Colloidal Quantum Dot Light Emitting Diodes: Materials and Devices

Colloidal Quantum Dot Light Emitting Diodes

Explore all the core components for the commercialization of quantum dot light emitting diodes

Quantum dot light emitting diodes (QDLEDs) are a technology with the potential to revolutionize solid-state lighting and displays. Due to the many applications of semiconductor nanocrystals, of which QDLEDs are an example, they also hold the potential to be adapted into other emerging semiconducting technologies. As a result, it is critical that the next generation of engineers and materials scientists understand these diodes and their latest developments.

Colloidal Quantum Dot Light Emitting Diodes: Materials and Devices offers a comprehensive introduction to this subject and its most recent research advancements. Beginning with a summary of the theoretical foundations and the basic methods for chemically synthesizing colloidal semiconductor quantum dots, it identifies existing and future applications for these groundbreaking technologies. The result is tailored to produce a thorough understanding of this area of research.

Colloidal Quantum Dot Light Emitting Diodes readers will also find:

• An author with decades of experience in the field of organic electronics
• Detailed discussion of topics including advanced display technologies, the patent portfolio and commercial considerations, and more
• Strategies and design techniques for improving device performance

Colloidal Quantum Dot Light Emitting Diodes is ideal for material scientists, electronics engineers, inorganic and solid-state chemists, solid-state and semiconductor physicists, photochemists, and surface chemists, as well as the libraries that support these professionals.

Preface xi

1 History and Introduction of QDs and QDLEDs 1

1.1 Preparation Route of Quantum Dots 3

1.2 Light-Emitting Characteristics of Quantum Dots 3

1.2.1 Particle Size and Emission Color 3

1.2.2 Quantum Dot Optical Property 4

1.2.2.1 Quantum Surface Effect 4

1.2.2.2 Quantum Size Effect 4

1.2.2.3 Quantum Confinement Effect 5

1.2.2.4 Quantum Tunnelling Effect 5

1.2.2.5 Quantum Optical Properties 6

1.2.3 Core–Shell Structure of QDs 8

1.2.4 Continuously Gradated Core–Shell Structure of QDs (cg-QDs) 12

1.2.5 Typical QDs Materials 14

1.2.5.1 II–VI Semiconductor QDs 16

1.2.5.2 IV–VI Semiconductor QDs 17

1.2.5.3 II 3 –v 2 Semiconductor QDs 17

1.2.5.4 Ternary I–III–VI 2 Chalcopyrite Semiconductor QDs 17

1.2.5.5 Single Element-Based Semiconductor QDs 17

1.3 Application of Quantum Dots on Display Devices 18

1.3.1 The Basic Structure of QDLED 18

1.3.2 Main Factors Affecting QDLED Light Emission 19

1.3.2.1 Auger Recombination (AR) 19

1.3.2.2 Fluorescence Resonance Energy Transfer 21

1.3.2.3 Surface Traps and Field Emission Burst 22

1.3.3 History of QDLED Development 22

1.4 Conclusion and Remarks 27

References 28

2 Colloidal Semiconductor Quantum Dot LED Structure and Principles 33

2.1 Basic Concepts 33

2.1.1 Color Purity 33

2.1.2 Solution Processability 34

2.1.3 Stability 35

2.1.4 Surface States of Quantum Dots 36

2.1.5 Energy Levels and Energy Bands 36

2.1.6 Metals, Semiconductors, and Insulators 37

2.1.7 Electrons and Holes 38

2.1.8 Fermi Distribution Function and Fermi Energy Level 39

2.1.9 Schottky Barrier 39

2.1.10 Energy Level Alignment 40

2.2 Colloidal Quantum Dot Light-Emitting Devices 40

2.2.1 The Basic Structure of QDLED 41

2.2.2 The Working Principle of QDLED 43

2.2.3 Operating Parameters of QDLED 44

2.2.3.1 Turn-on Voltage 44

2.2.3.2 Luminous Brightness 44

2.2.3.3 Luminous Efficiency 44

2.2.3.4 Luminescence Color 45

2.2.3.5 Luminous Lifetime 45

2.2.3.6 QDLED Device Fabrication Process 48

References 48

3 Synthesis and Characterization of Colloidal Semiconductor Quantum Dot Materials 51

3.1 Background 51

3.2 Synthesis and Post-processing of Colloidal Quantum Dots 53

3.2.1 Direct Heating Method and Hot Injection Synthesis Method 53

3.2.1.1 Hot-Injection Method 54

3.2.1.2 Direct Heating Method 55

3.2.2 Precursor Chemistry 56

3.2.3 Ligating and Non-ligating Solvents 56

3.2.4 Mechanism of Nucleation and Growth of Colloidal Quantum Dots 58

3.2.5 Size Distribution Focus and Size Distribution Scatter 59

3.2.6 Crystalline Species-Mediated Growth and Orientation of Nanocrystals Attachment Growth 60

3.2.7 Synthesis Methods and Band Gap Regulation Engineering of Nuclear-Shell Quantum Dots 61

3.2.7.1 Non-alloyed Core–Shell Quantum Dots 63

3.2.7.2 Alloy Core–Shell Quantum Dots 64

3.2.8 Surface Chemistry of Colloidal Quantum Dots 65

3.2.8.1 Covalent Bond Classification Method 65

3.2.8.2 Entropic Ligands 66

3.3 Material Characterization 66

3.3.1 Ultraviolet–Visible (UV–Vis) Absorption and Fluorescence Spectra 67

3.3.2 Nuclear Magnetic Resonance Spectroscopy 69

3.3.3 Fourier Transform Infrared Spectroscopy (FTIR) 71

3.3.4 X-Ray Photoelectron Spectroscopy (XPS) 74

3.3.5 Transmission Electron Microscopy 76

3.3.6 Small-Angle X-Ray Scattering and Wide-Angle X-Ray Scattering 76

3.3.7 X-Ray Diffractometer 77

3.3.8 X-Ray Absorption Fine Structure Spectra 78

3.3.9 Measurement of Fluorescence Quantum Yield 79

3.4 Conclusion and Outlook 79

References 81

4 Red Quantum Dot Light-Emitting Diodes 87

4.1 Background 87

4.2 Red Light Quantum Dot Materials 88

4.2.1 Materials 89

4.2.2 Quantum Dot Structure Design and Optimization 90

4.2.3 Surface Ligands 91

4.2.4 Core–Shell Structure 94

4.2.5 Alloy Core–Shell Structure 96

4.3 Red QDLED Devices 97

4.3.1 Red QDLED Device Architecture Development 97

4.3.2 Common Device Structures 99

4.4 Conclusion and Outlook 102

References 104

5 Green Quantum Dot LED Materials and Devices 111

5.1 Background 111

5.2 Commonly Used Luminescent Layer Materials in Green QDLEDs 120

5.2.1 Discrete Core/Shell Quantum Dots 120

5.2.2 Alloyed Core/Shell Quantum Dots 121

5.2.3 Core/Multilayer Shell Quantum Dots 121

5.3 Development of Device Structures for Green QDLEDs 122

5.4 Factors Affecting the Performance of Green QDLEDs 125

5.4.1 QD Ligand Effect 126

5.4.2 QD Core/Shell Structure 129

5.4.3 Optimization of the Device Structure 130

5.4.4 Other Strategies to Improve Device Performance 132

5.5 Summary and Outlook 134

References 135

6 Blue Quantum Dot Light-Emitting Diodes 141

6.1 Introduction 141

6.2 Blue Quantum Dot Luminescent Materials 143

6.2.1 Blue Quantum Dots Containing Cadmium 145

6.2.2 Cadmium-Free Quantum Dots 149

6.2.2.1 Quantum Dots Based on InP 149

6.2.2.2 Quantum Dots Based on ZnSe 151

6.2.2.3 Quantum Dots Based on Cu 153

6.2.2.4 Quantum Dots Based on AlSb 155

6.3 Optimization of Charge Transport Layer (CTL) 155

6.3.1 Hole Transport Layer 156

6.3.2 Electron Transport Layer 161

6.4 Device Structure 164

6.5 Summary 166

References 168

7 Near-Infrared Quantum Dots (NIR QDs) 173

7.1 Introduction of Near-Infrared Quantum Dots 173

7.2 Near-Infrared Quantum Dot Materials 174

7.2.1 Chalcogenide Lead Quantum Dots 176

7.2.2 Chalcogenide Cadmium Quantum Dots 177

7.2.3 Silicon Quantum Dots 178

7.3 Optimization of Near-Infrared Quantum Dot Materials 179

7.3.1 Regulation of Near-Infrared Quantum Dots by Ligand Engineering 179

7.3.2 Control of Near-Infrared Quantum Dots by Core/Shell Structure 180

7.3.3 Quantum Dots in the Matrix 181

7.4 Summary and Prospect 182

References 183

8 White QDLED 187

8.1 Generation of White Light 187

8.2 Quantum Dots for White LEDs 188

8.2.1 Yellow–Blue Composite White Light Quantum Dots 189

8.2.1.1 Cadmium-Containing Yellow Light Quantum Dots 189

8.2.1.2 Cadmium-Free Yellow Light Quantum Dots 189

8.2.2 Three-Base Color Quantum Dot Composite 193

8.2.3 Quantum Dots with Direct White Light Emission 197

8.3 Summary Outlook 200

References 203

9 Non-Cadmium Quantum Dot Light-Emitting Materials and Devices 207

9.1 Introduction 207

9.2 Quantum Dots and QDLED 208

9.2.1 InP 208

9.2.2 ZnSe 215

9.2.3 I-iii-vi 218

9.3 Methods for Optimizing QDLED Performance 222

9.3.1 Ligand Engineering 223

9.3.2 Shell Engineering 224

9.3.3 QDLED Device Structure Optimization 225

9.4 Summary and Outlook 227

References 230

10 AC-Driven Quantum Dot Light-Emitting Diodes 235

10.1 Principle of Luminescence of DC and AC-Driven QDLEDs 236

10.2 Mechanism of Double-Emission Tandem Structure of AC QDLEDs 239

10.2.1 Field-Generated AC QDLEDs 240

10.2.2 Half-Field to Half-Injection AC QDLEDs 242

10.2.3 AC/DC Dual Drive Mode QDLEDs 244

10.3 Optimization Strategies for AC QDLEDs 245

10.3.1 Optimization of the Field-Induced AC QDLED 247

10.3.1.1 Dielectric Layer Optimization 248

10.3.1.2 Quantum Dot Layer Optimization 250

10.3.2 Optimization of Half-Field-Driven Half-Injected AC QDLEDs 251

10.3.2.1 Charge Generation Layer Optimization 254

10.3.2.2 Tandem Structure 254

10.3.2.3 AC/DC Dual Drive Mode QDLED Optimization 255

10.3.3 Conclusion and Future Direction of AC-QDLED 256

References 257

11 Stability Study and Decay Mechanism of Quantum Dot Light-Emitting Diodes 259

11.1 Quantum Dot Light-Emitting Diode Stability Research Status 259

11.2 Factors Affecting the Stability of Quantum Dot Light-Emitting Diodes 261

11.2.1 Quantum Dot Light-Emitting Layer 261

11.2.2 Hole Transport Layer 263

11.2.3 Electronic Transport Layer 265

11.2.4 Other Functional Layers 267

11.3 Quantum Dot Light-Emitting Diode Efficiency Decay Mechanism 268

11.4 Aging Mechanisms of QDLEDs 271

11.4.1 Positive Aging 272

11.4.2 Negative Aging 273

11.4.3 Electron Transport Layer 274

11.4.4 Hole Transport Layer 275

11.4.5 QDs Layer 276

11.5 Characterization Technologies for QDLEDs 278

11.5.1 Transient Electroluminescence 279

11.5.2 Electro-Absorption (EA) Spectroscopy 281

11.5.3 In-Situ EL–PL Measurement 282

11.5.4 Differential Absorption Spectroscopy 283

11.5.5 Displacement Current Measurement DCM Technology 285

11.6 Outlook 286

References 287

12 Electron/Hole Injection and Transport Materials in Quantum Dot Light-Emitting Diodes 291

12.1 Introduction 291

12.2 Charge-Transport Mechanisms 292

12.3 Electron Transport Materials (ETMs) for QDLED 293

12.3.1 Metal-Doped ETMs 293

12.3.2 Metal Salt-Doped ETMs 296

12.3.3 Design of Composite Materials ETMs 296

12.3.4 Polymer-Modified ETMs 296

12.3.5 Inorganic Organic Hybrid ETMs 296

12.3.6 Double-Stacked ETMs 297

12.4 Electron Injection Materials for QDLED 299

12.5 Hole Transport Materials for QDLED 301

12.5.1 Doping of HTMs 305

12.5.2 Compositions of HTMS 309

12.5.3 New HTM Materials for QDLED 311

12.6 Hole Injection Materials for QDLED 315

12.7 Summary and Outlook 321

References 322

13 Quantum Dot Industrial Development and Patent Layout 327

13.1 Introduction 327

13.2 Patent Layout 330

13.2.1 Nanosys 330

13.2.2 SAMSUNG 332

13.2.3 Nanoco 335

13.2.4 Najing Tech 338

13.2.5 CSOT 344

13.2.6 BOE 347

13.2.7 TCL 351

13.3 Summary and Outlook 355

References 355

14 Patterning Techniques for Quantum Dot Light-Emitting Diodes (QDLED) 361

14.1 Introduction 361

14.2 Photolithography 361

14.3 Micro-Contact Transfer 363

14.4 Inkjet Printing 366

14.5 Other Patterning Techniques 368

14.6 Conclusion 369

References 370

Index 373

Hong Meng, PhD, is a Professor in the School of Advanced Materials at the Peking University Shenzhen Graduate School, China. After receiving his PhD from University of California, Los Angeles (UCLA) in 2002, he has spent the last twenty years of his career working at the Institute of Materials Science and Engineering (IMRE) in Singapore, Lucent Technologies Bell Labs, and DuPont Experimental Station.