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100   $a20080823d2008      uy|            0
101 0 $aeng
135   $aur|n|---|||||
181   $ctxt
182   $cc
183   $acr
200 10$aAdvances in organic light-emitting devices /$fYoungkyoo Kim and Chang-Sik Ha
210  1$a[Stafa-Zuerich] :$cTrans Tech Publications,$d[2008]
215   $a1 online resource (153 p.)
225 1 $aMaterials science foundations,$x1422-3597 ;$vvolume 40
300   $aDescription based upon print version of record.
311   $a0-87849-483-9 
320   $aIncludes bibliographical references.
327   $aAdvances in Organic Light-Emitting Device; Preface; Table of Contents; List of Abbreviations; Table of Contents; 1. History of the OLED; 2. Introduction to OLEDs; 2.1 Classification of OLEDs. 2.2 OLED Using Small Organic Molecules; 2.3 PLED Using Emissive Polymers; 2.4 Hybrid OLED; 2.5 Kinds of Devices According to Function and Structure; 3. The Physics behind OLEDs; 3.1 Basic Mechanism; 3.2 Charge Carrier Injection and Transport; 3.3 Delayed EL Owing to Low Charge Carrier Mobility; 3.4 Generation of Singlet and Triplet Excitons in OLEDs; 3.5 Efficiency of OLEDs
327   $a3.6 Exciton Energy Transfer from Donor (Host) to Acceptor (Guest)4. Organic Materials (Small Molecules ) for OLEDs; 4.1 Hole-Injecting Materials; 4.2 Hole-Transporting Materials; 4.3 Light-Emitting Materials (Organic Light-Emitters); 4.4 Hole-Blocking Materials. 4.5 Electron-Transporting Materials; 4.6 Electron-Injecting Materials. 4.7 Electrodes; 5. Polymeric Materials for PLEDs; 5.1 Polymers for Buffer Layer; 5.2 Light-Emitting Polymers; 5.3 Hole-Blocking/Electron-Transporting/Electron-Injecting Polymers. 5.4 Electrode Materials; 6. Materials for Hybrid OLEDs
327   $a6.1 Materials for All-Organic HOLEDs6.2 Materials for Organic-Inorganic HOLEDs; 7. Reliability and Lifetime; 7.1 Moisture Effect; 7.2 Oxygen Effect; 7.3 Impurity Effect; 7.4 Progressive Electrical Short; 7.5 Solvent and Polymer Side-Chain Effects in PLEDs; 7.6 Intrinsic Material Stability and Luminance Decay Mechanism; 8. OLED Displays; 8.1 Passive Matrix-Organic Light-emitting Display (PM-OLED); 8.2 Active-Matrix - Organic Light-Emitting Display (AM-OLED); 8.3 Full-Color OLED Displays; 9. Ongoing Challenges; 9.1 Flexible OLED; 9.2 Organic Light-Emitting Transistors
327   $a9.3 OLED for Lighting Applications10. OLED Market Trends and Outlook; 10.1 OLED Market Trends; 10.2 Outlook
330   $aOrganic electroluminescence (OEL) is the phenomenon of electrically-driven emission of light from organic materials; including both fluorescent and phosphorescent organic solids. The organic light-emitting device (OLED), which exploits OEL emission from organic semiconducting thin films (with thicknesses of less than a few hundred nanometers), sandwiched between electrodes, has attracted keen interest in its application to flat-panel displays, due to its high luminous efficiency, low driving voltage, tunable colors as well as a convenient device-structure design and low fabrication costs when
410  0$aMaterials science foundations ;$vvolume 40.
606   $aOrganic scintillators
606   $aElectroluminescent devices
615  0$aOrganic scintillators.
615  0$aElectroluminescent devices.
676   $a620.11295
700   $aKim$b Youngkyoo$01492312
702   $aHa$b Chang-Sik
801  0$bMiAaPQ
801  1$bMiAaPQ
801  2$bMiAaPQ
906   $aBOOK
912   $a9910786506103321
996   $aAdvances in organic light-emitting devices$93714750
997   $aUNINA