# The Impact of Destructive Climatic Factors on the Mechanical and Performance Properties of Structural Materials

**Authors:** Paweł Widomski, Przemysław Maksymowicz, Oliwia Trzaska, Paulina Mayer-Trzaskowska, Paweł Kaczyński, Anna Berbesz-Wyrodek, Barbara Gronostajska, Waldemar Bober, Michał Kogut

PMC · DOI: 10.3390/ma18132970 · 2025-06-23

## TL;DR

This study examines how extreme weather conditions affect the durability and performance of structural materials like polymers and metals.

## Contribution

The research introduces a comprehensive testing framework combining mechanical and environmental stressors to evaluate material resilience.

## Key findings

- Polymers like laser-extruded plexiglass and polycarbonate showed good resistance to aging.
- High-impact polystyrene experienced significant deformation and hardness loss after UV exposure.
- Aluminum and stainless steel retained their properties after 12 months of accelerated aging, unlike galvanized steel.

## Abstract

This study investigates the effects of destructive climatic factors on the mechanical and performance properties of various structural materials, encompassing both polymers and metals. Over recent decades, the growing adoption of synthetic polymers has revolutionized engineering applications, yet their susceptibility to environmental degradation poses significant challenges. This research emphasizes the need for comprehensive testing under both operational and environmental stressors, including extreme temperatures, UV radiation, and moisture, to assess material durability and performance. Mechanical tests were conducted at ambient (25 °C) and low temperatures (−50 °C) to evaluate the strength and strain responses of selected materials. Additionally, a 12-month accelerated aging process using UV radiation and elevated temperatures was performed to simulate long-term environmental exposure. Parameters such as Shore D hardness, gloss, and mass were measured at regular intervals to quantify material degradation. The results revealed significant differences in performance across material types. Among polymers, laser-extruded and milky plexiglass, as well as solid polycarbonate, exhibited satisfactory resistance to aging, with minimal changes in mechanical properties. However, high-impact polystyrene displayed substantial deformation and hardness loss after prolonged UV exposure. For metals, aluminum and stainless steel (304 and 316) demonstrated exceptional durability, retaining structural and aesthetic properties after 12 months of accelerated aging, whereas galvanized steel exhibited pronounced corrosion. The study highlights the critical interplay between mechanical loading and environmental factors, stressing the importance of material selection tailored to specific climatic conditions. It further underscores the value of integrating experimental findings with predictive models, such as finite element analysis, to enhance the design and longevity of engineering materials. The findings provide actionable insights for industries operating in temperate climates, where materials are subjected to diverse and cyclic environmental stressors. Recommendations are offered for selecting resilient materials suitable for protective housings and structural components.

## Full-text entities

- **Chemicals:** aluminum (MESH:D000535), steel (MESH:D013232), polymers (MESH:D011108), stainless steel (MESH:D013193), polystyrene (MESH:D011137)

## Figures

17 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12250640/full.md

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Source: https://tomesphere.com/paper/PMC12250640