ABS Nanocomposites for Advanced Technical and Biomedical Applications
Yazarlar (9)
Lubomír Lapčík
Palacký University Olomouc, Çek Cumhuriyeti
Martin Vašina
Tomas Bata University İn Zlin, Çek Cumhuriyeti
Yousef Murtaja
Tomas Bata University İn Zlin, Çek Cumhuriyeti
Harun Sepetçioğlu
Selçuk Üniversitesi, Türkiye
Barbora Lapčíková
Palacký University Olomouc, Çek Cumhuriyeti
Martin Ovsík
Tomas Bata University İn Zlin, Çek Cumhuriyeti
Michal Staněk
Tomas Bata University İn Zlin, Çek Cumhuriyeti
Doç. Dr. İdris KARAGÖZ
Yalova Üniversitesi, Türkiye
Apurva Shahaji Vadanagekar
Palacký University Olomouc, Çek Cumhuriyeti
| Makale Türü |
Özgün Makale
(SSCI, AHCI, SCI, SCI-Exp dergilerinde yayınlanan tam makale)
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| Dergi Adı | Polymers (Q1) | ||
| Dergi ISSN | 2073-4360 Wos Dergi Scopus Dergi | ||
| Dergi Tarandığı Indeksler | SCI-Expanded | ||
| Makale Dili | İngilizce | Basım Tarihi | 03-2025 |
| Cilt / Sayı / Sayfa | 17 / 7 / 909–0 | DOI | 10.3390/polym17070909 |
| Makale Linki | https://doi.org/10.3390/polym17070909 | ||
| Özet |
| This study investigated the mechanical, thermal, and morphological properties of acrylonitrile butadiene styrene (ABS)-based nanocomposites reinforced with different types and concentrations of nanofillers. The uniaxial tensile testing results indicated that Young's modulus () generally decreased with increasing filler content, except at 0.500 w.% filler concentration, where a slight increase in stiffness was observed. A statistically significant interaction between sample type and filler concentration was identified ( = 0.045). Fracture toughness measurements revealed a significant reduction in impact resistance at 1.000 w.% filler concentration, with values dropping by up to 67% compared with neat acrylonitrile butadiene styrene. Dynamic mechanical vibration testing confirmed a decrease in stiffness, as evidenced by a shift of the first resonance frequency () to lower values. Hardness measurements including indentation and Shore D hardness exhibited an increasing trend with rising filler concentration, with statistically significant differences observed at specific concentration levels ( < 0.05). Scanning electron microscopy analysis showed that nanofillers were well dispersed at lower concentrations, but agglomeration began above 0.500 w.%, resulting in void formation and a noticeable decline in mechanical properties. The results suggest that an optimal filler concentration range of 0.250-0.500 w.% offers an ideal balance between enhanced mechanical properties and material integrity. |
| Anahtar Kelimeler |
| nanocellulose | halloysite | calcium carbonate | ABS polymer | mechanical testing |
BM Sürdürülebilir Kalkınma Amaçları
| Atıf Sayıları | |
| WoS | 2 |
| SCOPUS | 3 |
| Google Scholar | 2 |