Why is impostant to study the effect of moisture uptake on glass transition temperature of fiber reinforcement polymer?
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Studying the effect of moisture uptake on the glass transition temperature (GTT) of fiber-reinforced polymers (FRPs) is crucial due to its impact on the structural integrity and long-term durability of composite materials. Moisture absorption can lead to changes in the GTT, affecting the mechanical properties and performance of FRPs over time . The absorbed moisture can influence the matrix properties, causing degradation in the material's strength and potentially leading to interphase damage and cracking . Understanding how moisture affects the GTT is essential for predicting the material's behavior under different environmental conditions, such as temperature variations and exposure to fluids, enabling the development of more reliable composite structures .
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| Papers (5) | Insight |
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| Studying moisture uptake's impact on glass transition temperature in fiber-reinforced polymers is crucial for assessing material durability and performance under varying environmental conditions, aiding in material selection and design. | |
| Studying moisture uptake's impact on glass transition temperature is crucial as it affects mechanical properties, durability, and performance of fiber-reinforced polymer composites, aiding in material optimization and application reliability. | |
5 Citations | Studying moisture uptake is crucial as absorbed moisture can significantly impact the mechanical properties, including the glass transition temperature, of fiber-reinforced polymer composites, affecting their long-term structural integrity. |
22 Sep 2021 1 Citations | Studying moisture uptake's impact on glass transition temperature helps understand structural changes in polymer composites, aiding in developing more reliable and durable materials for various applications. |
24 Oct 2020 2 Citations | Studying moisture impact on glass transition temperature in fiber reinforced polymers is crucial for assessing durability under maritime conditions, aiding in material selection for long-term performance in such environments. |
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