Metal Complexes of the Porphyrin-Functionalized Polybenzoxazine

Zhang, Guohu; EL‐Mahdy, Ahmed F. M.; Ahmed, Lamiaa Reda; Matsagar, Babasaheb M.; Al-Saeedi, Sameerah I.; Kuo, Shiao‐Wei; Wu, Kevin C.‐W.

doi:10.3390/polym14030449

Cited by 9 publications

(10 citation statements)

References 63 publications

(71 reference statements)

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“…The FT-IR spectra show that the peaks of the porphyrin skeleton are located at 1598, 1354, and 798 cm –1 , and the peaks at 3354 and 3440 cm –1 are absorption bands of NH 2 units (Figure b) . For Co-TAP, the peak related to N–H in-plane bending vibration at 959 cm –1 disappears, and a new signal at 991 cm –1 appears, confirming the incorporation of Co ions into the center of the macrocycle . This evidence persuasively proved the incorporation of cobalt ions into the porphyrin structures and the successful synthesis of the desired structures.…”

mentioning

confidence: 67%

“…Compared with the TAPP, the maximum absorption of Co-TAP at 444 nm presents a slightly red shift of 16 nm. Additionally, when porphyrinic macrocycle is coordinated with Co ions, the Q band pattern is simplified to two Q bands at around 555 and 605 nm, which is attributable to the more symmetrical environment . The FT-IR spectra show that the peaks of the porphyrin skeleton are located at 1598, 1354, and 798 cm –1 , and the peaks at 3354 and 3440 cm –1 are absorption bands of NH 2 units (Figure b) .…”

mentioning

confidence: 97%

“…Additionally, when porphyrinic macrocycle is coordinated with Co ions, the Q band pattern is simplified to two Q bands at around 555 and 605 nm, which is attributable to the more symmetrical environment . The FT-IR spectra show that the peaks of the porphyrin skeleton are located at 1598, 1354, and 798 cm –1 , and the peaks at 3354 and 3440 cm –1 are absorption bands of NH 2 units (Figure b) . For Co-TAP, the peak related to N–H in-plane bending vibration at 959 cm –1 disappears, and a new signal at 991 cm –1 appears, confirming the incorporation of Co ions into the center of the macrocycle .…”

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confidence: 97%

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Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Feng

Yang

et al. 2023

J. Phys. Chem. Lett.

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Li−O 2 batteries have an extremely high theoretical specific energy; however, the large charge overpotential and highly reactive singlet oxygen ( 1 O 2 ) are two major obstacles. Porphyrin as a special kind of macrocyclic conjugated aromatic system exhibits excellent redox activity, which can be optimized by introducing a center metal atom. Herein,5,10,15,-porphyrin (TAPP) and 5,10,15,20-tetrakis(4-aminophenyl)-porphyrin-Co(II) (Co-TAP) are applied as effective redox mediators for Li−O 2 batteries. The synergistic effects of a center metal atom and organic ligand make Co-TAP more favorable for oxygen reduction and evolution. To understand the fundamental reaction mechanisms with or without TAPP or Co-TAP, the discharge/charge processes and the parasitic reactions have been comprehensively studied. The results reveal that TAPP affects the formation mechanism of Li 2 O 2 , while Co-TAP transforms the main discharge product into LiOH without adding extra water. Co-TAP-containing batteries operated via LiOH chemistry completely eradicate 1 O 2 and significantly alleviate the parasitic reactions associated with 1 O 2 .

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confidence: 67%

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confidence: 97%

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confidence: 97%

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Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Feng

Yang

et al. 2023

J. Phys. Chem. Lett.

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“…It is expected that the introduction of melamine, which has an active amino and triazine structure, can enhance the thermal stability and crosslink density of polymers 46 . Also, it was found that the introduction of Schiff‐base structure could enhance the crosslink density and stability of the resin 47–52 . As the report by Xu, 49 two diepoxides containing a two‐benzene‐ring‐conjugated Schiff base when cured with an aromatic diamine result in high‐performance thermosets.…”

Section: Introductionmentioning

confidence: 95%

Melamine as cross‐linking agent for mono‐cyclic benzoxazine with aldehyde groups: higher crosslinking density and thermal properties

Zhang,

Hou,

et al. 2023

J of Applied Polymer Sci

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Benzoxazine resin shows great potential as matrix for high performance composites, possessing good processabilty, dielectric property, mechanical property, and thermal properties, but its further application is limited by low crosslinking density and poor curing activity, especially for mono‐cyclic benzoxazines. In this work, melamine, a tertiary amine with a stable triazine structure, was introduced into the aldehyde‐containing mono‐cyclic benzoxazine, in order to achieve higher crosslinking density, higher curing activity, and better thermal properties. The chemical structure of prepolymers was verified by Fourier transform infrared spectroscopy (FTIR), 1H nuclear magnetic resonance (1H NMR) spectra, the curing behavior was investigated by differential scanning calorimetry, the thermal properties of polymers were studied by thermogravimetric analysis (TGA) and thermal mechanical analysis (TMA). It was found that the introduction of trifunctional melamine (MA) could lower curing temperature and promote the curing degree. Additionally, a proper amount of MA could increase the crosslinking density and thermal properties of the resultant polybenzoxazine. For example, poly(BZ‐3MA) showed the highest thermal stability with the temperature at 5% weight loss (Td5) of 415°C, carbon residue (Yc) of 67.7%, 23°C, and 2.9% higher than those of poly(BZ). Moreover, the glass transition temperature of poly(BZ‐5MA) reached 204.06°C, 36.51°C higher than that of poly(BZ).

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“…Its polymeric product can form through thermal ring-opening polymerization (ROP) without the need to add any potentially harmful catalysts (Scheme S1). − Holly and Cope prepared the first monofunctional BZ, 3,4-dihydro-2 H -1,3-benzoxazine, through Mannich condensation . Although the chemical structures of PBZs are similar to those of traditional phenolic resins, PBZs are generally prepared by using simple and self-catalyzed polymerization processes and display good heat resistance, high degradation and glass transition ( T g ) temperatures, near-zero volumetric shrinkage during polymerization, excellent flame retardancy, good mechanical properties, low dielectric constants, water absorption properties, and variable surface free energies. ,− In addition, high flexibility in the molecular design of BZ resins allows a variety of physical and mechanical properties to be introduced into the resulting PBZ materials. − Moreover, the properties of PBZs lead to many potential applications in, for example, adsorbents, metal capture, energy storage, gas uptake, shape-memory and self-healing polymers, anticorrosion coatings, adhesives, and electronic materials. − The syntheses and characteristics of mono-, bi-, tri-, and tetrafunctional BZs have been investigated in detail by many research groups. ,,,,,,, In general, monofunctionalized BZs tend to form linear polymers of relatively lower molecular weight, while bifunctional BZs form cross-linked macromolecules featuring more stable networks …”

Section: Introductionmentioning

confidence: 99%

Formaldehyde-Free Synthesis of Fully Bio-Based Multifunctional Bisbenzoxazine Resins from Natural Renewable Starting Materials

Mohamed

Khan

et al. 2022

Macromolecules

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Although bio-based benzoxazines (BZs) have been explored widely as sustainable thermosetting resins, few high-performance BZs have been prepared completely from natural renewable resources. In this study we synthesized a fully bio-based multifunctional bisbenzoxazine (AP-fa-BZ) in high yield and purity from apigenin (AP), furfurylamine (fa), and benzaldehyde by using both solvent and solventless approaches. Fourier transform infrared (FTIR) spectroscopy, high-resolution mass spectrometry, and one- and two-dimensional nuclear magnetic resonance spectroscopy confirmed the chemical structure of AP-fa-BZ. We then used dynamic mechanical analysis, differential scanning calorimetry (DSC), thermogravimetric analysis, and in situ FTIR spectroscopy to examine the thermal characteristics of AP-fa-BZ before and after its ring-opening polymerization (ROP). DSC revealed that the temperature required for the formation of poly(AP-fa-BZ) through ROP (236.3 °C) was significantly lower than that of a typical 4-phenyl-3,4-dihydro-2H-1,3-benzoxazine (Pa-type) monomer due to the positive catalytic effect of the phenolic OH groups in the AP structure. After thermal polymerization at 250 °C, the resulting poly(AP-fa-BZ) possessed a high thermal decomposition temperature (T d10 = 395 °C), a high char yield (52 wt %), and a high glass transition temperature (T g = 283 °C). Contact angle measurements revealed the tunable surface properties of AP-fa-BZ. Finally, the AP-fa-BZ resin functioned as an antibacterial agent against both Staphylococcus aureus and Escherichia coli.

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Metal Complexes of the Porphyrin-Functionalized Polybenzoxazine

Cited by 9 publications

References 63 publications

Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Melamine as cross‐linking agent for mono‐cyclic benzoxazine with aldehyde groups: higher crosslinking density and thermal properties

Formaldehyde-Free Synthesis of Fully Bio-Based Multifunctional Bisbenzoxazine Resins from Natural Renewable Starting Materials

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Metal Complexes of the Porphyrin-Functionalized Polybenzoxazine

Cited by 9 publications

References 63 publications

Completely Eradicating Singlet Oxygen in Li–O2 Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Completely Eradicating Singlet Oxygen in Li–O2 Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Melamine as cross‐linking agent for mono‐cyclic benzoxazine with aldehyde groups: higher crosslinking density and thermal properties

Formaldehyde-Free Synthesis of Fully Bio-Based Multifunctional Bisbenzoxazine Resins from Natural Renewable Starting Materials

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Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry

Completely Eradicating Singlet Oxygen in Li–O₂ Battery via Cobalt(II)-Porphyrin Complex-Catalyzed LiOH Chemistry