DOI:
10.1039/D4MH01055H
(Communication)
Mater. Horiz., 2025, Advance Article
Engineering of robust conjugated polymer-based aerogels via surface-initiated polycondensation towards sunlight-driven seawater desalination and uranium extraction†
Received
10th August 2024
, Accepted 11th October 2024
First published on 15th October 2024
Abstract
The aerogels with low thermal conductivity and cross-linked 3D networks can be easily integrated with functional materials to maximize their functionalities, realizing diverse applications such as photothermal seawater desalination and photocatalytic uranium extraction. Sp2C-conjugated porous polymers (sp2C-CPPs) with robust and conjugated CC linkages are ideal photosensitizers for these applications, owing to their exceptional semiconducting properties as well as chemical stability. However, the limited processability and collectability of as-synthesized sp2C-CPP powders impede their extended applications. Herein, we report the preparation of robust sp2C-CPP (DHA-TMT and DBD-TMT) based aerogels via surface-initiated aldol polycondensation (SI-AP). The fully conjugated CC skeletons and electron-donating groups (–OH) endow the sp2C-CPP aerogels with excellent photothermal conversion efficiency (95.6%) and strong affinity for uranium adsorption. In particular, the DHA-TMT aerogel with hydrophilic porous channel exhibits a superb evaporation performance achieving ∼1.55 kg m−2 h−1 under AM 1.5 G while the fast mass transfer caused by photothermal conversion increases the uranium extraction capacity up to 1200 mg m−2 in simulated seawater. Moreover, the sp2C-CPP aerogels demonstrate high stability under strong acid, base and brine solutions. This work shows a strategy for the preparation of uniform and high stability sp2C-CPP-based aerogels to simultaneously enhance their photothermal and photocatalytic performance.
New concepts
This work shows a strategy for the preparation of uniform and high stability sp2C-CPP-based aerogels to simultaneously enhance their photothermal and photocatalytic performance. Herein, we demonstrate the preparation of robust sp2C-CPP based aerogels via surface-initiated aldol polycondensation (SI-AP). Benefiting from the extended π-conjugated structure and the high-density –OH groups, the resultant sp2C-CPP-based aerogels exhibit a broad light-harvesting range extended to 2500 nm and excellent photothermal conversion efficiency. In particular, the DHA-TMT aerogel with hydrophilic porous channel exhibits a superb evaporation performance achieving ∼1.55 kg m−2 h−1 under AM 1.5 G. Meanwhile, the DHA-TMT-based aerogels exhibit exceptional photothermal conversion efficiency, which significantly enhances ion transfer. The uranium extraction ability through the fast mass transfer caused by photothermal conversion improves the original adsorption capacity from 280 (under dark) to 1200 mg m−2.
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Introduction
Conjugated polymer aerogels (CPAs) are a class of multifunctional materials constructed through conjugated bonds,1–3 integrating the excellent optoelectronic properties of conjugated polymers4,5 with the high porosity and thermal insulating properties of aerogels.6–9 Therefore, CPAs are widely applied in a range of fields like desalination,10,11 photocatalysis,12,13 air water harvesting14,15 and adsorption.16,17 However, traditional sol–gel and template-assisted methods for preparing freestanding CPAs encounter a barrier in terms of extensibility, such as the requirement for demanding conditions, such as supercritical CO2 drying,18 high temperature,19,20 and specific synthesis systems,21 and the as-prepared CPAs exhibit limited mechanical strength and uniformity.22,23 An effective strategy to address these challenges is preparing CPAs by surface-initiated aldol polycondensation (SI-AP) and in situ growth on pre-existing robust SiO2 aerogel substrates.24,25 Compared with other physical methods,26–29 the SI-AP strategy enables strong surface covalent bonding between the conjugated polymer and SiO2 aerogel, achieving structural designability and excellent mechanical properties for stable operation in harsh marine environments.30,31
Aldol polycondensation, as an efficient method to construct CC linkages through the reaction between aldehydes and acidic terminal methyl groups, has been extensively utilized to synthesize sp2C-conjugated porous polymers (sp2C-CPPs).32–34 The resultant sp2C-CPP powders generally share high chemical stability and exceptional optoelectronic properties,35–40 including light-harvesting capability41,42 and high charge carrier mobility43–45 due to their extended π-conjugation and robust skeletons, which render them highly desirable in numerous solar-driven energy conversion fields, such as photothermal seawater desalination and photocatalytic uranium extraction.4,46 Nevertheless, the typical powder morphology and insolubility of sp2C-CPPs impede their practical application and recyclability.47 As such, applying SI-AP to fabricate sp2C-CPP-based aerogels would be promising to surpass the inherent properties of powders and shape them into diverse forms towards desired applications.
Herein, we show the synthesis of two sp2C-CPP-based aerogels (DHA-TMT & DBD-TMT) through SI-AP on commercially available SiO2 aerogels. Benefiting from the extended π-conjugated structure and the high-density –OH groups, the resultant sp2C-CPP-based aerogels exhibit a broad light-harvesting range extended to 2500 nm and excellent photothermal conversion efficiency (∼71.8 °C under AM 1.5G). Furthermore, the hydrophilic porous channel and robust skeleton endow the aerogels with remarkable seawater desalination performance (1.55 kg m−2 h−1) and high stability. Meanwhile, the DHA-TMT-based aerogels demonstrate exceptional photothermal conversion efficiency, significantly enhancing ion transfer and promoting uranium extraction capacity up to 1200 mg m−2. This work presents the design and synthesis of robust and high-performance sp2C-CPP-based aerogels for simultaneous sunlight-driven seawater desalination and uranium extraction.
Results and discussion
Preparation and characterization of the sp2C-CPPs
Firstly, to explore the effect of varying conjugation degree on the photothermal properties of the materials, two sp2C-CPPs with different structures were synthesized (Fig. 1B). The sp2C-CPPs are synthesized via an in situ on surface-initiated strategy on the aerogel.
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| Fig. 1 (A) Schematic of the synthesis of sp2C-CPPs on aerogels through surface-initiated aldol polycondensation. (B) The theoretical structure of DHA-TMT and DBD-TMT. (C) and (D) FT-IR spectra of DHA, DBD, TMT, DHA-TMT CPP, and DBD-TMT CPP. (E) and (F) Photograph and SEM images of DHA-TMT aerogels and DBD-TMT aerogels. | |
As shown in Fig. 1A, a self-assembled monolayer (SAM) of 3-aminopropyltrimethoxysilane (APTES) is created on an aerogel with a native oxidized layer. The comprehensive XPS spectra and high-resolution C 1s spectra of aerogel-APTES reveal distinct new N 1s and C–N peaks, respectively, providing compelling evidence for the successful grafting of APTES onto the aerogels (Fig. S1, ESI†). Next, the SAM-modified aerogel is immersed in a solution containing 2,4,6-trimethyl-1,3,5-triazine (TMT) and either 2,5-dihydroxy-1,4-benzenedicarboxaldehyde (DHA)/4′,4′-biphenyldicarboxaldehyde or 3′,3-dihydroxy (DBD) at 150 °C for three days to produce uniform DHA-TMT and DBD-TMT aerogels through in situ growth (Fig. S2, ESI†). During the in situ growth process of DHA-TMT and DBD-TMT aerogels, Brønsted acid acts as a catalyst for both Schiff base formation and aldol condensation reactions resulting in grafting of an olefin-linked sp2C-CPP layer on the aerogel. The successful preparation of sp2C-CPPs was proven by Fourier transform infrared (FTIR) spectroscopy (Fig. 1C and D). In the FTIR spectra of both groups in DHA-TMT and DBD-TMT, a sharp decrease of the stretching vibration peak of CO (1668 cm−1, 1662 cm−1) was observed; meanwhile, new peaks attributed to the CC stretch band appeared at 1632 cm−1 and 1617 cm−1, confirming that the sp2C-CPPs of vinylene linkages were successfully formed. Scanning electron microscopy (SEM) measurements show that both sp2C-CPPs have globular morphology (Fig. 1E and F) and it should be noted that the blank sample fiber has a smooth surface with no isolated globular particles (Fig. S3, ESI†), evidencing that the 2D sp2C-CPPs grow in situ along the surface of the aerogel. In addition, SEM images show a rougher surface with more spherical particles in the DHA-TMT aerogel, which enhance light absorption through multiple internal reflections and scattering (Fig. 1E and F inset). Meanwhile, the rough surface also improved solar utilization efficiency and promoted a larger contact area with uranyl ions (Fig. S4, ESI†). Additionally, the water contact angle test results demonstrate that the blank aerogel was hydrophobic while the sp2C-CPP aerogel exhibits exceptional hydrophilicity due to the abundant presence of hydroxyl groups within its structure (Fig. S5, ESI†). The mechanical stiffness was assessed through a uniaxial quasi-static compression test. The mechanical properties of the blank aerogel and DHA aerogel are similar, revealing that sp2C-CPP coating has a relatively small impact on mechanical strength (Fig. S6 and S7, ESI†). Fig. S8a (ESI†) illustrates the strain–stress relationship of the sp2C-CPP aerogel at various compression strains (30%, 50%, and 70%). It is evident that the aerogel material predominantly exhibits a densification regime, with its stress exponentially increasing beyond a strain of 50%. The compressive strength rises with the increase in compressive strain, reaching a maximum value at 70% (approximately 0.63 MPa). The sp2C-CPP aerogel underwent compression fatigue tests, and after 10 load-to-unload cycles at a strain of 70%, it demonstrated the ability to retain approximately 70% of its initial maximum stress, exhibiting its exceptional mechanical strength (Fig. S8b and c, ESI†). Furthermore, the microscopic measurement demonstrated that sp²C-CPP aerogel still retains fibrous structure after compression fatigue testing. Moreover, the sp2C-CPP aerogels demonstrate exceptional chemical and thermal stabilities as evidenced by thermogravimetric analysis (TGA) and acid/base (12 M HCl or 12 M NaOH) immersion tests (Fig. S9, ESI†).
Efficient solar-powered water evaporation of sp2C-CPP aerogels
As shown in Fig. 2A, in the evaporation system, polystyrene foam was used to provide buoyancy, and cotton thread was employed to pump water from the bulk water for continuous and stable evaporation (Fig. S10, ESI†). To further investigate the light absorption performance, the light absorption properties of both sp2C-CPP aerogels were characterized by UV-vis-NIR spectroscopy (Fig. 2B). DHA-TMT aerogel showed relatively low light transmittance and reflectance over the entire solar spectrum compared with DBD-TMT aerogel, indicating that the DHA-TMT aerogel possessed more excellent light absorption performance. In addition to the rougher inner surface, the higher degree of conjugation of the DHA-TMT aerogel was another reason for the more excellent light absorption performance. Sp2C-CPPs are a new class of organic semiconductor materials follow the electron–hole generation and relaxation photothermal conversion mechanism. Organic polymers with highly planar backbones have the ability to enhance π-conjugation and facilitate electron–hole pair separation. Consequently, the extended π-conjugated plane structure, formed by hydroquinone units as building blocks with an elevated degree of conjugation, exhibits improved photothermal conversion efficiency. Furthermore, we used an IR camera to observe and record the temperature rise curve and photos of both sp2C-CPP aerogel evaporation devices under 1 sun (Fig. 2C and Fig. S11, ESI†). Compared with the dry DBD-TMT aerogel with a value of 65.5 °C within 300 s, the DHA-TMT aerogel sample can reach up to 71.8 °C within 300 s under 1 sun irradiation. The results show that the higher the conjugation degree of sp2C-CPPs, the stronger the photothermal conversion ability.
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| Fig. 2 (A) Scheme of the setup used in the water evaporation test. (B) The UV absorption spectra of different samples in the wavelength range of 400 to 2500 nm and comparison with the standard AM 1.5 G spectrum filter. (C) Temperature versus time curves of DHA-TMT aerogels and DBD-TMT aerogels. (D) Mass change versus time curves of bulk water, fiberglass, DHA-TMT aerogels, and DBD-TMT aerogels under 1 sun irradiation. Water evaporation rate from bulk water, fiberglass, and DHA-TMT, DBD-TMT under 1 sun irradiation (inset). (E) Mass change versus time curves of DHA-TMT and DBD-TMT evaporators under different optical concentrations. (F) DHA-TMT and DBD-TMT evaporator evaporation rate in simulated seawater for 12 hours. | |
We found that even though the absorption of water molecules has a high specific capacity, the surface temperature of the sp2C-CPP aerogels can reach almost 40 °C (Fig. S12 and S13, ESI†). Because of the low thermal conductivity of the aerogel, it has a good thermal insulation effect and greatly reduces the possible thermal diffusion, maximizing the use of converted solar energy. Then we tested the evaporation rate of both evaporators by optical concentrators. As shown in Fig. 2D, the water evaporation rates of the DHA-TMT and DBD-TMT aerogels were calculated to be 1.55 kg m−2 h−1 and 1.15 kg m−2 h−1 under 1 kW m−2. It is worth noting that, with the gradual increase in solar irradiance, the water evaporation rate of sp2C-CPPs shows an almost linear growth trend. This implies that the performance of sp2C-CPPs remains relatively consistent under different solar radiation conditions, demonstrating predictable stability (Fig. 2E). Surprisingly, the water evaporation rates of the DHA-TMT aerogel reached 0.7 kg m−2 h−1 of 0.5 sun irradiation for 1 h. This shows that even in places where sunlight is insufficient, the evaporation device can achieve a good evaporation effect (Fig. S14a, ESI†).
Meanwhile, we found that both aerogel samples still maintained a high evaporation rate after 10 cycles and 12 hours in 3.5 wt% seawater (Fig. 2F and Fig. S14b, ESI†). Moreover, the evaporation rate and efficiency were not significantly reduced by experiments at high-concentrations as high as 25 wt% (Fig. S14c, ESI†), which indicates the effectiveness of seawater, and no solid salt was deposited on the surface of the aerogel after 1 hour of evaporation, showing the concentration self-driven salt-resistance of the sp2C-CPP aerogels.
Self-driven salt resistance mechanism of the sp2C-CPP aerogels
High salt-resistance is a key property of evaporators to achieve desalination at a high evaporation rate. In general, one of the mechanisms for salt mitigation is salt ion diffusion backflow, which requires a stable and efficient water supply capacity of the evaporator, as well as macro-channels. So we have employed a simple method to investigate the self-driven salt resistance mechanism of sp2C-CPP aerogels. 0.5 gram of solid NaCl was placed on the surface of sp2C-CPP aerogel and floated in 200 mL DI water. Upon contact with water, the sp2C-CPPs aerogel was soaked rapidly due to the capillary effect, and then we observed that the solid salt dissolved in a short time and formed a concentrated salt solution on the surface of the sp2C-CPPs aerogel (Fig. 3A). And as new liquid flowed into the bulk solution, the concentrated solution moved down from the cotton. This is achieved by introducing a significant number of –OH groups at the molecular level into the backbone structure of the sp2C-CPPs, rendering it highly hydrophilic. Additionally, the large pore structure of the aerogel substrate itself facilitates the construction of numerous water channels that promote efficient salt circulation because the water channels can enhance the diffusion and convection of salt ions under the action of concentration gradients (Fig. 3B and C). Then, the practical applications of sp2C-CPPs for solar-light-driven desalination and water treatment were further explored. The seawater quality of the treated water was assessed using inductively coupled plasma mass spectrometry (ICP-MS). Following desalination through our solar water evaporation system, the concentrations of ions (Na+, K+, Mg2+, and Ca2+) were significantly reduced by three to four orders of magnitude, falling well below the drinking water standards set by the World Health Organization (WHO) (Fig. 3D). Besides seawater, sp2C-CPP based solar evaporation systems can also be used to purify wastewater containing heavy metals. After purification, the concentration of heavy metal ions such as Cr3+, Cu2+, Ni2+, Zn2+, and Ga3+ was reduced to ∼0.1 ppm (Fig. 3E). By comparison, it also can be seen that the evaporation rate of the sp2C-CPP aerogel evaporator in this work is higher than the average level of two-dimensional materials (1.42 kg m−2 h−1) (Fig. 3F and Table S1, refer to the ESI†).
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| Fig. 3 (A) Digital photographs of a salt self-excreting salt progression of DHA-TMT CPP aerogels under ambient conditions. (B) and (C) Schematic diagram showing the salt transport in seawater below the evaporator. (D) Ion concentration of simulated seawater before and after desalination. (E) Heavy ion concentration before and after purification. (F) Comparison of evaporation performance and photothermal conversion efficiency of different evaporators based on two-dimensional materials previously reported. | |
The synergistic effect of photothermal and photocatalysis for uranium extraction
Photocatalytic technology as an environmentally friendly, and efficient method has been extensively used for uranium recovery from natural seawater and solar-driven photothermal effects are considered to have significant potential in enhancing the coordination between uranium and binding sites48 (Fig. 4A). UV-vis absorption spectroscopy and Mott–Schottky plots were conducted to assess the optical properties of the two sp2C-CPP aerogels (Fig. 4B and Fig. S15, ESI†). The band gaps of the two sp2C-CPPs were 1.34 eV (DHA-TMT) and 1.49 eV (DBD-TMT), respectively, obtained by their corresponding Tauc plots (Fig. S10, ESI†). Combining with conduction band (ECB) values (−0.898 eV and −0.93 eV) determined via the x-intercept of the Mott–Schottky plots, we obtain the conduction band (EVB) values of 0.442 eV and 0.56 eV, based on the equation: EVB = ECB + Eg. Since these values are more positive than that of U(VI), the photogenerated electrons of both sp2C-CPPs are thermodynamically permitted to generate a reduction of soluble U(VI) to insoluble U(IV) (Fig. 4C). Encouraged by the above results, further investigations were conducted to explore the photocatalytic uranium capture performance of the two sp2C-CPP aerogels. All the experiments were conducted under simulated seawater conditions (pH = 8.2) to account for the simultaneous occurrence of photothermal desalination and uranium extraction from seawater. Firstly, we tested the uranium capacity of SiO2 aerogel substrate in the same condition. The results indicate that uranium capture by SiO2 substrate almost negligible (Fig. S17, ESI†). Significantly, under simulated sunlight irradiation, the uranium capture capacities of both sp2C-CPP aerogels sharply increased from 280 mg m−2 and 240 mg m−2 to 1200 mg m−2 (DHA-TMT) and 880 mg m−2 (DBD-TMT), respectively (Fig. 4D). And the extraction performance of uranium from DHA-TMT aerogel is significantly superior than DBD-TMT aerogel, which is consistent with the results of photothermal experiments mentioned above. This can be attributed to the highly conjugated hydroquinone group present in the donor unit, which significantly narrows the band gap and enhances charge transfer efficiency, resulting in higher photocatalytic uranium extraction capacity. Moreover, the photothermal effect elevates the overall temperature and accelerates the movement of uranyl ions, which further accelerates the extraction efficiency of uranium. Furthermore, the kinetic investigations indicate that the Langmuir model better fits the equilibrium adsorption isotherm, proving that photocatalytic uranium extraction is a chemical adsorption process (Fig. 4E and Fig. S18 and 19, ESI†). We performed calculations to determine the electron distribution in the highest occupied molecular orbitals (HOMOs) and lowest unoccupied molecular orbitals (LUMOs) of the sp2C-CPPs. The results indicate efficient electron injection from the π-conjugated backbone into the electrophilic triazine unit, facilitating enhanced separation of photogenerated electrons (Fig. 4F).
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| Fig. 4 (A) Schematic diagram of the proposed mechanism for DHA-TMT to capture uranium. (B) UV-vis absorption spectra of DHA-TMT and DBD-TMT. (C) Band structure diagram of DHA-TMT and DBD-TMT aerogels. (D) Adsorption kinetics of uranium on DHA-TMT and DBD-TMT aerogels. Experimental conditions: pH = 8.2, initial U(VI) = 16 ppm. (E) Adsorption isotherm of uranium on DHA-TMT and DBD-TMT. Experimental conditions: pH = 8.2. (F) The excited state electronic structures of DHA-TMT and DBD-TMT aerogels and schematic of the effect of temperature on the rate of motion of uranium ions. | |
Furthermore, DHA-TMT exhibits a narrower band gap in its HOMO–LUMO energy levels compared to DBD-TMT, suggesting superior electron mobility. Moreover, the emergence of new intense U 4f double peaks in the complete XPS spectra of both sp2C-CPP adsorbents, under both sunlight irradiation and dark conditions, provides compelling evidence for the formation of UO2 (Fig. S20a and b, ESI†). Also, the U 4f peaks were more pronounced after uranium adsorption in the light than in the dark. Meanwhile, the peaks for U 4f7/2 (382.01 and 381.87 eV) and U 4f5/2 (392.8 and 392.8 eV) in the high-resolution U 4f XPS spectra of DHA-TMT-U and DBD-TMT-U demonstrated that U(VI) and U(IV) coexisted after uranium binding both in the dark and under visible light irradiation, proving that U(VI) was reduced to U(IV) during the sorption of DHA-TMT and DBD-TMT (Fig. S20c and d, ESI†). Finally, following five cycles, the regenerated aerogel demonstrated a uranium adsorption capacity of 865 mg m−2, representing 75.5% of the initial capacity. This indicates that it can be effectively utilized for uranium adsorption in seawater environments over extended periods (Fig. S21, ESI†)
Conclusions
In summary, we show the synthesis of three-dimensional porous sp2C-CPP-based aerogels through surface-initiated aldol polycondensation. Owning to the extended π-conjugated structure and electron-donating groups (–OH), the as-prepared sp2C-CPP-based aerogels exhibit superior photothermal and photocatalytic performance. Under visible-light irradiation, the DHA-TMT-based aerogels showed high light-to-thermal conversion efficiency (∼95.6%) and water evaporation rate (∼1.55 kg m−2 h−1) in simulated seawater. The sp2C-CPP aerogels also exhibit an exceptional resistance to salt with no visible salt crystals on the surface of the aerogels even in 25% brine and under 10 cycles. Meanwhile, the DHA-TMT-based aerogels exhibit exceptional photothermal conversion efficiency, which significantly enhances ion transfer. The uranium extraction ability through the fast mass transfer caused by photothermal conversion improves the original adsorption capacity from 280 (under dark) to 1200 mg m−2. This work demonstrated an effective SI-AP approach to constructing robust sp2C-CPP-based aerogels and provided promising three-dimensional porous materials for sunlight-driven seawater desalination and uranium extraction.
Data availability
All data of this study are available within the article and its ESI.†
Conflicts of interest
There are no conflicts to declare.
Acknowledgements
This work was supported by the National Natural Science Foundation of China (Grant No. 52003279), the Leading Innovative and Entrepreneur Team Introduction Program of Zhejiang (Grant No. 2021R01005), and the Key Research and Development Program of Ningbo (Grant No. 2022ZDYF020023).
References
- J. A. Martín-Illán, D. Rodríguez-San-Miguel, O. Castillo, G. Beobide, J. Perez-Carvajal, I. Imaz, D. Maspoch and F. Zamora, Angew. Chem., Int. Ed., 2021, 60, 13969–13977 CrossRef.
- W. Zhang, H. Zuo, Z. Cheng, Y. Shi, Z. Guo, N. Meng, A. Thomas and Y. Liao, Adv. Mater., 2022, 34, 2104952 CrossRef CAS PubMed.
- N. B. McKeown and P. M. Budd, Chem. Soc. Rev., 2006, 35, 675–683 RSC.
- M. Wang, P. Zhang, X. Liang, J. Zhao, Y. Liu, Y. Cao, H. Wang, Y. Chen, Z. Zhang, F. Pan, Z. Zhang and Z. Jiang, Nat. Sustain., 2022, 5, 518–526 CrossRef.
- M. Barawi, L. Collado, M. Gomez-Mendoza, F. E. Oropeza, M. Liras and V. A. de la Peña O’Shea, Adv. Energy Mater., 2021, 11, 2101530 CrossRef CAS.
- N. Hüsing and U. Schubert, Angew. Chem., Int. Ed., 1998, 37, 22–45 CrossRef.
- F. Rechberger, F. J. Heiligtag, M. J. Süess and M. Niederberger, Angew. Chem., Int. Ed., 2014, 53, 6823–6826 CrossRef CAS PubMed.
- L. Chen, X. Yu, M. Gao, C. Xu, J. Zhang, X. Zhang, M. Zhu and Y. Cheng, Chem. Soc. Rev., 2024, 53, 7489–7530 RSC.
- X. Hu and J. Zhu, Adv. Funct. Mater., 2020, 30, 1907234 CrossRef CAS.
- C. Li, S. Cao, J. Lutzki, J. Yang, T. Konegger, F. Kleitz and A. Thomas, J. Am. Chem. Soc., 2022, 144, 3083–3090 CrossRef CAS PubMed.
- A. Jrad, M. A. Olson and A. Trabolsi, Chem, 2023, 9, 1413–1451 CAS.
- Y. Zhao, S. Li, G. Fu, H. Yang, S. Li, D. Wu and T. Zhang, ACS Cent. Sci., 2024, 10, 775–781 CAS.
- S. Li, Y. Geng, B. Teng, S. Xu, P. S. Petkov, Z. Liao, B. Jost, Y. Liu, X. Feng, B. Wu and T. Zhang, Chem. Mater., 2023, 35, 1594–1600 CrossRef CAS.
- H. L. Nguyen, N. Hanikel, S. J. Lyle, C. Zhu, D. M. Proserpio and O. M. Yaghi, J. Am. Chem. Soc., 2020, 142, 2218–2221 CrossRef CAS PubMed.
- A. Mei, H. Guo, W. Zhang, Y. Liu and W. Chen, Small, 2024, 2403521 CrossRef CAS.
- X. Guo, Y. Li, M. Zhang, K. Cao, Y. Tian, Y. Qi, S. Li, K. Li, X. Yu and L. Ma, Angew. Chem., Int. Ed., 2020, 59, 22697–22705 CrossRef CAS PubMed.
- N. A. Mazlan, A. Lewis, F. S. Butt, R. Krishnamoorthi, S. Chen and Y. Huang, Front. Chem. Sci. Eng., 2024, 18, 89 CrossRef CAS.
- J. A. Martín-Illán, D. Rodríguez-San-Miguel, O. Castillo, G. Beobide, J. Perez-Carvajal, I. Imaz, D. Maspoch and F. Zamora, Angew. Chem., Int. Ed., 2021, 60, 13969–13977 CrossRef.
- S.-C. Li, B.-C. Hu, Y.-W. Ding, H.-W. Liang, C. Li, Z.-Y. Yu, Z.-Y. Wu, W.-S. Chen and S.-H. Yu, Angew. Chem., Int. Ed., 2018, 57, 7085–7090 CrossRef CAS.
- B.-C. Hu, H.-R. Zhang, S.-C. Li, W.-S. Chen, Z.-Y. Wu, H.-W. Liang, H.-P. Yu and S.-H. Yu, Adv. Funct. Mater., 2023, 33, 2207532 CrossRef CAS.
- C. Ziegler, A. Wolf, W. Liu, A.-K. Herrmann, N. Gaponik and A. Eychmüller, Angew. Chem., Int. Ed., 2017, 56, 13200–13221 CrossRef CAS PubMed.
- X. Li, Z. Jia, J. Zhang, Y. Zou, B. Jiang, Y. Zhang, K. Shu, N. Liu, Y. Li and L. Ma, Chem. Mater., 2022, 34, 11062–11071 CrossRef CAS.
- D. Zhu, Y. Zhu, Q. Yan, M. Barnes, F. Liu, P. Yu, C.-P. Tseng, N. Tjahjono, P.-C. Huang, M. M. Rahman, E. Egap, P. M. Ajayan and R. Verduzco, Chem. Mater., 2021, 33, 4216–4224 CrossRef CAS.
- H. Fan, J. Gu, H. Meng, A. Knebel and J. Caro, Angew. Chem., Int. Ed., 2018, 57, 4083–4087 CrossRef CAS.
- K. Wang, H. Yang, Z. Liao, S. Li, M. Hambsch, G. Fu, S. C. B. Mannsfeld, Q. Sun and T. Zhang, J. Am. Chem. Soc., 2023, 145, 5203–5210 CrossRef CAS.
- Y. Chen, S. Li, X. Pei, J. Zhou, X. Feng, S. Zhang, Y. Cheng, H. Li, R. Han and B. Wang, Angew. Chem., Int. Ed., 2016, 55, 3419–3423 CrossRef CAS PubMed.
- W.-R. Cui, C.-R. Zhang, R.-P. Liang and J.-D. Qiu, J. Mater. Chem. A, 2021, 9, 25611–25620 RSC.
- W.-R. Cui, C.-R. Zhang, R.-P. Liang, J. Liu and J.-D. Qiu, ACS Appl. Mater. Interfaces, 2021, 13, 31561–31568 CrossRef CAS PubMed.
- Y. Zhang, S. Yuan, X. Feng, H. Li, J. Zhou and B. Wang, J. Am. Chem. Soc., 2016, 138, 5785–5788 CrossRef CAS PubMed.
- S. Zhao, G. Siqueira, S. Drdova, D. Norris, C. Ubert, A. Bonnin, S. Galmarini, M. Ganobjak, Z. Pan, S. Brunner, G. Nyström, J. Wang, M. M. Koebel and W. J. Malfait, Nature, 2020, 584, 387–392 CrossRef CAS PubMed.
- J. Wang, D. Yuan, P. Hu, Y. Wang, J. Wang and Q. Li, Adv. Funct. Mater., 2023, 33, 2300441 CrossRef CAS.
- A. Acharjya, P. Pachfule, J. Roeser, F.-J. Schmitt and A. Thomas, Angew. Chem., Int. Ed., 2019, 58, 14865–14870 CrossRef CAS PubMed.
- Y. Yamashita, T. Yasukawa, W.-J. Yoo, T. Kitanosono and S. Kobayashi, Chem. Soc. Rev., 2018, 47, 4388–4480 RSC.
- C.-P. Niu, C.-R. Zhang, X. Liu, R.-P. Liang and J.-D. Qiu, Nat. Commun., 2023, 14, 4420 CrossRef CAS.
- S. Li, R. Ma, S. Xu, T. Zheng, G. Fu, Y. Wu, Z. Liao, Y. Kuang, Y. Hou, D. Wang, P. S. Petkov, K. Simeonova, X. Feng, L.-Z. Wu, X.-B. Li and T. Zhang, J. Am. Chem. Soc., 2022, 144, 13953–13960 CrossRef CAS.
- G. Fu, D. Yang, S. Xu, S. Li, Y. Zhao, H. Yang, D. Wu, P. S. Petkov, Z.-A. Lan, X. Wang and T. Zhang, J. Am. Chem. Soc., 2024, 146, 1318–1325 CrossRef CAS.
- W.-R. Cui, F.-F. Li, R.-H. Xu, C.-R. Zhang, X.-R. Chen, R.-H. Yan, R.-P. Liang and J.-D. Qiu, Angew. Chem., Int. Ed., 2020, 132, 17837–17843 CrossRef.
- J. Xu, C. Yang, S. Bi, W. Wang, Y. He, D. Wu, Q. Liang, X. Wang and F. Zhang, Angew. Chem., Int. Ed., 2020, 59, 23845–23853 CrossRef CAS PubMed.
- T. Li, J. Xiong, M. Chen, Q. Shi, X. Li, Y. Jiang, Y. Feng and B. Zhang, Front. Chem. Sci. Eng., 2024, 18, 3 CrossRef CAS.
- Y. Zhang, W. Lv, F. Wang, X. Niu, G. Wang, X. Wu, X. Zhang and X. Chen, Front. Chem. Sci. Eng., 2023, 17, 548–556 CrossRef CAS.
- S. Li, R. Ma, S. Xu, T. Zheng, H. Wang, G. Fu, H. Yang, Y. Hou, Z. Liao, B. Wu, X. Feng, L.-Z. Wu, X.-B. Li and T. Zhang, ACS Catal., 2023, 13, 1089–1096 CrossRef CAS.
- W.-R. Cui, C.-R. Zhang, R.-H. Xu, X.-R. Chen, W. Jiang, Y.-J. Li, R.-P. Liang, L. Zhang and J.-D. Qiu, Appl. Catal., B, 2021, 294, 120250 CrossRef CAS.
- G. Fu, H. Yang, W. Zhao, P. Samorì and T. Zhang, Adv. Mater., 2024, 2311541 CrossRef CAS PubMed.
- L. Liang, Y. Zhao, W. Zhang, H. Yan, M. Chen, Y. Chen, J. Zhou and T. Zhang, Chem. Eng. J., 2024, 496, 153894 CrossRef CAS.
- E. Jin, Z. Lan, Q. Jiang, K. Geng, G. Li, X. Wang and D. Jiang, Chem, 2019, 5, 1632–1647 CAS.
- C. Li, S. Cao, J. Lutzki, J. Yang, T. Konegger, F. Kleitz and A. Thomas, J. Am. Chem. Soc., 2022, 144, 3083–3090 CrossRef CAS PubMed.
- X. Kong, Z. Wu, M. Strømme and C. Xu, J. Am. Chem. Soc., 2024, 146, 742–751 CrossRef CAS PubMed.
- T. Li, X. Lin, Z. Zhang, L. Yang, Y. Qian, L. Fu, S. Zhou, W. Chen, Q. Wang, X. Li, X.-Y. Kong, H. Xiao, L. Jiang and L. Wen, Adv. Funct. Mater., 2023, 33, 2212819 CrossRef CAS.
Footnotes |
† Electronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d4mh01055h |
‡ This work is dedicated to the 20th anniversary of the Ningbo Institute of Materials Technology and Engineering (NIMTE). Y. Chen and G. Fu contributed equally to this work. |
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