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  • 08월 18일 17시 이후 : 초록수정 불가능, 일정확인 및 검색만 가능

제108회 대한화학회 학술발표회, 총회 및 기기전시회 안내 Quantum dot-organosilicon hybrid material

등록일
2011년 8월 24일 17시 51분 08초
접수번호
1648
발표코드
MAT1-1 이곳을 클릭하시면 발표코드에 대한 설명을 보실 수 있습니다.
발표시간
목 14시 : 00분
발표형식
분과기념
발표분야
재료화학 - Microfluidic-Based Materials Chemistry
저자 및
공동저자
정현담
전남대학교 화학과, Korea
Quantum dot-organosilicon hybrid material is a class of organic-inorganic one that integrate quantum dots (QDs) and organosilicons at the molecular level. These materials garnered much interest due to the thermal and mechanical stabilities of the organosilicon component and the capability of modifying bulk properties by varying the QD. In detail, variation of QD at the molecular level can be used to tune bulk properties such as optical properties, including refractive index, light absorption properties, and luminescence properties, dielectric properties, and charge trap properties. InP/ZnS core-shell QDs capped by myristic acid (MA) were synthesized by a typical hot injection method and successive ionic layer adsorption (SILAR) approach. Post ligand exchanging these QDs with 3 aminopropyldimethylsiloxane (APDMS) allows to embed QDs to vinyl-functionalized silicones through chemical bonding. Connecting the QDs by short cross linker such as 1,4-divinyltetramethylsilylethane (DVMSE) was demonstrated to investigate the interaction between the QDs in the QD-organosilicon hybrid materials. Photoluminescence (PL) of the hybrid was quenched gradually as its size was increased, which is explained by scatter effect and restricted surface relaxation induced by the linker tension. This lab has also initiated compelling research into silicon quantum dot (Si QD) solids in order to utilize their synergetic benefits. The refractive index value of the Si QD thin film at a 30 °C curing temperature was 1.61 and 1.45 at 800 °C due to complete oxidation of the Si phases. The optical band gap values of 5.49 - 5.90 eV corresponded to Si phases with diameters between 0.82 - 0.74 nm, dispersed throughout the oxidized Si QD thin films and modeled by Si molecular clusters of approximately fourteen silicon atoms. Another kind of hybrid polymer, poly(tetraphenyl)silolesiloxane, was also invented and synthesized for realization of its unique charge trap properties. The organic portions consisting of (tetraphenyl)silole rings were responsible for negative charge trapping, while the Si-O-Si inorganic linkages provided the intrachain energy barrier for controlling electron transport.

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