Self-Healing Coatings Containing Core–Shell Nanofibers with pH-Responsive Performance

Wang, Qi; Wang, Wei; Ji, Xiaohong; Hao, Xiangping; Ma, Chengcheng; Wei, Hao; Li, Xinglinmao; Chen, Shougang

doi:10.1021/acsami.0c18933

Cited by 71 publications

(30 citation statements)

References 45 publications

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“…Most of the self‐healing coatings researched at present rely on local ultraviolet radiation or heating to complete the self‐healing. [ 48–51 ] Making rapid self‐healing coatings without external energy is still a challenge. Moreover, coating materials often face many complex environments, which require coating materials to have certain reliable mechanical properties.…”

Section: Resultsmentioning

confidence: 99%

Main‐Side Chain Hydrogen Bonding‐Based Self‐Healable Polyurethane with Highly Stretchable, Excellent Mechanical Properties for Self‐Healing Acid–Base Resistant Coating

et al. 2021

Macromol. Rapid Commun.

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Developing an autonomous self‐healing polyurethane (PU) elastomer with excellent mechanical properties and high ductility has attracted increasing attention. Nowadays, the synthesis of elastomers with excellent mechanical properties and rapid self‐healing at room temperature faces a huge challenge. Herein, This work reports a new supramolecular PU with excellent mechanical properties and rapid self‐healing at room temperature through the introduction of T‐type chain extender into the supramolecular polymer chain. The introduction of T‐chain extender can be used to enhance the mechanical strength of PU, and the multiple hydrogen bonds on the side‐chain provide theoretical support for the rapid self‐healing ability of PU. Maximum stress of the synthesized PU can reach 3.4 ± 0.15 Mpa, and maximum elongation at break can reach 3200% ± 160%. Due to flexibility and re‐constructability of side‐chain hydrogen bonds, PU stress repair efficiency can reach 96.7%, and can be self‐healing scratches rapidly and effectively at room temperature. The mechanical properties and self‐healing properties of PU can be adjusted by the content of T‐type chain extender. The PU is applied to the metal surface coating, which has excellent acid–base resistance, bond strength up to 2.9 ± 0.1 Mpa, and the ability to eliminate local damage on the coating surface quickly at room temperature.

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Section: Resultsmentioning

confidence: 99%

Main‐Side Chain Hydrogen Bonding‐Based Self‐Healable Polyurethane with Highly Stretchable, Excellent Mechanical Properties for Self‐Healing Acid–Base Resistant Coating

et al. 2021

Macromol. Rapid Commun.

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“…In Figure 6, R s is the solution resistance, and R c and CPE -1 represent the coating resistance and coating capacitance, respectively. R ct and CPE -2 represent the charge-transfer resistance and double-layer capacitance, respectively (Wang et al, 2021;Cui et al, 2018). Figure 8A was used to fit the EIS data for PA/G/EP during the 96-h immersion, and Figure 8B was used to fit the EIS data which have two time constants (Pan et al, 2020).…”

Section: Corrosion Performance Of the G Modified Epoxy Surface Tolerant Coatingmentioning

confidence: 99%

Corrosion Performance and Rust Conversion Mechanism of Graphene Modified Epoxy Surface Tolerant Coating

Guo

et al. 2021

Front. Mater.

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A graphene modified epoxy surface tolerant coating was prepared, and the corrosion performance and rust conversion mechanism of the prepared composite coating on rusty carbon steel substrate was investigated. Scanning electron microscope (SEM), X-ray powder diffractometer (XRD), and infrared (IR) spectrum were used to confirmed the iron rust conversion performance by the reaction of phytic acid and rust. electrochemical impedance spectroscopy (EIS), polarization curve, and salt spray test were used to evaluate the corrosion resistance of low surface treatment coatings. Results indicated most of the rust were dissolved and transformed with the reaction of phytic acid and rust on the rusty carbon steel; graphene could effectively improve the compactness and protective performance of the epoxy surface tolerant coating.

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“…Due to their ability to be ionized in an aqueous environment, applications using polyelectrolytes can be found across many disciplines, such as in medicine, mineral separation, paints, food industry, corrosion inhibition, water purification and filtration, or cosmetics. [10,13,[22][23][24][25][26][27] In the past decades, the design of pH-responsive biomedical systems has been the focus of many research groups as for example shown by responsive lipid or polymeric nanoparticles using ionizable polymers. [28][29][30][31][32][33] This is attributable to the wide range of pH-differences found within the human body and the numerous pathological conditions inducing pH changes occuring for example in tumors, due to inflammation or during the wound healing process.…”

Section: Introductionmentioning

confidence: 99%

pH-Responsive Electrospun Nanofibers and Their Applications

et al. 2021

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Electrospun nanofibrous membranes offer superior properties over other polymeric membranes not only due to their high membrane porosity but also due to their high surface-to-volume ratio. A plethora of available polymers and post-modification methods allow the incorporation of "smart" responsiveness in fiber membranes. The pHresponsive property is achieved using polymers from the class of polyelectrolytes, which contain pH-dependent functional groups on their polymeric backbone. Electrospinning macroscopic membranes using polyelectrolytes earned considerable interest for biomedical and environmental applications due to the possibility to trigger chemical and physical changes of the membrane (swelling, wettability, degradation) in response to environmental pH-changes. Here, we review recent advancements in the field of electrospinning of pHresponsive nanofiber materials. Starting with the chemical background of pH-responsive polymers at the molecular level, we highlight the material-property transformation upon pH-change at the macroscopic membrane level and, finally, we provide an overview of recent applications of pH-responsive fiber membranes.

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Self-Healing Coatings Containing Core–Shell Nanofibers with pH-Responsive Performance

Cited by 71 publications

References 45 publications

Main‐Side Chain Hydrogen Bonding‐Based Self‐Healable Polyurethane with Highly Stretchable, Excellent Mechanical Properties for Self‐Healing Acid–Base Resistant Coating

Main‐Side Chain Hydrogen Bonding‐Based Self‐Healable Polyurethane with Highly Stretchable, Excellent Mechanical Properties for Self‐Healing Acid–Base Resistant Coating

Corrosion Performance and Rust Conversion Mechanism of Graphene Modified Epoxy Surface Tolerant Coating

pH-Responsive Electrospun Nanofibers and Their Applications

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