Chromogenics : Smart Switchable Optical Materials and Their Applications

著者名：Lampert, Carl M. (EDT)

Wiley（2025/12/30発売）

• 言語：ENG
• ISBN：9781394159079
• eISBN：9781394159093

Description

Firsthand insights into the current and future technology and large-scale applications of color- and opacity-changing optical materials

Chromogenics delivers a comprehensive overview of the industry-relevant scientific background of chromogenics and provides details on successful manufacturing techniques for the scalable fabrication of products, enabling readers to apply chromogenic materials in billion-dollar market segments such as the car industry (rear-view mirrors) and building and construction industries (self-tinting windows), as well as for individual end-user products such as sunglasses.

This work includes contributions from developers of chromogenic products from leading companies and industry-near research institutions such as Fraunhofer, Merck, Pleotint, and Gentex, Chromogenics explores topics including:

• Electrochromics (both inorganic and polymeric), thermochromics, and suspended particle devices (SPD)
• Encapsulated pigment devices, specific liquid crystals, and polymer dispersed liquid crystals (PDLC)
• Vacuum web coaters and their large-area coatings, transparent electronic conductors, sputter coating processes, and pyrolytic doped tin oxide
• Commercial technologies including pyrolytic deposition, magnetron sputtering, slot die coating, and doctor blade coating
• Products such as switchable self-dimming mirrors and switchable glazing for glare reduction, solar energy control, and privacy glazing

Presenting state-of-the-art research in the field along with future outlooks, Chromogenics is an essential reference on the subject for materials scientists, physical chemists, applied physicists, and engineering scientists in industry.

Table of Contents

List of Contributors xiii

Preface xv

Part I Technologies 1

1a Overview of Chromogenics 3
Carl M. Lampert

Nomenclature 3

1a.1 Introduction 5

1a.2 The Dynamic Glass Market 7

1a.2.1 Automotive 8

1a.2.2 Eyewear 9

1a.2.3 Architectural 10

1a.2.4 Aerospace 12

1a.2.5 Information Display 12

1a.3 Families of Chromogenic Materials 13

1a.3.1 Chromogenics Switching by Collective Physical Movement 14

1a.3.1.1 Electromechanical 17

1a.3.1.2 Mechanochromism 19

1a.3.1.3 Magnetochromics and Magnetoionics 20

1a.3.1.4 Electrokinetics 21

1a.3.1.5 Dispersed Liquid Crystals (PDLC and NCAP) 22

1a.3.1.6 Suspended Particles 26

1a.3.2 The Chemichromic and Electrochemichromic Families 28

1a.3.2.1 Gasochromic 30

1a.3.2.2 Halochromism 34

1a.3.2.3 Solvatochromism 35

1a.3.2.4 Hydrochromism 35

1a.3.2.5 Electrochemichromic 35

1a.4 Chromogenic Switching by Discrete Movement of Ions, Atoms, and Molecules 36

1a.4.1 Electrochromics 37

1a.4.1.1 Inorganic Electrochromics 38

1a.4.1.2 Organic and Polymer Electrochromics 41

1a.4.2 Light-Induced Switching – Photochromics 42

1a.4.3 Thermal-Induced Switching – Thermochromic and Thermotropics 45

1a.4.3.1 Thermal-Induced Switching – Ligand Exchange Thermochromic (LETC) 46

1a.4.3.2 Thermal-Induced Switching – Thermotropics 48

1a.5 Multiband Switching Windows and Surfaces 49

1a.6 Running a Chromogenics Business 50

1a.6.1 Organizational Viewpoint 51

1a.6.2 Materials Viewpoint – Chromogenics 51

1a.6.3 Materials Viewpoint – Electrochromics 52

1a.6.4 Manufacturing Viewpoint 52

1a.6.5 Marketing Perspective 53

1a.7 Additional Information about Chromogenics 53

Acknowledgments 54

References 54

1b Introduction to Glazing Design and Measurements 69
Carl M. Lampert

Nomenclature 69

1b.1 Common Metrics for Glazing 71

1b.2 Solar Radiation and the Earth’s Atmosphere 72

1b.2.1 Clearness Index 74

1b.2.2 Daylighting 74

1b.3 Transmittance, Reflectance, and Absorptance Measurements 75

1b.3.1 Solar Transmittance 75

1b.3.2 Luminous, Visible Transmittance, and Visible Light Transmittance (VLT) 75

1b.3.3 Absorbance or Optical Density Measurement 77

1b.3.4 Haze and Scattering Measurements 78

1b.4 Color Measurements 80

1b.5 Thermal Emissivity and Emittance 82

1b.5.1 Low-e Coatings and Transparent Conductors used in Insulated Glass Units (IGUs) 83

1b.6 Design of an IGU Window System 86

1b.7 Energy Flow Mechanisms in Glazing Fenestration 87

1b.7.1 Conductive Heat Transport 88

1b.7.2 Convective Heat Transport 88

1b.7.3 Radiative Heat Transport 88

1b.8 Parameters Commonly Used to Characterize Window Glazing 89

1b.8.1 U-Factor 89

1b.8.2 Solar Heat Gain Coefficient (SHGC) 90

1b.8.3 Solar Factor (g-Value) or Total Solar Energy Transmittance (TSET) 91

1b.8.4 Total Solar Transmittance 91

1b.8.5 Instantaneous Heat Flow in a Whole Glazing 91

Acknowledgments 92

References 92

2 Electrochromics 97
Carl M. Lampert, Anoop Agrawal, and Junichi Nagai

Nomenclature 97

2.1 Introduction to the Field of Electrochromics 100

2.2 Electrochromic Materials 101

2.2.1 Coloration Efficiency 105

2.3 Electrochromic Device Design 106

2.3.1 Transparent Conductors 110

2.3.2 Electrochromic Device Switching Time 111

2.4 Self-Dimming Automotive Rearview Mirrors 112

2.5 Early Development of Electrochromic Automotive Sunroofs 116

2.6 Early Electrochromic Windows Developed at Asahi Glass Company 118

2.7 Designing Materials Systems for Electrochromic Glazing 120

2.8 Dynamic Building Windows 123

2.9 Commercial Electrochromic Windows 124

2.9.1 Window Performance Parameters 125

2.9.2 Electrochromic Glazing Examples 127

2.10 Multiband Switching for Glazing 134

2.10.1 Localized Surface Plasma Resonance (LSPR) 134

2.10.2 Early Commercial Development of LSPR Nanocrystals for Dual-Band Switchable Glazing 136

2.10.3 Research in Dual-Band Electrochromics 136

2.11 Electrochromic Windows for Aircraft 139

2.12 Electrochromic Eyewear 142

2.13 Electrochromic Information Displays 144

2.14 Electrochromic Gradient Filter 146

2.15 Dynamic Thermal Emittance Electrochromics for Spacecraft and Spacesuits 149

2.16 Other Electrochromic Devices: Photoelectrochromic and Photovoltaic-Electrochromic 151

Acknowledgments 151

References 151

3 Trends in Organic Electrochromic Materials and Their Applications 173
Melepurath Deepa and Anoop Agrawal

Nomenclature 173

3.1 Introduction to Organic Electrochromics 174

3.2 Organic EC Materials and Device Architectures 176

3.3 Electrochromic Supercapacitors (ESCs) with at Least One Transparent State 182

3.4 Integration of PV and ECD−Photoelectrochromic Device 187

References 191

4 Polymeric Electrochromics 195
Marco Schott and Uwe Posset

Nomenclature 195

4.1 Introduction 196

4.2 Electrochromic Polymers 196

4.2.1 Conjugated Polymers 196

4.2.2 Metal Coordination Polymers 204

4.3 Device Manufacturing 206

4.4 Industrial Applications of Polymeric Electrochromic Devices 213

4.5 Conclusion and Outlook 216

References 218

5 Evolution of Industrial Polymer Dispersed Liquid Crystal (PDLC) Technology in Europe: A Review of Research, Development, Manufacturing, and Potential Emerging Technologies 229
H. Hakemi

Nomenclature 229

5.1 Introduction to PDLC Technology 229

5.2 The Original PDLC Inventions 232

5.2.1 Micro-Emulsion (ME) Invention 233

5.2.2 Phase Separation (PS) Invention 233

5.2.2.1 Polymer Induced Phase Separation (PIPS) 233

5.2.2.2 Solvent Induced Phase Separation (SIPS) 233

5.2.2.3 Thermal Induced Phase Separation (TIPS) 233

5.3 Manufacturing Methods of PDLC Film 235

5.4 Historical Evolution of Industrial PDLC Technology 236

5.4.1 The Early Period (<1995) 237

5.4.2 The Setback Period (1995–2005) 238

5.4.3 The Revival Period (>2005) 238

5.5 PDLC Industrial Development in Italy 240

5.5.1 SNR (Italy) PDLC License 240

5.5.2 SNR Industrial R&D Program 242

5.5.3 SNR Production Program 243

5.5.3.1 Dry/Coating & Lamination Technique 244

5.5.3.2 Wet/Coating & Lamination Technique 244

5.5.4 SNR Intellectual Property 246

5.6 Important Industrial Development Issues 247

5.6.1 The Significance of Scale 247

5.6.2 The Significance of Time 247

5.7 Industrial Development of PDLC in Europe 247

5.7.1 Innoptec S.p.A. (Italy) 248

5.7.2 Dream Glass S.L. (Spain) 248

5.7.3 Gauzy Ltd. (Israel) 248

5.8 Potential Emerging Industrial PDLC Technologies 249

5.8.1 Direct PDLC Glazing 249

5.8.2 Bistable PDLC 250

5.8.3 Solar-Control PDLC 251

5.8.4 Dynamic PDLC Signage 251

5.9 The PDLC Market Situation 253

References 253

6 Suspended Particle Devices 261
Philippe Lemarchand and Brian Norton

Nomenclature 261

6.1 Introduction 262

6.2 Materials 264

6.3 Manufacture and Commercial Specifications 266

6.3.1 Switching Duration 267

6.3.2 Spectral Transmittance 272

6.4 Applications in the Built Environment 276

6.5 Accelerated Testing 279

6.6 Conclusion 284

Acknowledgment 287

References 287

7 Inorganic Thermochromics and Photochromics 293
Lars Österlund, José Montero, and Gunnar A. Niklasson

Nomenclature 293

7.1 Introduction 294

7.2 Optical Properties 295

7.3 Thermochromic Coatings 297

7.3.1 Challenges for VO 2 -Based Films 299

7.3.2 Synthesis of VO 2 -Based Thermochromic Films 304

7.3.3 Synthesis of VO 2 -Based Nanoparticles and Nanocomposites 307

7.4 Photochromic Coatings 310

7.4.1 Silver Halides 312

7.4.2 Transition Metal Oxides 312

7.4.3 Rare-Earth Oxyhydrides 315

7.5 Thermochromic and Photochromic Smart Windows 318

7.5.1 Applications of Thermochromic and Photochromic Glazing 318

7.5.2 Performance Limits 322

7.6 Conclusions 324

References 325

8 Overview of Organic Thermochromic Materials 341
Gunnar A. Niklasson, José Montero, and Carl M. Lampert

Nomenclature 341

8.1 Introduction 342

8.2 Clear Organic Thermochromics 344

8.2.1 Ligand-Exchange, Metal–Organic Materials 344

8.2.2 Leuco Dyes in a Matrix 350

8.3 Thermotropic Materials 353

8.3.1 Hydrogels 354

8.3.2 Polymer Blends 357

8.3.3 Ionogels 359

8.3.4 Casting Resins 360

8.3.5 Additional Materials 361

8.4 Discussion and Comparison 361

References 365

9 Other Chromogenic Technologies 371
Carl M. Lampert

Nomenclature 371

9.1 Introduction 372

9.2 E Ink – Encapsulated Electrophoretic Ink 373

9.3 eyrise® Liquid Crystal Glazing 379

9.4 ELSTAR Dynamics Electrophoretic Glazing 383

9.5 MEMS and Microshutter Materials 385

9.6 Optofluidics 388

9.7 Thermochromic Perovskites 390

Acknowledgments 391

References 392

Part II Manufacturing 395

10 Introduction to Manufacturing 397
Carl M. Lampert

Nomenclature 397

10.1 Manufacturing Introduction 398

10.2 The Glass Industry 398

10.3 Surface Cleaning 402

10.4 Flat Glass Sputter Coating 403

10.5 Vacuum Web Coating 406

10.5.1 Flexible Electrochromic Coating 406

10.5.2 Flexible Glass 407

10.6 Other Flat Glass Coating Processes 408

10.7 Slot-Die Coating 408

10.8 Wet-Chemical Sol–Gel Deposition 410

10.9 Atomic Layer Deposition (ALD) 413

10.9.1 Spatial ALD 413

10.10 Inkjet Deposition 415

10.11 Photonic Processing 417

10.12 Busbars and Electrical Connections 418

Acknowledgments 418

References 419

11 Sputter Coating Processes and Industrial Approaches 427
Wilmert C.S. De Bosscher

Nomenclature 427

11.1 Large-Area Magnetron Sputtering Basics 427

11.2 Magnetron and Process Concepts for Sputter Deposition of Metals 431

11.3 Tweaking Deposition Rate for Reactive Sputtering of SiO 2 434

11.4 Uniform Deposition of a Transparent Conductive Oxide (TCO) of Indium Tin Oxide (ITO) 436

11.5 Improved Process Stability and Performance for Metal Oxide Layers 439

11.6 Controlling Stoichiometry of Electrochromic Wo X Layers 442

11.7 High-Pressure Sputtering Increasing Mechanical Stability of NiO Layer 445

11.8 Conclusions 448

Acknowledgments 448

References 449

12 Vacuum Web Coaters and Their Large-Area Coatings Used in Chromogenic Products: Technology and Applications of Transparent Electronic Conductors 453
Paul Lippens

12.1 Vacuum Web or Roll Coaters 453

12.1.1 Definition, Basic Configuration 453

12.1.2 Industrial Systems Available on the Market 455

12.2 Coating Systems Produced on Web Coaters 458

12.2.1 Overview of a Few Important Coating Systems 458

12.2.2 An Important Building Module: Transparent Conducting Electrodes 459

12.2.2.1 Semiconducting ITO 459

12.2.2.2 Nodule Formation 460

12.2.2.3 Typical ITO Compositions for Web Coating 461

12.2.2.4 Other Transparent Electronic Conductors 463

12.3 Outlook 464

12.3.1 Web Coating on Thin Rollable Glass 464

12.3.2 Machine-Related Developments 465

12.3.2.1 Combination of Several Deposition Technologies on the Same Web Coater 465

12.3.2.2 Air-to-Air Coaters 465

References 466

13 Pyrolytic Fluorine-Doped Tin Oxide on Glass for Chromogenic Products 469
George Neuman

13.1 Introduction 469

13.2 The Development of Online Pyrolytic Deposition of Conductive Tin Oxide 469

13.3 Manufacturers 484

13.4 Chemical Vapor Deposition (CVD) 484

13.5 Properties 488

13.6 Color Suppression Technology (CSI) 493

13.7 Physical and Chemical Properties 494

13.8 Commercial Products 497

13.9 Conclusion 497

Acknowledgments 498

References 499

Index 503