Development of hydrophobic polyurethane film from structurally modified castor oil and its anticorrosive performance

Mohanty, Sudhanya; Borah, Kashmiri; Kashyap, Siddhartha Shankar; Sarmah, Sanjib; Bera, Manas Kumar; Basak, Pratyay; Narayan, Ramanuj

doi:10.1002/pat.5892

Cited by 5 publications

(7 citation statements)

References 58 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the case of the ACO-DA-0.90 film, the presence of more amine content exerts a plasticizing effect that mitigates the rigidity of the film, which is reflected by the lower storage modulus of ACO-DA-0.90. The presence of more amine might remain as a pendant group or act as a spacer between the cross-linked network that disrupts the interchain interaction and plasticizes the CAN network. , As shown in Figure a, a drop in the storage modulus was observed in both the CAN films when the temperature was gradually increased to T α . The T α values for ACO-DA-0.75 and ACO-DA-0.90 were found to be reliable and comparable with the observed DSC analysis data.…”

Section: Resultsmentioning

confidence: 99%

Fully Biobased Self-Healing and Recyclable Covalent Adaptable Networks Prepared via a Catalyst-Free Aza-Michael Reaction

Kashyap,

Borah,

Shivam Shailesh Kumar

et al. 2024

ACS Appl. Polym. Mater.

Self Cite

View full text Add to dashboard Cite

In the present scenario, petroleum resource-based thermoset materials have become an environmental threat due to their permanent cross-linked structure that limits their recyclability. To overcome this problem, the development of covalent adaptable networks (CANs) containing dynamic covalent bonds has emerged in recent years that can be recycled under suitable conditions. However, the development of fully biobased as well as recyclable CANs following a green synthetic protocol is yet a great challenge and a dream toward a sustainable environment. With this goal, here, we report the development of fully biobased CAN films from acrylated castor oil (a low-cost vegetable oil derivative) and cystamine (a biobased diamine) via a catalyst-free aza-Michael reaction using disulfide linkage as the dynamic covalent bond. The CAN films show excellent thermoself-healing behavior and recyclability for at least 10 cycles while maintaining their material properties. In addition, the CAN films can be catalytically degraded, which can be further reprocessed to reconstruct the films. Furthermore, the CAN films are hydrophobic in nature, indicating that these biobased recyclable CAN films are useful for protective surface coating applications. Therefore, as a proof of concept, we further demonstrate the anticorrosive properties of a film having a maximum water contact angle of 102.4°, analyzed by a polarization method, electrochemical impedance, and a salt spray fog test under a corrosive environment. This work provides an economical as well as environmentally friendly route to develop multifunctional materials for a sustainable future.

show abstract

Section: Resultsmentioning

confidence: 99%

Fully Biobased Self-Healing and Recyclable Covalent Adaptable Networks Prepared via a Catalyst-Free Aza-Michael Reaction

Kashyap,

Borah,

Shivam Shailesh Kumar

et al. 2024

ACS Appl. Polym. Mater.

Self Cite

View full text Add to dashboard Cite

show abstract

“…The Nyquist plots for COPU (Figure S4b), MoS5-COPU-0.5 (Figure 6f), MoS5-COPU-1 (Figure 6j), and MoS5-COPU-2 (Figure S5b) show that the anticorrosive performance of the prepared coating is judged from the lower frequency region of the impedance modulus. 7 All the plots of COPU, MoS5-COPU-0.5, MoS5-COPU-1, and MoS5-COPU-2 show only one time constant, which indicates that corrosion is still in the way of electron transfer. The EIS data is fitted with an equivalent circuit containing one time constant, and the fitted data are displayed in Table 3, where R ct represents the charge transfer resistance, R s represents the solution resistance, and Q represents the coating capacitance (inset in Figure 6b).…”

Section: Anticorrosive Performancementioning

confidence: 97%

“…13−15 Additionally, the presence of hydroxyl functionality in the castor oil makes it a suitable bio-based polyol resin that can commonly be used as a precursor for the synthesis of polyurethanes. 7 Further, with the advancement of new chemical technologies for the uplift of new materials, integration of inorganic moieties into the organic polymer matrix emerged as a new area of research. 16 This approach allows the usage of both the components in their distinctive ways; the organic part provides flexibility and improves compatibility with the polymer segment while the inorganic content provides thermal, mechanical, and structural stability in addition to high ductility and superior adhesion to the metal substrate.…”

Section: Introductionmentioning

confidence: 99%

Role of Silicoaluminophosphate as a Corrosion Inhibiting Nanocontainer and Filler in Environmentally Benign Bio-Based Hybrid Coatings

Kashyap,

Borah,

Shailesh Kumar

et al. 2024

ACS Sustainable Resour. Manage.

Self Cite

View full text Add to dashboard Cite

Zeolites, renowned for their versatile properties, have emerged as highly promising materials across a spectrum of applications. Coupled with their remarkable thermal and chemical stabilities, these properties broaden the horizons of zeolite applications across various industrial sectors. Their multifaceted functionality positioned them as optimal materials for filler incorporation in paints and coatings technology, offering both ecological soundness and economic viability. Moreover, in pursuit of sustainability, the selection of a bio-based polymer matrix for embedding the filler is essential. This strategic choice not only mitigates volatile organic compounds (VOCs) and toxicity but also underscores a concerted effort toward eco-conscious practices. Herein, we report the development of the bio-based hybrid coatings containing a microporous zeolite material with a one dimensional channels system (i.e., SAPO-5) as the filler and nanocontainer for an anticorrosive agent (Mo). The material (Mo-SAPO-5) was prepared through hydrothermal synthesis and ex situ modification with molybdenum. Before incorporation into the coating formulations, it was characterized via a combination of various spectroscopic and analytic techniques including powder XRD, FT-IR, and N2 sorption. Subsequently, the Mo-SAPO-5 nanocontainer system was incorporated into a castor-oil-based polyurethane matrix as a filler with variable weight ratios (up to 2 wt %). The physicochemical, mechanical, and thermal properties of the free-standing PU films were thoroughly examined through a standard protocol involving FT-IR-ATR, XRD, TGA, DSC, DMTA, and UTM. Finally, the hybrid PU films were cast on a mild steel substrate and were subjected to a corrosion inhibition study by potentiodynamic polarization (PDP), electrochemical impedance spectroscopy (EIS) techniques, and a salt spray fog test. The studies revealed that out of all the compositions prepared, the MoS5-COPU-0.5 films (with 0.5 wt % filler) exhibited a promising anticorrosive property with the highest corrosion inhibition (C R ≈ 5.77 × 10–6 mm/year), charge transfer resistance (R ct ≈ 1.33 × 107 Ω), and phase angle (θ > 80°).

show abstract

“…Up to now, FPU with targeted performance can be synthesized precisely by designing fluorochemicals including fluorinated isocyanates, fluorinated capping agents, and fluorinated chain extenders as hard segments; fluorinated polyester polyols and fluorinated polyether polyols as soft segments; and fluorinated acrylate as additives. The methods of introducing fluorinated chain segments and their corresponding product characterization are shown in Table 3 [44][45][46]. Although typical PU has a high mechanical strength, high elastic modulus, and high abrasion resistance, the enrichment of polar groups (hydrophilics) on its surface leads to poor weather resistance as well as humidity and heat resistance, which limit its applicational range.…”

Section: Design and Synthesis Of Fpumentioning

confidence: 99%

Section: Design and Synthesis Of Fpumentioning

confidence: 99%

Synthesis, Structure, Properties, and Applications of Fluorinated Polyurethane

Li,

Yu,

et al. 2024

Polymers

View full text Add to dashboard Cite

Fluorinated polyurethane (FPU) is a new kind of polyurethane (PU) material with great applicational potential, which is attributed to its high bond energy C-F bonds. Its unique low surface energy, excellent thermal stability, and chemical stability have attracted considerable research attention. FPU with targeted performance can be precisely synthesized through designing fluorochemicals as hard segments, soft segments, or additives and changes to the production process to satisfy the needs of coatings, clothing textiles, and the aerospace and biomedical industries for materials that are hydrophobic and that are resistant to weathering, heat, and flames and that have good biocompatibility. Here, the synthesis, structure, properties, and applications of FPU are comprehensively reviewed. The aims of this research are to shed light on the design scheme, synthesis method, structure, and properties of FPU synthesized from different kinds of fluorochemicals and their applications in different fields and the prospects for the future development of FPU.

show abstract

Development of hydrophobic polyurethane film from structurally modified castor oil and its anticorrosive performance

Cited by 5 publications

References 58 publications

Fully Biobased Self-Healing and Recyclable Covalent Adaptable Networks Prepared via a Catalyst-Free Aza-Michael Reaction

Fully Biobased Self-Healing and Recyclable Covalent Adaptable Networks Prepared via a Catalyst-Free Aza-Michael Reaction

Role of Silicoaluminophosphate as a Corrosion Inhibiting Nanocontainer and Filler in Environmentally Benign Bio-Based Hybrid Coatings

Synthesis, Structure, Properties, and Applications of Fluorinated Polyurethane

Contact Info

Product

Resources

About