Changhee Lee School of Electrical Engineering and Computer Science Seoul National Univ.
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1 Quantum Dot-Conducting ti Polymer Hybrids for Optoelectronic t Devices Changhee Lee School of Electrical Engineering and Computer Science Seoul National Univ. chlee7@snu.ac.kr CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 1/23
2 Contents Introduction of semiconductor Quantum dots Quantum Dot / Conducting Polymer Hybrid Material Light-Emitting Diodes Based on QD-Polymer Hybrid Materials Summary CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 2/23
3 Nanoparticle applications Quantum dots QDLEDs Solar cells Biomedicine Magnetic nanoparticles Biomedicine: MRI. Hyperthemia, Drug delivery Metal nanoparticles Biodetection (Au. Ag) QLED & Display Electromagnetic shell (Fe, Ni, Co) Nanofluid Metal oxide nanoparticles Dielectrics Nanocomposite Nanocoating Al Active Layer PEDOT:PSSPSS - + ITO Biomarkers SAIT A. P. Alivisatos, Science (1998) NANOCO W. U. Huynh, J. J. Dittmer, A. P. Alivisatos, Science, 295, 2425 (2002) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 3/23
4 Comparison of QD-LED and OLED Feature QD-LED OLED Efficiency Low High Emission bandwidth (color saturation) Color Tunability Cost of Emitter Manufacturing process Narrow FWHM<30nm Excellent: Change QD size Low: One procedure for all RGB emitters Solution-based Broad FWHM< nm Low: Different emitter High Vacuum deposition Solution-based Large display area Yes Yes J. H. Kwak, Ph.D. Thesis (SNU, 2010) Flexibility Yes Yes J. H. Kwak, Ph.D. Thesis (SNU, 2010) J. H. Kwak et al., SID 2010 CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 4/23
5 LEDs based on colloidal quantum dots QD-LEDs e injection QDs HTL ETL Size-tunable band-gaps (Color tunability) High PL quantum efficiency Light p cathode Good photostability Narrow emission i line widths (FWHM anode <30 nm) Compatibility with solution processing methods h injection e-h Recombination CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 5/23
6 QD LEDs Tunable over the Entire Visible Spectrum Polina O. Anikeeva, Jonathan E. Halpert, Moungi G. Bawendi and Vladimir Bulovic (MIT), Nano Lett., 2009, 9 (7), pp CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 6/23
7 Problems for low efficiency of colloidal QD-LEDs Poor charge carrier injection because 1) QDs generally have an inorganic shell of a wide bandgap material (e.g., CdS or ZnS) to increase photostability and improve emission quantum yields by passivating surface defects. HIL/ HTL 2) QDs are covered by a layer of organic ligands, organic which is needed during their growth and provides QD solubility in organic solvents to allow processing. 5~5.5 ev However, these organic and inorganic i layers form 6.5~7.3 ev a tunneling barrier for charge injection. 1~2 ev gap 3) The valence bands of the QDs are generally shifted Top view to lower energy compared to the highest occupied molecular orbital (HOMO) levels of commonly used organic hole-injection layers. This introduces significant energy barriers to hole injection. 4) Massive QD aggregation occurs in blend film of QDs and polymers Poor morphology Wide energy band gap shell Organic ligands Surface traps T i X-section view CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 7/23
8 Conducting Polymer - Nanoparticle Hybrid System Nanoparticle Conducting Polymer/NP Hybrid High extinction coefficient High electron mobility Band gap & position tunability Solution process capability Polymer SH SH SH SH High extinction coefficient High hole mobility Solution process capability Patterning capability Synthesis thru RAFT, ATRP, NMP High extinction coefficient Efficient charge separation Improved colloidal stability Solution process capability Patterning capability CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 8/23
9 Quantum Dot / Conducting Polymer Hybrid n O SH m NH N SH poly(tpa)-b-cysteaminacrylate Evidence of hybridization * UV illumination (365 nm, 2 mw/cm 2 ) hexane dimetyhlformamide Matthias Zorn, Wan Ki Bae, Jeonghun Kwak, Hyemin Lee, Changhee Lee, Rudolf Zentel, Kookheon Char, ACS Nano 3 (5), 1063 (2009) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 9/23
10 Comparison of QD/Polymer Hybrid and Blend Quantum Dot /Conducting Polymer Hbid Hybrids The thiol anchor groups in the CAA block replace the surface ligands (oleic acid) of QDs, leading to QD/conducting polymer hybrid films. * poly(para methyl triphenylamine-b-cysteamine acrylamide) Quantum Dot / Conducting Polymer Blends The fluorinated block (PFP) with low surface energy does not have specific interactions with QDs, resulting in QD/conducting polymer blend films. * poly(para methyl triphenylamine-b-pentafluorophenole) Jeonghun Kwak, Wan Ki Bae, Matthias Zorn, Heeje Woo, Hyunsik Yoon, Jaehoon Lim, Sang Wook Kang, Stefan Weber, Hans-Jürgen Butt, Rudolf Zentel, Seonghoon Lee, Kookheon Char, Changhee Lee, Adv. Mater. 21 (48), 5022 (2009) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 10/23
11 Comparison of QD/Polymer Hybrid and Blend Pristine QDs (OA) QD/Polymer Hybrids QD+polymer blends PL In ntensity (a a. u.) Wavelength (nm) PTPA-b- CAA About 80 % of the PL intensity remains after grafting the QD surfaces with block copolymer. CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 11/23
12 Comparison of QD/Polymer Hybrid and Blend Hybrid Film Fluorescent Optical Microscopy Optical Microscopy Blend Film * All films were fabricated by spin- coating. CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 12/23
13 Comparison of QD/Polymer Hybrid and Blend TEM top view Hybrid Films QD 0.5 wt% * All films were fabricated by spin-coating. QD 1.0 wt% QD 1.5 wt% * Scale bars in the figure are 200 nm. Blend Films QD 0.5 wt% QD 1.0 wt% QD 1.5 wt% H b id andd Blend Hybrid Bl d films fil show h drastic d i differences. diff CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 13/23
14 Comparison of QD/Polymer Hybrid and Blend TEM cross-section view TEM top view Hybrid Films QD 0.5 wt% QD 1.0 wt% QD 1.5 wt% * Scale bars in the figure are 200 nm. Blend Films QD 0.5 wt% QD 1.0 wt% QD 1.5 wt% A Aggregation i & phase h separation i within i hi blend bl d films. fil CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 14/23
15 Comparison of QD/Polymer Hybrid and Blend QD / Polymer Hybrids: Drop-casted Morphology Hybrid Film Blend Film TEM cross-section view TEM cross-section view Drastic differences can be observed within drop-casted samples. This result is extendable to similar solution process (e.g., Ink-jet) Aggregation & phase separation in Blend film. CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 15/23
16 QD / Polymer Hybrids: Patterning Test Capillary force lithography Optical Microscopy Fluorescent Optical Microscopy regular hole patterns (hole diameter: 1 μm, μm hole distance: μm) conventional solution-based process (ink-jet, roll-to-roll, etc.) compatible CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 16/23
17 QD/Polymer hybrid films for efficient QD-LEDs CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 17/23
18 QD/Polymer Hybrid LEDs Wan Ki Bae, et al., Angew. Chem. Int. Ed. (submitted) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 18/23
19 Multicolor QLEDs QLED in Large Area Pixel size = 3.5 x 3.8 cm 2 Multicolored QLEDs G5 G4/YG 1 cm 1 cm G4/O G4/R 1 cm 1cm 1cm QLED with Strong EL Emission G5 G4/YG G4/R G4/O CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 19/23
20 QD-Polymer Blend vs Polymer/NP Hybrid QD-Polymer blend Polymer/NP /NPHybrid Polymer/NP hybrid NP Polymer Top view X-section view Top view X-section view Physical mixing of NPs & polymers Chemical binding btw NPs & polymers Massive QD aggregation Nanoscopic morphology control Poor morphology control Extensive process capability Surface states of NPs Surface state passivation with polymers Improved colloidal stability P. Alivisatos(U.C. Berkeley), R. Jenssen(Eindhoven) Limited efficiency e cy & poor reproducibility High efficiency & reliability! Jeonghun Kwak, et al., Adv. Mater. 21 (48), 5022 (2009) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 20/23
21 Summary Quantum Dot / Conducting Polymer Hybrid Material - QD/conducting polymer hybrid materials have been prepared by grafting conducting polymer with anchor group. - Hybrid films show improved surface/bulk morphology and stability compared to QD/conducting polymer composite films. Light-Emitting Diodes Based on QD-Polymer Hybrid Materials - reduced dturn-on voltage, high h efficiency, i reduced d efficiency i roll-off and high h color purity. Compatible with conventional solution/patterning process and Applicable to another optoelectronic devices such as solar cells, photodiodes, d etc. Jeonghun Kwak, et al., Adv. Mater. 21 (48), 5022 (2009) Wan Ki Bae, et al., Angew. Chem. Int. Ed. (submitted) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 21/23
22 Acknowledgements Prof. Seonghoon Lee (School of Chemistry, SNU) Prof. Kookheon Char (Dept. of Chemical Engineering, SNU) Prof. Rudolf Zentel (Univ. of Mainz) Dr. Wan ki Bae (SNU) Dr. Jeonghun Kwak (SNU) Dr. Matthias Zorn (Univ. of Mainz) Brain Korea 21 Program (SNU/MEST) Mr. Donggu Lee (M.S. student, SNU) Mr. Min Ki Nam (M.S. student, SNU) Mr. Jaehoon Lim (M.S. student, SNU) International Research Training Group (IRTG) CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 22/23
23 Thank you very much for your attention. CHANGHEE LEE Organic Semiconductor Lab. Seoul National University 23/23
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