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4. Improvement of mechanical and physical performance of poly (lactic acid) biocomposites by application of surface silanization for huntite–hydromagnesite mineral.

Author

Dike, Ali Sinan

Subjects
*LACTIC acid, *SILANIZATION, *PHYSICAL mobility, *X-ray spectroscopy, *INFRARED spectroscopy, *SURFACE interactions
Abstract

Silanization process was applied to huntite–hydromagnesite (HH) mineral in for improve its adhesion to poly (lactic acid) (PLA) matrix. Surfaces of HH samples were examined by infrared spectroscopy and energy-dispersive X-ray spectroscopy analysis. HH was compounded with PLA using melt-blending technique. Modified HH incorporations led to nearly 19% and 20% increase in tensile strength and modulus of PLA, respectively. The maximum improvement for tensile strength value is obtained for 15 wt% of modified HH containing composite sample. On the other hand, percentage strain of PLA decreases nearly 22% with the addition of HH. Silane-modified HH-containing composites yield higher impact energy compared to untreated HH. Impact performance of composites increases nearly 18% with the increase in loading ratio of HH. Silane-modified HH displays higher storage modulus than HH, and glass transition temperature of PLA shifts to higher levels with the inclusion of HH. HH-filled composites exhibit no significant difference with melt flow rate value of PLA. Water resistance of silane-treated HH-containing composites are found to be higher than untreated HH attribitued to hydrophobicity of silicon-rich surface. Accordingly, composites that include modified HH are suitable for outdoor applications. Morphological investigations confirm that dispersion homogeneity and strong adhesion are achieved due to the improvement of surface interactions between HH and PLA phases after silane treatment process. [ABSTRACT FROM AUTHOR]

Published
2022
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10. Preparation and Characterization of Calcite Loaded Poly (Lactic Acid) Composite Materials

Author

DİKE, Ali Sinan

Subjects
Engineering, kalsit,kompozit malzeme,poli (laktik asit),ekstrüzyon, Mühendislik, Poly (lactic acid),calcite,composite material,extrusion
Abstract

Bu çalışmada, kalsit (KS) minerali ağırlıkça %5, 10, 15 ve 20konsantrasyonlarında poli (laktik asit) (PLA) ile ekstrüzyon işlemikullanılarak karıştırılmıştır. PLA ve kompozitlerin test numuneleri enjeksiyonkalıplama ile hazırlanmıştır. Kompozitlerin karakterizasyonları, çekme, sertlikve darbe testlerini içeren mekanik testler, erime akış hızı testi (MFR) ile akışdavranışı ve taramalı elektron mikroskopi (SEM) yöntemi ile morfolojik çalışmalarbaz alınarak yapılmıştır. Mekanik test sonuçları, çekme dayanım ve modülde enyüksek artışa %10 KS eklenmiş kompozitte saptandığını göstermiştir. Daha fazlaKS eklenmesi çekme dayanımında belirgin düşüşe neden olmuştur. PLA’nın darbedayanımı KS eklenmesi ile azalmıştır. Kompozitler arasında en yüksek darbeenerjisi PLA-15 KS numunesinde bulunmuştur. Eklentisiz PLA’nın sertliği KSeklemelerinden sonra artmıştır. Eklentisiz PLA’ya kıyasla, KS takviyeli PLAbiraz yüksek MFR değerleri vermiştir. Kompozitlerin SEM mikro-resimlerigöstermiştir ki; KS parçacıkları düşük ekleme oranlarında PLA matrisi içindehomojen şekilde dağılmıştır. KS yüksek konsantrasyonlarda parçacık-parçacıketkileşimlerini tercih ettiğinden büyük aglomeratlar ve zayıf dağılımgözlenmiştir. Bu sonuçlara göre, %10 ve %15 konsantrasyonları kalsit içeren PLAkompozitleri için uygun olarak belirlenmiştir., In this work, calcite (KS) mineral was compounded with poly (lacticacid) (PLA) at the concentrations of 5, 10, 15 and 20 wt% using extrusionprocess. Test samples of PLA and composites were prepared by injection molding.Characterizationof composites were done based on mechanical tests including tensile, hardnessand impact tests, flow behavior by melt flow rate test (MFR) and morphologicalstudies by scanning electron microscopy (SEM) method.[A1] Mechanical test results showed thatthe highest improvements in tensile strength and tensile modulus values wereobtained for 10 wt% of KS filled composite. Further addition of KS causedremarkable decrease in tensile strength. Impact strength of PLA reduced by KSadditions. The highest impact energy value was found in PLA-15 KS sample amongcomposites. Hardness of neat PLA increased after KS inclusions. KS loaded PLAgave slightly higher MFR values compared to neat PLA. SEM micro-images ofcomposites implied that KS particles dispersed homogeneously in PLA matrix attheir lower loading ratio. Large agglomerates and poor dispersion were obtainedfor higher concentrations of KS since they favor particle-particle interactions.According to these results, concentrations of 10wt% and 15wt% were determinedas suitable for calcite containing PLA composites. [A1]Bucümleyi yeniden yazabilir misiniz? Biraz karışık olmuş. Konuyu bilmeyen biriokuduğunda sertlik, çekme ve darbe testlerinin mekanik olduğunu bilmeyebilir.Bunu ayrı cümlelerde yazarsanız daha iyi olur.

Published
2019

14. Improvement of organoclay dispersion into polystyrene-based nanocomposites by incorporation of SBS and maleic anhydride-grafted SBS.

Author

Dike, Ali Sinan and Yilmazer, Ulku

Subjects
*ORGANOCLAY, *IMPACT strength, *THERMOPLASTIC elastomers, *COMPATIBILIZERS, *GLASS transition temperature, *MALEIC anhydride, *INJECTION molding
Abstract

In this study, organoclay-containing polystyrene (PS)-based nanocomposites were fabricated by extrusion in the presence of thermoplastic elastomer modifiers. Styrene–butadiene–styrene (SBS) rubber was used as the elastomeric compatibilizer and maleic anhydride (MA) was grafted onto SBS rubber at different ratios. Grafting was made via melt blending. Cloisite® 30B was used as the organoclay and it was added to PS and PS/SBS blends using a corotating twin-screw extruder, followed by injection molding. Clay loading was kept constant as 2 wt%, and the elastomer content was varied between 0 and 40 wt% throughout the study. MA grafted SBS enhanced the intercalation/exfoliation of clay layers resulting in higher tensile strength, modulus, elongation at break, and impact strength with respect to neat PS. Composites containing 15 wt% MA grafted SBS displayed the optimum average domain size resulting in the high impact strength without deteriorating the tensile strength and modulus values. Elastomer addition increased the glass transition temperature of the samples due to branching or cross-linking during extrusion. PS and PS/SBS exhibited similar melt flow index values with their organoclay-containing composites. MA acted as a plasticizer and decreased viscosity. Scanning electron microscopy study indicated that dispersion of clay layers was observed at the PS-SBS interphase and also in the elastomer phase. Intercalated and exfoliated structures of organoclay layers were confirmed by X-ray diffraction and transmission electron microscopy analyses. [ABSTRACT FROM AUTHOR]

Published
2020
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15. Improvement of mechanical and physical properties of carbon fiber-reinforced polyamide composites by applying different surface coatings for short carbon fiber.

Author

Dike, Ali Sinan

Subjects
*POLYAMIDES, *SURFACE coatings, *FIBROUS composites, *CARBON fiber-reinforced plastics, *DYNAMIC mechanical analysis, *GLASS transition temperature, *SCANNING electron microscopy
Abstract

In this study, short carbon fiber (CF) surface was coated with jeffamine, isocyanate, and polyamide (PA). Surface-coated layers of CF samples were confirmed by infrared spectroscopy. Desized and coated CFs were incorporated to PA6 by melt-compounding method with a constant ratio of 20 wt%. Tensile testing, shore hardness, dynamic mechanical analysis (DMA), and melt flow rate (MFR) test of composites were performed. Adhesion of CF to the polymer matrix was investigated by scanning electron microscopy (SEM) of composites. Mechanical characterization of composites implied that tensile strength, tensile modulus, percent elongation, and shore hardness of unfilled PA were extended to higher values by the addition of surface-coated CFs. The highest improvement was observed for isocyanate-modified CF-loaded PA-based composites. According to DMA results, storage modulus and loss modulus of PA increased with the incorporation of sized CF into polymer matrix. CF containing composites showed higher glass transition temperature with respect to unfilled PA. Addition of CF caused no significant change for MFR of PA. Poor adhesion of desized CF and relatively strong adhesion of surface-coated CFs to PA matrix were confirmed by SEM analysis. [ABSTRACT FROM AUTHOR]

Published
2020
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16. Effects of concentration and surface silanization of barite on the mechanical and physical properties of poly(lactic acid)/barite composites.

Author

Hatipoglu, Aygun and Dike, Ali Sinan

Subjects
*POLYLACTIC acid, *LACTIC acid, *ATTENUATED total reflectance, *SILANIZATION, *DYNAMIC mechanical analysis, *GLASS transition temperature
Abstract

Neat and surface silanized barite (BR) was compounded with poly(lactic acid) (PLA) at the loading range of 5, 10, 15, and 20 wt% by melt blending process. Surface characteristics of BR samples were examined by infrared spectroscopy in attenuated total reflectance mode. Mechanical, thermal, water resistance, melt flow, and morphological characterizations of composites were performed by tensile and impact tests, dynamic mechanical analysis, water absorption test, melt flow rate (MFR) test, and scanning electron microscopy (SEM) analysis, respectively. BR additions lead to increase in tensile strength and modulus of PLA. The maximum improvement is obtained for 15 wt% of silanized BR containing composite. In contrast, percent elongation of PLA decreases with the incorporation of BR. Treated BR-loaded composites give higher impact energy values compared to untreated BR. Impact performance of composites increases with concentration. Silanized BR-filled composite at 5 wt% concentration exhibits higher storage modulus than unfilled PLA, where other composites yield relatively lower values in the case of storage modulus. Glass transition temperature of PLA extends to higher values by the addition of BR. Inclusions of BR samples cause a slight decrease in MFR of unfilled PLA. Water absorption of composites is found to be higher than that of PLA. Silanized BR-filled composites display lower water absorption values compared to untreated BR, thanks to hydrophobic nature of Si containing surface. According to SEM microimages of composites, more homogeneous dispersion in PLA matrix is achieved for treated BR particles than neat ones due to enhancement for interfacial adhesion of BR to PLA after silanization. [ABSTRACT FROM AUTHOR]

Published
2020
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20. Effect of carbon fiber amount and length on flame retardant and mechanical properties of intumescent polypropylene composites.

Author

Atabek Savas, Lemiye, Mutlu, Aysenur, Dike, Ali Sinan, Tayfun, Umit, and Dogan, Mehmet

Subjects
CARBON fibers, MECHANICAL behavior of materials, FIREPROOFING agents, POLYPROPYLENE, POLYMERIC composites, OXYGEN index of materials
Abstract

The effects of carbon fiber amount and length were studied on the flame retardant, thermal, and mechanical properties of the intumescent polypropylene composites. The flame retardant properties of the intumescent polypropylene-based composites were investigated using limiting oxygen index, vertical burning test (UL-94), and mass loss calorimeter. The mechanical properties of the composites were studied using tensile test and dynamic mechanical analysis. According to the flammability tests results, the antagonistic interaction was observed between carbon fiber and ammonium polyphosphate. The limiting oxygen index value reduced steadily as the added amount of carbon fiber increased. Mechanical test results revealed that the addition of carbon fiber increased the tensile strength and the elastic modulus as the added amount increased. No effect of carbon fiber length was observed on the flammability, fire performance, and tensile properties of composites, whereas the elastic modulus increased as the carbon fiber initial length increased. [ABSTRACT FROM AUTHOR]

Published
2018
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21. Nanocomposites based on blends of polystyrene

Author

Dike, Ali Sinan, Yılmazer, Ülkü, and Diğer

Subjects
Polimer Bilim ve Teknolojisi, Polymer Science and Technology, Extrusion, Chemical Engineering, Kimya Mühendisliği, Polystyrene, Organoclays, Maleic anhydride, Nanocomposites
Abstract

Polistirenin (PS) kırılganlığı nedeni ile kullanım alanı sınırlıdır. Bu sorunu çözmek ve polistirenin kullanım alanını genişletmek için PS elastomerik bir malzeme ile karıştırılabilir ve darbe dayanımı modifiye edilebilir. Bu çalışmada, darbe modifikasyonu nedeni ile Young modülü ve gerilme dayanımında meydana gelen azalmanın üstesinden bu karışıma organokil ilave edilip ve nanokompozit üretip karışımı güçlendirerek gelindi.Bu çalışma iki kısımdan oluşur. Çalışmanın ilk kısmında üç farklı alifatik elastomerik malzeme ve üç farklı organokil kullanıldı ve onların polistirenin yapısal, mekanik, termal ve reolojik özellikleri üzerindeki etkileri incelendi. Lotader AX8900, Lotader AX8840 ve Lotader 2210 alifatik elastomerik uyumlaştırıcılar olarak seçildi ve Cloisite ® 15A, Cloisite ® 25A ve Cloisite ® 30B organokil olarak seçildi. Çalışmanın ilk kısmının tamamında organokil miktarı 2% ve elastomer miktarı 5% olarak korundu.Çalışmanın ikinci kısmında aromatik bir elastomer, Stiren-Bütadien-Stiren kauçuğu; SBS, elastomerik uyumlaştırıcı olarak seçildi ve SBS kauçuğu üzerine değişik oranlarda maleik anhidrit aşılandı. Aşılama vidaları aynı yönde dönen çift vidalı ekstruder yardımı ile yapıldı. Organokil olarak Cloisite® 30B kullanıldı. Organokilin PS ve PS / Elastomer alaşımları üzerindeki etkilerini incelemek için PS / Elastomer alaşımları da hazırlandı ve onların özellikleri de incelendi. Çalışmanın ikinci kısmının tamamında kil içeriği 0% ile 4% arasında, elastomer içeriği 0% ile 40% arasında değiştirildi. Bütün numuneler uygun koşullarda, vidaları aynı yönde dönen çift vidalı ekstruderde hazırlandı ve ardından enjeksiyonlu kalıplama işlemi uygulandı.Organokillerin PS matriksi içindeki dağılım durumunu ve kil tabakalarının aralıklarını incelemek için X ışınları kırınımı analizleri yapıldı. Çalışmanın ilk kısmında hazırlanan nanokompozitlerin tabaka aralıklarında önemli bir artış gözlenmedi fakat çalışmanın ikinci kısmında hazırlanan nanokompozitler araya girmiş ve yapraklanmış yapılar sergilediler.Elastomerik fazların ortalama alan boyutlarını incelemek için taramalı elektron mikroskopu analizleri yapıldı. Elastomerik fazı PS matriksinden uzaklaştırmak için ultrasonik banyoda oda sıcaklığında n-Heptan ile aşındırma yapıldı. İkili alaşımlar ve üçlü nanokompozitlerin elastomer içeriği arttıkça ortalama alan boyutu büyüdü.Bu çalışmada kullanılan hammadde ve hazırlanan numunelerin akış davranışlarını incelemek için eriyik akış indeksi testi uygulandı. Çalışmanın ilk kısmında elastomer ve organokil ilavesi eriyik akış indeksi değerlerini beklenildiği şekilde düşürdü. Çalışmanın ikinci kısmında kullanılan PS ve elastomerik malzemeler benzer eriyik akış indeksi değerlerine sahip olmalarına ragmen bu malzemelerle hazırlanan numuneler bu malzemelerin her ikisinden daha yüksek eriyik akış indeksi değeri sergilediler.Uyumlaştırıcı tipi, organokil tipi ve malzemelerin konsantrasyonunun hazırlanan malzemelerin mekanik özellikleri üzerindeki etkilerini incelemek için çekme ve çentiksiz Charpy darbe testleri yapıldı. Elastomerik fazın PS matriksi ile uyumsuzluğu nedeni ile çalışmanın ilk kısmında hazırlanan nanokompozitlerin gerilme özelliklerinde önemli bir artış gözlenmedi. Çalışmanın ikinci kısmında aromatik elastomerler kil tabakalarını araya girmiş / yapraklanmış hale getirerek daha yüksek gerilme dayanımı, modül, kopmada uzama ve darbe dayanımı değerlerine sebep oldu.Organokil ve elastomer ilavesinin bu çalışmada hazırlanan alaşım ve nanokompozitlerin ısısal özellikleri üzerindeki etkilerini incelemek için Diferansiyel Taramalı Kalorimetri Analizi yapıldı. Bu analiz yoluyla camsı geçiş sıcaklığı, Tg ölçüldü. Elastomer ilavesi örneklerin camsı geçiş sıcaklığını arttırdı fakat organokil ilavesi camsı geçiş sıcaklığını önemli derecede etkilemedi. Due to brittleness of polystyrene, PS, its usage area is restricted. To solve this problem and expand the usage area of PS, it can be blended and impact modified with an elastomeric material. In this study, the decrease in the modulus and tensile strength imparted by impact modification was overcome by reinforcing this mixture by incorporating organoclays and producing nanocomposites.This study consists of two parts. In the first part of this study three different types of aliphatic elastomeric materials and three different types of organoclays were used and their effects on the morphology, mechanical, thermal, and rheological properties of PS were investigated. Lotader AX8900, Lotader AX8840 and Lotader 2210 were chosen as the aliphatic elastomeric compatibilizers; and Cloisite ? 15A, Cloisite ? 25A and Cloisite ? 30B were chosen as the organoclays. Organoclay content was kept at 2% and elastomer content was kept at 5% throughout the first part of the study.In the second part of this study, an aromatic elastomer; Styrene-Butadiene-Styrene rubber, SBS, was chosen as the elastomeric compatibilizer and maleic anhydride was grafted onto SBS rubber at different ratios. Grafting was made by means of a co-rotating twin screw extruder. Cloisite ? 30B was used as the organoclay. In order to investigate the effects of organoclay addition on the properties of the PS and PS / Elastomer blends, PS / Elastomer blends were also prepared and their properties were also investigated. Clay content was varied between 0% and 4%, and the elastomer content was varied between 0% and 40% throughout the second part of the study. All samples were prepared by a co-rotating twin screw extruder, followed by injection molding at appropriate conditions.In order to investigate the state of dispersion and the basal spacings of the organoclays in the PS matrix, XRD analyses were carried out. No significant improvement was observed on the basal spacing of the nanocomposites prepared in the first part of the study, but nanocomposites prepared in the second part of the study exhibited intercalated or exfoliated structures.In order to investigate the average domain sizes of the elastomeric phases, SEM analyses were carried out. To remove the elastomeric phase from the PS matrix, etching was done with n-Heptane in an ultrasonic bath at room temperature. Average domain sizes increased as the elastomer content increased in the binary blends and ternary nanocomposites.In order to investigate the flow behaviour of the raw materials and the samples prepared throughout this study, MFI tests were carried out. In the first part of the study, addition of elastomer and organoclay decreased the MFI values, as expected. Although both PS and elastomeric materials used in the second part of the study have similar MFI values, samples prepared with these materials exhibited higher MFI values than both of the polymers.In order to investigate the effects of the compatibilizer type, organoclay type, and concentration of materials on the mechanical properties of the prepared samples, tensile and unnotched Charpy impact tests were performed. Due to incompatibility of the elastomeric phase with the PS matrix, no significant improvement was observed in tensile properties of the nanocomposites prepared in the first part of this study. In the second part of the study, the aromatic elastomers enhanced the intercalation / exfoliation of clay layers resulting in higher tensile strength, modulus, elongation at break and impact strength with respect to neat PS.In order to observe the effects of organoclay and elastomer addition on the thermal properties of blends and nanocomposites prepared in this study, Differential Scanning Calorimetry analyses were done. By this analysis, glass transition temperature, Tg was measured. Elastomer addition increased the Tg of the samples, whereas organoclay addition did not affect the Tg significantly. 215

Published
2011

25. Mechanical Properties of Polypropylene Based Composites Reinforced with B4C

Author

Dike, Ali Sinan and Mindivan, Harun

Abstract

The present work aims to compare the mechanical properties of Polypropylene (PP) based composites reinforced with B4C. Maleic Anhydride Modified Polypropylene (MAPP) was added to improve the B4C-matrix interphase. Processing has been carried out by twin-screw extrusion and injection molding. By adding the B4C particles to the PP and PP+MAPP matrix, the yield strength, shore D hardness, microhardness and relative scratch resistance increased gradually, but PP+MAPP/B4C composites showed better overall mechanical properties than the PP/B4C composites. However, elongation at break values occurred for all composites dropped with the B4C content, and PP+MAPP/B4C composites exhibited lower elongations at break than PP/B4C composites.

Published
2013
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26. Preparation and characterization of poly (lactic acid) / barite composites

Author

Hatipoğlu, Aygün, Dike, Ali Sinan, and Nanoteknoloji ve Mühendislik Bilimleri Ana Bilim Dalı

Subjects
Polymer composites, Polimer Bilim ve Teknolojisi, Barite, Polymer Science and Technology, Polylactic acid
Abstract

Polimer matris ile eklenti arasındaki arayüzey yapışması polimerik kompozit malzemelerinözelliklerinde önemli bir bir rol oynar. Barit (BR) mineralinin yüzeyi, poli (laktik asit) (PLA)ile mineral eklenti arasındaki uyumu arttırmak amacıyla silan uyumlaştırıcı ajan ile modifiyeedilmiştir. BR örneklerinin yüzey özellikleri İnfrared spektrometre (IR) ile karakterizeedilmiştir. Saf ve yüzeyi silanlanmış BR, ağırlıkça % 5, 10, 15, and 20 yükleme oranlarındaeriyik karıştırma işlemi kullanılarak PLA ile karıştırılmıştır. Kompozitlerin mekanik, ısısalmekanik,su dayanım, eriyik akış ve morfolojik karakterizasyonları, sırasıyla çekme ve darbetestleri, dinamik mekanik analiz (DMA), su emme testi, eriyik akış hızı (MFR) testi vetaramalı elektron mikroskopisi (SEM) analizi ile gerçekleştirilmiştir.Test sonuçlarına göre, BR eklenmesi PLA'nın çekme dayanım ve çekme modülünüarttırmıştır. Maksimum artış %15 silanlanmış BR eklenmiş kompozit için belirlenmiştir.Kompozitlerin darbe dayanımı BR konsantrasyonu ile yükselmiştir. DMA analizi göstermiştirki; PLA'nın camsı geçiş sıcaklığı BR eklenmesi ile daha yüksek değerlere çıkmıştır. BReklentileri PLA'nın MFR değerinde ufak azalmaya neden olmuştur. Silanlanmış BR içerenkompozitler işlem görmemiş BR ile kıyaslandığında, silikon kaplı yüzeyin hidrofobikdoğasından ötürü daha düşük su emme değerleri sergilemiştir. Kompozitlerin SEM mikroresimlerinegöre, silanlamadan sonra BR'nin PLA'ya yüzeysel yapışması arttığı için işlemgörmüş BR parçacıklarında görmemiş olanlara kıyasla PLA matrisi içinde daha homojendağılıma ulaşılmıştır. Silanlanmış BR'nin, PLA bazlı kompozitlerin uygulamaları açısındanuygun olduğu bulunmuştur. Interfacial adhesion between additive and polymer matrix plays a significant role in propertiesof polymeric composite materials. Surface of barite (BR) mineral was modified by silanecoupling agent in order to increase compatibility between mineral additive and poly (lacticacid) (PLA) matrix. Surface properties of BR samples were characterized by Infraredspectrometry (IR). Untreated and surface silanized BR were compounded with PLA at theloading ratios of 5, 10, 15, and 20 wt% using melt-mixing process. Mechanical, thermomechanical,water resistance, melt flow, and morphological characterizations of compositeswere performed by tensile and impact tests, dynamic mechanical analysis (DMA), waterabsorption test, melt flow rate (MFR) test, and scanning electron microscopy (SEM) analysis,respectively.According to results, BR additions led to increase in tensile strength and tensile modulus ofPLA. The maximum improvement was obtained for 15 wt% of silanized BR filled composite.Impact strength of composites increased with addition amount of BR. DMA analysis revealedthat glass transition temperature of PLA extended to higher values by the addition of BR.Inclusions of BR caused slight decrease in MFR value of PLA. Silanized BR containingcomposites displayed lower water absorption values compared to untreated BR, thanks tohydrophobic nature of silicon coated surface. According to SEM micro-images of composites,more homogeneous dispersion in PLA matrix was observed for treated BR particles thanuntreated ones due to enhancement for interfacial adhesion of BR to PLA after silanization.Silanized BR was found to be suitable for the applications of PLA-based composites. 54

Published
2020

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