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논문 기본 정보
- 자료유형
- 학위논문
- 저자정보
- 지도교수
- Hyun-jong Paik
- 발행연도
- 2018
- 저작권
- 부산대학교 논문은 저작권에 의해 보호받습니다.
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This dissertation describes the synthesis of polymers for individual dispersion of single-walled
carbon nanotubes (SWCNTs) with high aspect ratio. In contrast to small molecular surfactants,
polymeric dispersants require soft external force to exfoliate SWCNTs which results in SWCNTs
with low defects and high aspect ratio. Thus, it is of great importance to optimize polymer
structure for SWCNT dispersion by selecting monomers, controlling composition and topologies.
Well-defined polymeric dispersants are synthesized by atom transfer radical polymerization. The
polymeric dispersants are composed of furfuryl methacrylate (FMA), anchoring group interacting
with SWCNT surface and 2-(dimethylamino)ethyl methacrylate (DMAEMA) or quaternized
QDMAEMA (QDMAEMA) as a stabilizer group for solubilizing SWCNT in mediates. The
copolymers are characterized by GPC and 1H NMR for molecular weight, polydispersity index,
and composition.
The dispersion solutions of SWCNT with synthesized polymers are analyzed the dispersion
stability and dispersibility by particle stability analyzer, UV-Vis-NIR spectroscopy, TEM, AFM,
Raman spectroscopy and XPS. The mechanism for individual dispersion of SWCNTs has also
been proposed to understand the role of polymeric dispersants. The individually dispersed
SWCNTs preserving the own length and surface structure have potential for electrical devices, in
particular transparent conductive films (TCFs). TCFs were fabricated and evaluated for flexible
touch panel screen
carbon nanotubes (SWCNTs) with high aspect ratio. In contrast to small molecular surfactants,
polymeric dispersants require soft external force to exfoliate SWCNTs which results in SWCNTs
with low defects and high aspect ratio. Thus, it is of great importance to optimize polymer
structure for SWCNT dispersion by selecting monomers, controlling composition and topologies.
Well-defined polymeric dispersants are synthesized by atom transfer radical polymerization. The
polymeric dispersants are composed of furfuryl methacrylate (FMA), anchoring group interacting
with SWCNT surface and 2-(dimethylamino)ethyl methacrylate (DMAEMA) or quaternized
QDMAEMA (QDMAEMA) as a stabilizer group for solubilizing SWCNT in mediates. The
copolymers are characterized by GPC and 1H NMR for molecular weight, polydispersity index,
and composition.
The dispersion solutions of SWCNT with synthesized polymers are analyzed the dispersion
stability and dispersibility by particle stability analyzer, UV-Vis-NIR spectroscopy, TEM, AFM,
Raman spectroscopy and XPS. The mechanism for individual dispersion of SWCNTs has also
been proposed to understand the role of polymeric dispersants. The individually dispersed
SWCNTs preserving the own length and surface structure have potential for electrical devices, in
particular transparent conductive films (TCFs). TCFs were fabricated and evaluated for flexible
touch panel screen
목차
Chapter 1. General Introduction 11.1 General introduction 21.2 References . 3Chapter 2. Theoretical Background . 82.1 Carbon nanotube 92.1.1 Structure. 92.1.2 Properties . 142.2 Dispersion of carbon nanotubes 162.2.1 Covalent functionalization of carbon nanotubes 172.2.2 Non-covalent functionalization of carbon nanotubes 172.2.2.1 CNTs dispersion by surfactants 182.2.2.2 CNTs dispersion by polymeric dispersants 202.3 Synthesis of well-defined polymeric dispersants . 222.4 References . 24Chapter 3. The Effect of Composition of Polymers on Dispersion of Single-walledCarbon Nanotubes . 333.1 Introduction 343.2 Experimental 353.2.1 Materials. 353.2.2 Instruments 353.2.3 Synthesis of p(FMA-co-DMAEMA) . 363.2.4 Quarternery ammonium modification of p(FMA-co-DMAEMA) 363.2.5 Dispersions of SWCNTs using the polymeric dispersant 373.3 Results & Discussion 373.3.1 Design and characterization of polymeric dispersants 373.3.2 Characterization of the SWCNT dispersion . 413.4 Conclusion . 543.5 References . 54Chapter 4. The Dispersion and Evaluation of Single-walled Carbon NanotubesDispersion by Polymer Wrapping 584.1 Introduction 594.2 Experimental 604.2.1 Materials. 604.2.2 Instruments 604.2.3 Synthesis of polymeric dispersants 614.2.4 Dispersion of HiPco-SWCNTs using polymeric dispersants . 614.3 Results & Discussion 624.2.2 Synthesis of polymeric dispersants 624.2.3 Characterization of dispersed SWCNTs . 624.4 Conclusion . 754.5 References . 75Chapter 5. Non-Destructed SWCNT Dispersion with High Aspect Ratio andFabrication of Transparent Conductive Films . 795.1 Introduction 805.2 Experimental 815.2.1 Materials. 815.2.2 Instruments 825.2.3 Synthesis of furfuryl alcohol . 835.2.4 Synthesis of furfuryl methacrylate (FMA) 835.2.5 Synthesis of p(FMA-co-DMAEMA) . 835.2.6 Dispersion of SWCNTs using the polymeric dispersants 845.2.7 Fabrication of transparent conductive films 845.3 Results and discussion . 865.3.1 Synthesis of polymeric dispersants 865.3.2 Characterization of the SWCNTs dispersion . 905.3.3 Design and characterization of polymeric dispersants 925.3.4 Characterization of the TCFs . 955.4 Conclusion . 1065.5 References . 106Chapter 6. Summary . 1126.1 Summary . 113APPENDIX . 115
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