MARC

 008090603s2006        ulka                    000      kor
■020    ▼a8931531869
■0801  ▼a621.382
■082    ▼a621.395▼bM973ㅇ▼223
■090    ▼a621.395▼bM973ㅇ
■1001  ▼aShizuo  Tokito,  Chihaya  Adachi,  Hideyuki  Murata공저
■24510▼a유기  EL  디스플레이  기초와  응용▼dShizuo  Tokito,  Chihaya  Adachi,  Hideyuki  Murata공저▼e강원호  장호정  공역
■260    ▼a서울▼b성안당▼c2006
■300    ▼a186p.▼b삽도▼c27cm
■505    ▼a1장  유기  EL  디스플레이의  특징과  과제▼a1.1  디스플레이  기술의  변천▼c10▼a1.2  유기  EL  디스플레이란▼c12▼a1.3  유기  EL  연구의  역사▼c14▼a1.4  유기  EL  디스플레이의  특징▼c20▼a1.5  유기  EL  디스플레이의  개발  동향▼c22▼a1.6  실용화  전개의  과제▼c25▼a참고문헌▼c26▼a2장  기본  구조와  발광  원리▼a2.1  유기  EL  소자의  기초▼c2800▼a1.  기본적인  동작  기구▼c2811▼a2.  발광  효율의  지배  인자▼c3122▼a3.  적층  구조의  의의▼c3233▼a4,  적층  구조와  재료  설계▼c3744▼a5.  고효율화를  위한  새로운  소자  구조▼c4055▼a2.2  백색  발광  유기  EL  소자▼c4266▼a2.3  유기  EL  소자의  제작  방법▼c4477▼a2.4  유기  EL  소자의  특성  평가법▼c5088▼a2.5  광  방출  효율의  중요성▼c5699▼a참고문헌▼c5800▼a3장  캐리어  주입과  수송  과정11▼a3.1  유기  반막에  캐리어  주입▼c6222▼a3.2  유기  반막  내의  캐리어  수송▼c6833▼a3.3  공간  전하  제한  전류▼c7744▼a참고문헌▼c7855▼a4장  도핑에  의한  고성능화66▼a4.1  여기  에너지  이동의  종류▼c8277▼a4.2  여기  에너지  이동  속도▼c8488▼a4.3  도핑  반막의  형광  양자  수율  평가▼c8799▼a4.4  에너지  이동을  이용한  유기  EL  소자의  고성능화▼c9000▼a4.4  에너지  이동을  이용한  유기  EL  소자의  고성능화▼c9011▼a4.5  캐리어  트랩기구에  기초한  발광  기구▼c9422▼a참고문헌▼c9833▼a5장  인광  발광에  의한  고성능화44▼a5.1  인광  발광이란▼c10055▼a5.2  인광의  발광  기구와  삼중항  여기자의  거동▼c10366▼a5.3  이상적인  소자  구조▼c10777▼a5.4  T-T  Annihilation(여기자-여기자  상호  작용)▼c11088▼a5.5  인광  유기  EL  소자의  내구성▼c11199▼a5.6  백색  인광  유기  EL  소자▼c11300▼a5.7  고분자  계열에  인광  발광의  도입▼c11611▼a참고문헌▼c11822▼a6장  유기  EL  재료33▼a6.1  저분자  재료▼c12244▼a6.2  고분자  재료▼c13255▼a6.3  전극  재료▼c13566▼a참고문헌▼c13877▼a7장  유기  EL  디스플레이의  개발88▼a7.1  디스플레이의  구조와  구동법▼c14299▼a7.2  디스플레이  제조  기술▼c15200▼a7.3  장수명화의  과제▼c16111▼a7.4  향후  전망▼c16722▼a참고  문헌▼c16833▼a8장  유기  EL  소자의  새로운  응용  전개44▼a8.1  휨성  디스플레이  연구의  현상과  전망▼c17255▼a8.2  조명  기구에의  전개▼c17666▼a8.3  유기  레이저의  가능성▼c17977▼a참고문헌▼c18388▼a찾아보기▼c18499
■9500  ▼c12,000

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