Biyo-Nanokompozitlerin Redogik Çalışmaları

Yıl 2025, Cilt: 3 Sayı: 2, 14 - 32, 31.08.2025

Elif Esra Altuner , Fatih Şen

Öz

Burada ele alınan biyopolimerlerden elde edilen nanokompozitlerin reolojik çalışmaları çeşitli çalışmalarla desteklenerek açıklanmıştır. Bu bölümde literatürde biyo nanokompozit malzemelerden elde edilen çeşitli kolloidler, karbon nanotüpler, çok duvarlı nanotüpler, misel çözeltileri ve granüler akışlar açıklanmıştır. Kolloidlerin karışık oransal rejimlere doğru kaydığı ve hacimsel etkileşimlerin daha etkili olduğu bildirilmiştir. Organik filler bağımsız açısal hıza sahiptir ve kompleks halleri katı gibi davranmıştır. Karbon nanotüplerin epoksi formları vurgulanmıştır. Trisodyum fosfat, titanyum dioksit ve nanopartiküller organik dolgularla birleştirildiğinde daha fazla sertlik veren bir yapı oluşmaktadır. Çok duvarlı karbon nanotüpler üzerinde yapılan karakterizasyonlarda bu malzemelerin yapısı incelenmiş ve redogik davranış genişletilmeye çalışılmıştır. Granüler akışların yapısında rezonans görüntülerinde bazı görüntüler zayıf iken bazılarında farklı sonuçlar elde edilmiştir. Gelecekte, bu çalışmaların genişletilmesi nanomalzemelerin reolojisinin akademik çalışmalarını daha da aydınlatacaktır.

Anahtar Kelimeler

Redogik çalışmalar , nanokompozitler , biyo-nanokompozitler

Rhedogical Studies of Bio-Nanocomposites

Öz

The rheological studies of nanocomposites obtained from biopolymers, addressed herein, have been explained with the support of various studies. Various colloids, carbon nanotubes, multi-walled nanotubes, micellar solutions, and granular flows obtained from bio nanocomposite materials are explained in the literature in this chapter. It has been reported that colloids shift towards mixed proportional regimes and volumetric interactions are more effective. Organic elephants have an independent angular velocity and their complex state behaved like a solid. Epoxy forms of carbon nanotubes are emphasized. When trisodium phosphate, titanium dioxide, and nanoparticles are combined with organic fillers, a structure that gives more hardness is formed. In the characterizations made on multi-walled carbon nanotubes, the structure of these materials was examined and the rhedogical behavior was tried to be expanded. In the structure of granular flows, some images were weak in resonance images, while different results were obtained in others. In the future, the expansion of these studies will further illuminate the academic studies of the rheology of nanomaterials

Anahtar Kelimeler

Rhedogical studies , nanocomposites , bio-nanocomposites

Kaynakça

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