tert-butanol or ethanol as a radical scavenger. The obtained degraded products were still solid powders and insoluble in DMF (Fig. S8g and i, ESI†) and exhibited markedly different chemical structures (Fig. S9, ESI†). These results can be explained as that the hydroxyl radicals from H2O2 played a leading role in the degradation of the amine-cured EP.
The amine-cured EP exhibits high initial thermal decomposition temperature and glass transition temperature (Tg). After degradation, the DEP still possesses excellent thermal stability since it starts to decompose as the temperature exceeds 210 °C and shows a Tg of 85 °C (Fig. S10 and S11, ESI†). Temperature-dependent FTIR spectroscopy was used to explore the assembly mechanism of DEP (Fig. 2a and Fig. S12a, ESI†). The bands in the region of 3500–3200 cm−1, which are assigned to the stretching vibration of hydroxy and amino groups, gradually shift to high wavenumbers upon heating, accompanied by their intensity reduction. It suggests the generation of “free” groups. At the same time, the N–H bending vibration (1607 cm−1) and C–OH stretching vibration (1041 cm−1) gradually shift to lower wavenumbers. Moreover, with increasing temperature, the peak intensity of the 1748 cm−1 (“free” CO groups) peak gradually increases, revealing the rupturing of hydrogen bonds related to carboxyl groups.30,31 Meanwhile, C–O–C and C–N also show complex changes upon heating from 25 to 130 °C. The spectral intensity of the 1244 cm−1 (C–O–C) and 1108 cm−1 (fatty C–N) peaks gradually decreases, while the peak at 1294 cm−1 (aromatic C–N) exhibits a red shift during the heating process. These results confirm that various types of hydrogen bonds exist in DEP.
In addition, we also observed that powdery DEP became a viscous liquid after adding hot ethanol or immersing in hot water (Fig. 2b and Fig. S13, ESI†). No carbon skeleton changes in DEP are found after treating with C2H5OH (DEP-C2H5OH) and H2O (DEP-H2O) (Fig. S14 and S15, ESI†). However, even after sufficient drying, an obvious increase in the O/C ratio is observed in DEP-H2O and DEP-C2H5OH (Table S2, ESI†). This result is due to the formation of new hydrogen bonds between DEP and water/ethanol molecules as the hydrogen bonds between DEP break. The interaction between ethanol and DEP is also confirmed from the rheological behaviors of C2H5OH-DEP. All samples are a viscous liquid with G′′ > G′ over the frequency sweep and temperature sweep (Fig. 2c and Fig. S16, ESI†). Upon increasing the content of ethanol, DEP exhibits a much lower G′, G′′, complex viscosity and Tg, proving the role of ethanol in breaking the hydrogen bonds in DEP (Fig. 2c, d and Fig. S17, ESI†). These results further verify that multiple hydrogen bonds exist in DEP, and the possible supramolecular network is shown in Fig. 2e (Fig. S12b, ESI†).
Impressively, DEP melted in the range of 145 to 210 °C and solidified as the temperature decreased. It behaves like the melting transitions of commercially available hot-melt adhesives such as the ethylene vinyl acetate copolymer (EVA) and amorphous poly alpha olefin (APAO) (Fig. S18, ESI†). Thus, DEP can be used as a candidate for hot-melt adhesives. Its adhesive strength reaches 2.31 MPa, which is about four times that of EVA (0.64 MPa) and three times that of APAO (0.72 MPa) (Fig. 3a). Encouraged by these results, the adhesive properties of DEP with the assistance of ethanol were further investigated to lower its operating temperature. As expected, DEP after adding ethanol exhibits an obvious stringing phenomenon when stretched between the two glass slices (Fig. 3b). The adhesive properties of DEP with different ethanol contents were investigated to imitate the adhesion process of DEP-C2H5OH with the extension of the drying time. As the ethanol evaporates, the adhesive strength of DEP gradually increases due to the reformation of intermolecular hydrogen bonds in DEP (Fig. 3b and Fig. S19, ESI†).
Benefiting from versatile functional groups, DEP shows excellent adhesion to various substrates, including hydrophilic glass and hydrophobic PTFE (Fig. 3c and Fig. S20 and S21, ESI†). Considering the remarkable and excellent adhesive strength to wood (1.25 MPa), DEP is expected to be a substitute for phenolic resin adhesive to reduce the use of formaldehyde. Interestingly, the soft PDMS after being cut can also be completely bonded and further bent over (Fig. S22, ESI†). The adhesive strength of DEP to aluminum slides remains at 2.5 MPa even after five cycles (Fig. 3d and Fig. S23, ESI†), which is equivalent to the initial value, exhibiting excellent regenerative nature. Furthermore, DEP shows excellent corrosion resistance to different aqueous or organic solutions. Notably, the adhesion strength of DEP remains above 2 MPa, and no small molecules are released from DEP even after immersing in different solvents for 48 h, proving the excellent stability of DEP (Fig. 3e and Fig. S24–S28, ESI†).
Different from most existing adhesives, DEP is easily detached from the substrate surface by implanting ethanol. In this way, the separated substrate could be restored to its original state and reused again (Fig. 3f). Aluminum slides are taken as an example to demonstrate the adhesion in various DEP layer sizes (Fig. S29, ESI†), and the adhesive strength for a DEP layer size of 1 cm2 is up to 4.34 MPa, beyond the property space of the previously reported LMWM-based supramolecular adhesives, and even higher than that of the previously reported high-molecular-weight molecule (HMWM)-based adhesives (Fig. 3g, details are in Table S3, ESI†).32–43 As the DEP layer size increased, greater force capacity can be observed. Furthermore, upon increasing the layer size to 3 cm2, the load remained but the displacement increased instead according to the lap-shear strength curve. This was because the bonded aluminum slides slipped between the clamps before they were pulled off due to the strong adhesion of DEP.
Developing adhesives that can adhere to wet surfaces or even be used underwater is extremely challenging. In this work, DEP exhibits excellent underwater adhesion. The introduction of a small amount of ethanol permits DEP-C2H5OH kneading casually, which can be shaped into balls, cubes, stars and other shapes (Fig. 4a). It shows a plasticizing effect and thus facilitates accurate delivery of the adhesive to the underwater target location. The target object was picked up from the water as the temperature first increased to 80 °C and then decreased to 20 °C (Fig. 4c and Videos S2, ESI†), while no adhesive behavior was observed at 20 °C (Fig. 4b and Videos S1, ESI†), indicating that DEP can be used as an underwater adhesive via temperature control.
The underwater adhesive performances of DEP are dependent on the content of ethanol. Without the addition of ethanol, DEP cannot transform into a completely fluid state in 80 °C water and tends to show poor adhesion performance due to insufficient contact with the substrates. With an increase in the ethanol content, the adhesion strength was inclined to be lower due to the weakened hydrogen-bond network of DEP (Fig. S30, ESI†). Additionally, the underwater adhesion performances of DEP with different layer sizes were investiagted. The adhesion strength is up to 5.88 MPa at a layer size of 1 cm2. As the layer size increases to 3 cm2, the bonded Al slides remain stable without breaking under this test condition, which is associated with the excellent underwater adhesion of DEP (Fig. S31, ESI†). Moreover, the adhesion strength of DEP does not decay (5.5 MPa) even if it is placed underwater for 48 h, suggesting the desirable stability of DEP for long-term use (Fig. 4d and Fig. S32, ESI†). Compared with previously reported underwater adhesives, the adhesion strength of DEP is higher, and it can be used as a promising candidate for an ideal wet adhesive (Fig. 4e, details are in Table S4, ESI†).38,44–53
Taking advantage of the desired water resistance, adhesion to a variety of substrates and underwater adhesion performance, DEP can be also developed as sealing and separating materials (Fig. 5a). Upon heating, the powdered DEP sticks together due to the supramolecular interaction between the components. After cooling, a strong sealing layer was formed on the water surface while the water was encapsulated in the test tube. Even after standing upside down, the water does not flow out (Fig. 5b and Video S3, ESI†). Such an excellent performance makes it possible for DEP to be applied in preventing liquid leakage and other fields. Furthermore, when DEP was added to an oil–water mixture, such as an n-hexane–water mixture, it floated at the interface of oil and water due to the lipophilicity and hydrophobicity of DEP. Similarly a DEP sealing layer was formed through heating/cooling cycles so the oil–water mixtures were separated successfully (Fig. 5c and Video S4, ESI†). To our best knowledge, this is the first report on such adhesiveness–separation bifunctional materials, which avoids the disadvantages of traditional filtration or adsorption separation methods, such as complicated equipment, low flux and easy contamination.
Footnote |
† Electronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d2mh00781a |
This journal is © The Royal Society of Chemistry 2022 |