Smithson, Chad


Publication Year
Deposit Date
Title
Type
Access


2014 (2)


article (2)


publishedVersion (2)


M24 (2)


openAccess (2)

Link to this page

http://TechnoRep.tmf.bg.ac.rs/APP/faces/author.xhtml?author_id=ce753f12-15f0-4d1c-9f2e-41cd945a018c&item_offset=0&project_offset=0&sort_by=dc.date.issued

Authority Key	Name Variants
ce753f12-15f0-4d1c-9f2e-41cd945a018c	Smithson, Chad (2)

Projects

No records found.

Author's Bibliography

Organoclay-polymer nanocomposites

Ljubić, Darko; Stamenović, Marina; Smithson, Chad; Nujkić, Maja; Petrović, Jelena; Putić, Slaviša

(Engineering Society for Corrosion, Belgrade, Serbia, 2014)

TY - JOUR
AU - Ljubić, Darko
AU - Stamenović, Marina
AU - Smithson, Chad
AU - Nujkić, Maja
AU - Petrović, Jelena
AU - Putić, Slaviša
PY - 2014
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2590
AB - The properties of polymer nanocomposites exceed the properties of common composite materials due to the nanoscale size and morphology of the fillers used. Particulate fillersare commonly used in polymers forimproved mechanical and thermal properties, as well as modified electrical properties and cost reduction. Organically modified layered clays, such asmontmorillonite, are among the most widely used fillers for the improvement of polymer matrices. Presented in this review are some of the most studied clay nanocomposites including clay-polyolefin, clay-polyester and clay-thermoplastic polyurethanenanocomposites. Additionally, the properties of clay-biopolymers nanocomposites will also be discussed.
AB - Svojstva polimernih nanokompozita prevazilaze svojstva uobičajenih kompozitnih materijala zbog nanodimenzija i morfologije upotrebljenih punioca. Čestični punioci se uglavnom koriste u cilju poboljšnja mehaničkih i toplotnih svojstava polimera, kao i za modifikovanje električnih svojstava polimerne matrice i smanjenja cene koštanja. Organski modifikovane slojevite gline, kao što je montmorilonit, su između ostalih, najzastupljeniji punioci u upotrebi za poboljšanje svojstava polimernih matrica. Ovim preglednim radom biće prikazani najznačajniji i najviše proučavani glina-polimerni nanokompoziti, kao što su glina-poliolefini, glina-poliestar i glina-termoplastični poliuretan nanokompoziti. Takođe, svojstva biopolimer-glina nanokompozita biće predstavljena i razmatrana u radu.
PB - Engineering Society for Corrosion, Belgrade, Serbia
T2 - Zaštita materijala
T1 - Organoclay-polymer nanocomposites
T1 - Organoglina-polimerni nanokompoziti
EP - 132
IS - 2
SP - 127
VL - 55
DO - 10.5937/ZasMat1402127L
ER -

@article{
author = "Ljubić, Darko and Stamenović, Marina and Smithson, Chad and Nujkić, Maja and Petrović, Jelena and Putić, Slaviša",
year = "2014",
abstract = "The properties of polymer nanocomposites exceed the properties of common composite materials due to the nanoscale size and morphology of the fillers used. Particulate fillersare commonly used in polymers forimproved mechanical and thermal properties, as well as modified electrical properties and cost reduction. Organically modified layered clays, such asmontmorillonite, are among the most widely used fillers for the improvement of polymer matrices. Presented in this review are some of the most studied clay nanocomposites including clay-polyolefin, clay-polyester and clay-thermoplastic polyurethanenanocomposites. Additionally, the properties of clay-biopolymers nanocomposites will also be discussed., Svojstva polimernih nanokompozita prevazilaze svojstva uobičajenih kompozitnih materijala zbog nanodimenzija i morfologije upotrebljenih punioca. Čestični punioci se uglavnom koriste u cilju poboljšnja mehaničkih i toplotnih svojstava polimera, kao i za modifikovanje električnih svojstava polimerne matrice i smanjenja cene koštanja. Organski modifikovane slojevite gline, kao što je montmorilonit, su između ostalih, najzastupljeniji punioci u upotrebi za poboljšanje svojstava polimernih matrica. Ovim preglednim radom biće prikazani najznačajniji i najviše proučavani glina-polimerni nanokompoziti, kao što su glina-poliolefini, glina-poliestar i glina-termoplastični poliuretan nanokompoziti. Takođe, svojstva biopolimer-glina nanokompozita biće predstavljena i razmatrana u radu.",
publisher = "Engineering Society for Corrosion, Belgrade, Serbia",
journal = "Zaštita materijala",
title = "Organoclay-polymer nanocomposites, Organoglina-polimerni nanokompoziti",
pages = "132-127",
number = "2",
volume = "55",
doi = "10.5937/ZasMat1402127L"
}

Ljubić, D., Stamenović, M., Smithson, C., Nujkić, M., Petrović, J.,& Putić, S.. (2014). Organoclay-polymer nanocomposites. in Zaštita materijala
Engineering Society for Corrosion, Belgrade, Serbia., 55(2), 127-132.
https://doi.org/10.5937/ZasMat1402127L

Ljubić D, Stamenović M, Smithson C, Nujkić M, Petrović J, Putić S. Organoclay-polymer nanocomposites. in Zaštita materijala. 2014;55(2):127-132.
doi:10.5937/ZasMat1402127L .

Ljubić, Darko, Stamenović, Marina, Smithson, Chad, Nujkić, Maja, Petrović, Jelena, Putić, Slaviša, "Organoclay-polymer nanocomposites" in Zaštita materijala, 55, no. 2 (2014):127-132,
https://doi.org/10.5937/ZasMat1402127L . .

Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites

Ljubić, Darko; Stamenović, Marina; Smithson, Chad; Nujkić, Maja; Međo, Bojan; Putić, Slaviša

(Engineering Society for Corrosion, Belgrade, Serbia, 2014)

TY - JOUR
AU - Ljubić, Darko
AU - Stamenović, Marina
AU - Smithson, Chad
AU - Nujkić, Maja
AU - Međo, Bojan
AU - Putić, Slaviša
PY - 2014
UR - http://TechnoRep.tmf.bg.ac.rs/handle/123456789/2600
AB - Polymers are the most studied viscoelastic material. The shorter times (high frequencies) corresponding to lower temperatures and long times (low frequencies) to high temperatures. This represents the quantitatively applied time-temperature superposition (TTS). Use of the Williams- Landel-Ferry (WLF) equation and the time-temperature superposition principle enables prediction and modeling of the mechanical and rheological properties of polymeric systems outside the timescale of the experiment. Application and validity of the TTS principle and WLF equation in polymer blends, composites, biopolymers and polymer networks will be discussed in this review.
AB - Polimeri su najproučavaniji viskoelastični materijali. Kraće vreme (odnosno visoke frekvencije) odgovaraju nižim temperaturama, a duže vreme (odnosno niske frekvencije) odgovaraju visokim temperaturama. Ovaj odnos vremena (frekvencije) i temperature predstavlja kvantitativnu primenu principa superponiranja vremena i temperature (TTS). Upotreba Viliams-Lendl-Feri (Williams- Landel-Ferry, WLF) jednačine i principa superponirnaja vremena i temperature omogućava predviđanje i modelovanje mehaničkih i reoloških svojstava polimernih sistema izvan vremenske skale eksperimenta. Upotreba i validnost TTS i WLF jednačine na polimerne blende, kompozite, biopolimere i polimerne mreže biće predstavljeni i razmatrani u ovom radu.
PB - Engineering Society for Corrosion, Belgrade, Serbia
T2 - Zaštita materijala
T1 - Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites
T1 - Princip superponiranja vremena i temperature - primena WLF jednačine za ispitivanje polimera i kompozita
EP - 400
IS - 4
SP - 395
VL - 55
DO - 10.5937/ZasMat1404395L
ER -

@article{
author = "Ljubić, Darko and Stamenović, Marina and Smithson, Chad and Nujkić, Maja and Međo, Bojan and Putić, Slaviša",
year = "2014",
abstract = "Polymers are the most studied viscoelastic material. The shorter times (high frequencies) corresponding to lower temperatures and long times (low frequencies) to high temperatures. This represents the quantitatively applied time-temperature superposition (TTS). Use of the Williams- Landel-Ferry (WLF) equation and the time-temperature superposition principle enables prediction and modeling of the mechanical and rheological properties of polymeric systems outside the timescale of the experiment. Application and validity of the TTS principle and WLF equation in polymer blends, composites, biopolymers and polymer networks will be discussed in this review., Polimeri su najproučavaniji viskoelastični materijali. Kraće vreme (odnosno visoke frekvencije) odgovaraju nižim temperaturama, a duže vreme (odnosno niske frekvencije) odgovaraju visokim temperaturama. Ovaj odnos vremena (frekvencije) i temperature predstavlja kvantitativnu primenu principa superponiranja vremena i temperature (TTS). Upotreba Viliams-Lendl-Feri (Williams- Landel-Ferry, WLF) jednačine i principa superponirnaja vremena i temperature omogućava predviđanje i modelovanje mehaničkih i reoloških svojstava polimernih sistema izvan vremenske skale eksperimenta. Upotreba i validnost TTS i WLF jednačine na polimerne blende, kompozite, biopolimere i polimerne mreže biće predstavljeni i razmatrani u ovom radu.",
publisher = "Engineering Society for Corrosion, Belgrade, Serbia",
journal = "Zaštita materijala",
title = "Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites, Princip superponiranja vremena i temperature - primena WLF jednačine za ispitivanje polimera i kompozita",
pages = "400-395",
number = "4",
volume = "55",
doi = "10.5937/ZasMat1404395L"
}

Ljubić, D., Stamenović, M., Smithson, C., Nujkić, M., Međo, B.,& Putić, S.. (2014). Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites. in Zaštita materijala
Engineering Society for Corrosion, Belgrade, Serbia., 55(4), 395-400.
https://doi.org/10.5937/ZasMat1404395L

Ljubić D, Stamenović M, Smithson C, Nujkić M, Međo B, Putić S. Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites. in Zaštita materijala. 2014;55(4):395-400.
doi:10.5937/ZasMat1404395L .

Ljubić, Darko, Stamenović, Marina, Smithson, Chad, Nujkić, Maja, Međo, Bojan, Putić, Slaviša, "Time: Temperature superposition principle: Application of WLF equation in polymer analysis and composites" in Zaštita materijala, 55, no. 4 (2014):395-400,
https://doi.org/10.5937/ZasMat1404395L . .