Preface xxi

Part I: Overview of Porphyrins 1

1 Composite Materials Utilizing Porphyrin Template: An Overview 3
Umar Ali Dar, Shazia Nabi and Mohd Shahnawaz

1.1 Introduction 4

1.2 Development and Construction of Porphyrin Composites 5

1.2.1 Porphyrin Synthesis and Functionalization 6

1.2.2 Synthesis of Porphyrin Composites 7

1.3 Applications of Porphyrin-Based Composites 8

1.3.1 Energy 9

1.3.2 Device Materials 9

1.3.3 Remediation 9

1.3.4 Nanotechnology 9

1.3.5 Agriculture 10

1.3.6 Catalysis 10

1.4 Future Perspectives 10

1.5 Conclusion 10

References 11

2 Physical and Mechanical Properties of Porphyrin Composite Materials 19
Kishor Kumar Roy, Sudipto Mangal, Anirban Karak and Ankita Acharya

2.1 Introduction 20

2.2 Synthesis Methods for Porphyrin Composites 21

2.2.1 Chemical Vapor Deposition (CVD) Techniques 21

2.2.2 Sol-Gel Methodology 22

2.2.3 Electrospinning and Electrochemical Deposition 22

2.2.4 Green Synthesis Approaches 24

2.2.5 Organometallic Methodologies for Synthesis 25

2.2.6 Comparative Analysis of Synthesis Techniques 26

2.3 Characterization Techniques 27

2.3.1 Scanning Electron Microscopy (SEM) for Morphological Analysis 27

2.3.2 X-Ray Diffraction (XRD) for Structural Investigation 28

2.3.3 Spectroscopic Techniques (UV-Vis and FTIR) for Chemical Analysis 29

2.3.4 Mechanical Testing Methods (Tensile, Compression, and Flexural) 30

2.4 Physical Properties of Porphyrin Composite Materials 30

2.4.1 Thermal Conductivity and Stability 31

2.4.2 Optical Properties and Light Absorption 32

2.4.3 Electrical Conductivity and Dielectric Properties 33

2.4.4 Magnetic Properties and Spin Dynamics 33

2.5 Mechanical Properties of Porphyrin Composite Materials 34

2.5.1 Tensile Strength and Elastic Modulus 35

2.5.2 Flexural Strength and Toughness 35

2.5.3 Impact Resistance and Fracture Toughness 36

2.5.4 Fatigue Behavior and Endurance Limit 36

2.6 Influence of Porphyrin Functionalization on Properties 37

2.6.1 Impact of Peripheral Substitution 37

2.6.2 Functional Groups and Surface Modification 37

2.6.3 Doping and Alloying Effects 37

2.6.4 Interfacial Interactions in Composite Systems 38

2.7 Applications of Porphyrin Composite Materials 38

2.7.1 Photovoltaics and Solar Cells 38

2.7.2 Sensing and Detection Technologies 39

2.7.3 Biomedical and Drug Delivery Applications 39

2.7.4 Catalysis and Environmental Remediation 40

2.8 Challenges and Future Perspectives 40

2.9 Conclusion 41

References 42

3 Porphyrin Composite Materials Analysis, Design, Manufacturing and Production 47
Elif Esra Altuner, Fatih Sen and Umar Ali Dar

3.1 Introduction 48

3.2 Porphyrin Aspects 49

3.2.1 Methods for Obtaining & Producing Porphyrins 50

3.2.1.1 Synthesis 50

3.2.1.2 Trans-Substituted Porphyrins 53

3.2.1.3 Obtaining A 2 BC Tetra-Substituted Porphyrins 53

3.3 The Analogs Design of Porphyrins 54

3.3.1 Analogs of Porphyrins 54

3.3.1.1 Chlorines and Bacteriochlorines 54

3.4 Composites 55

3.4.1 Porphyrin-Based Composites 55

3.4.2 Nano Porphyrin-Based Composites 55

3.4.3 (GQDs) and Porphyrin Composites 56

3.4.4 Graphene Oxide-Porphyrin Composites 57

3.4.5 Metalloporphyrins 57

3.5 Types of Porphyrin-Based Composites Framework 58

3.5.1 Porphyrin-Based MOFs 58

3.5.2 Porphyrin-Based COFs 59

3.5.3 Porphyrin-Based HOFs 60

3.6 Few Important Methods for Analysis of Porphyrins 61

3.6.1 Spectrophotometric Methods 61

3.6.2 Voltammetric Analysis 61

3.6.3 Analysis by HPLC Method 62

3.7 Conclusion 63

References 63

4 Advanced Characterization Methods and Characterization Types for Porphyrins 71
Elif Esra Altuner, Fatih Sen and Umar Ali Dar

4.1 Introduction 71

4.2 Types of Characterization Techniques Utilized for Porphyrins Analysis 72

4.2.1 UV-Vis Analysis and Spectrometric Properties 72

4.2.2 NMR Analysis of Porphyrins 74

4.2.3 Raman Spectroscopic Analysis of Porphyrins 74

4.3 HOMO-LUMO Relations for Porphyrins 75

4.4 Optical and Electro-Field Analysis 76

4.5 Applications in Solar Cells 76

4.6 DLS Analysis for Porphyrins 78

4.7 AFM Analysis for Porphyrins 79

4.8 Conclusion 80

References 80

Part II: Source, Design, Manufacturing, Properties and Fundamentals 87

5 Spectroscopic Nonlinear Optical Characteristics of Porphyrin-Functionalized Nanocomposite Materials 89
Vennila S., Wai Siong Chai, Kuan Shiong Khoo, Loganathan K. and Pau Loke Show

5.1 Introduction 90

5.2 Porphyrins 93

5.2.1 Chemical Characteristics of Porphyrins 94

5.3 Synthesis of Porphyrin 95

5.3.1 Adler-Longo Process of Porphyrin 95

5.3.2 Porphyrin Synthesis in Two Steps with a Single Flask at Ambient Temperature 96

5.4 Porphyrin-Functionalized Nanocomposites Materials 96

5.4.1 Porphyrin-Functionalized Nanocomposite Materials with Metal and Oxide Nanomaterials 96

5.4.2 Porphyrin-Functionalized Nanocomposite Materials with Polymers 98

5.4.3 Porphyrin-Functionalized Nanocomposite Materials with Biological Materials 99

5.4.4 Porphyrin-Functionalized Nanocomposite Materials with CNT or Carbon Fibers 99

5.5 Properties of Porphyrin-Functionalized Nanocomposite Materials 100

5.5.1 Spectral Properties 100

5.5.1.1 UV-Vis Spectroscopy 101

5.5.1.2 FTIR Spectroscopy 103

5.5.1.3 XRD Analysis 104

5.5.1.4 Fluorescence Spectroscopy 105

5.5.2 Nonlinear Optical Characteristics 105

5.6 Conclusion 106

References 107

6 Electrochemical Advancements in Porphyrin Materials: From Fundamentals to Electrocatalytic Applications 113
Alma Mejri and Abdelmoneim Mars

6.1 Introduction 114

6.2 Electrochemical Fundamentals of Porphyrin-Based Materials 115

6.2.1 Electrochemical Behavior of Porphyrin 116

6.2.2 Key Parameters Influencing Porphyrin Electrochemistry 118

6.2.3 Electrochemical Porphyrin-Based Materials 120

6.3 Porphyrin-Based Materials for Electrocatalysis Applications 124

6.3.1 Electrocatalysis Fundamentals 126

6.3.2 Porphyrin-Based Materials for CO 2 Reduction 127

6.3.3 Porphyrin-Based Materials for Electrocatalytic Water Splitting 131

6.3.3.1 Electrocatalytic Hydrogen Evolution Reaction 132

6.3.3.2 Electrocatalytic Oxygen Evolution Reaction 135

6.3.3.3 Overall Electrochemical Water Spilling 139

6.4 Conclusion and Outlooks 142

References 143

7 Manifestation of Porphyrin Composites in Variety of Photocatalytic Processes 153
Jyoti Rani, Varinder Singh and Gaurav Goel

7.1 Introduction 153

7.2 Porphyrin Composites 155

7.3 Synthesis of Porphyrin Composites 156

7.4 Photocatalytic Applications of Porphyrin Composites 156

7.4.1 Photocatalytic Production of Hydrogen Fuel by Water Splitting 158

7.4.1.1 Metal Oxides–Porphyrin Composites 159

7.4.1.2 Carbon Material–Porphyrin Composites 160

7.4.2 Photocatalytic Degradation of Dyes and Organic Pollutants 161

7.4.2.1 Conversion of CO 2 to Value-Added Chemicals 164

7.5 Conclusions 166

References 166

8 The Use of Porphyrin Composite Materials as Catalyst in a Variety of Application Sectors 173
Shagufta Parveen M. A. Ansari and Riyaz Ahmad Dar

8.1 Introduction 174

8.2 Related Works 178

8.3 Porphyrin-Based MOFs: Synthesis Methods, Structural Characteristics, and Characterization Techniques 181

8.3.1 Synthesis Methods 182

8.3.2 Structural Characteristics and Characterization Techniques 184

8.4 Design and Construction of Porphyrin-Based MOFs 185

8.4.1 Design of Porphyrin-Based MOFs 185

8.4.2 Porphyrin-Based MOF Construction 186

8.4.2.1 Porphyrin-Based MOFs with Carboxylic Acid Linkers 186

8.4.2.2 Porphyrin-Based MOFs with Nitrogen- Containing Heterocyclic Linkers 187

8.5 Application of Porphyrin-Based MOFs 188

8.5.1 PhotoCatalytic Evolution of Hydrogen 188

8.5.2 Catalytic Photolysis of CO 2 190

8.5.3 Photocatalytic Fixation of Nitrogen 192

8.5.4 Photocatalytic Removal of Pollutants 192

8.5.5 Photocatalytic Synthesis of Organic Compounds 193

8.5.6 Biosensing 194

8.5.7 Photodynamic Therapy with Porphyrin-Based MOFs 195

8.5.8 Advances in Fluorescence Imaging for Targeted Therapy 195

8.5.9 Sensing of pH 196

8.6 Conclusion and Future Scope 197

References 198

Part III: Advantages and Applications of Porphyrin Composites Materials 201

9 Porphyrin Composites Provide New Design and Building Construction Options 203
Xiaoquan Lu

9.1 Introduction 204

9.2 The Design Idea of Porphyrin Compound Material 205

9.2.1 Design and Synthesis of Porphyrins MOFs 206

9.2.2 Design and Synthesis of Porphyrin COFs 206

9.2.3 Design and Synthesis of Porphyrins HOFs 206

9.2.4 Design and Synthesis of Other Porphyrin-Based Composites 207

9.3 Construction of Porphyrin Electrochemiluminescence Molecules 208

9.3.1 Introduction to Electrochemiluminescence 208

9.3.2 Electrochemiluminescence Mechanism 208

9.3.3 Electrochemical Luminescence of Porphyrin Molecules Constructed by Molecular Regulation 210

9.3.4 Electrochemical Luminescence of Porphyrin Nanocomposites 215

9.3.5 Interfacial Electron-Induced Electrochemiluminescence 218

9.4 Construction and Characterization of Porphyrin Surface Interface Transport Molecules 219

9.4.1 Study of the Electron Transfer Process of Porphyrin at the Liquid/Liquid Interface 219

9.4.2 Study and Regulation of Photosensitized Materials and Their Models of Porphyrins 222

9.4.3 Regulation of the Porphyrin Interface 223

9.5 Composite of Porphyrins with Carbon-Based Materials 226

9.5.1 Construction of Porphyrin Functionalized Graphene Nanomaterials 226

9.5.2 Construction of Porphyrin-Functionalized Carbon Nanotubes 228

9.5.3 Construction of Porphyrin Functionalized g-C 3 N 4 230

9.5.4 Construction of Porphyrin-Functionalized Fullerenes 231

9.6 Porphyrin-Based MOFs, COFs, HOFs Porous Materials and Properties 233

9.6.1 Introduction and Application of Porphyrin MOFs 233

9.6.2 Introduction and Application of Porphyrin COFs 236

9.6.3 Brief Introduction and Application of Porphyrin HOFs 238

9.6.4 Brief Introduction and Application of Porphyrin POPs 240

9.7 Construction of Composite Materials of Porphyrins and Metal Nanoparticles 242

9.7.1 Construction and Application of Composite Materials 242

9.7.2 Construction of Porphyrin-Based Core-Shell Structure Nanomaterials 243

9.8 Properties of Porphyrin Nuclei 244

9.9 Application of Porphyrin Nuclei 244

9.10 Conclusion and Perspectives 246

Acknowledgments 247

References 247

10 A Comprehensive Review of Molecular Mechanisms Involved in Development of Porphyria, Due to Defective Porphyrin Biosynthesis in the Human Body 259
Santhosh Kumar Rajamani and Radha Srinivasan Iyer

10.1 Porphyrin Composites in Medicine – An Introduction 260

10.2 Nature of Porphyrins 260

10.3 Porphyrin Biosynthesis in Humans 260

10.4 Porphyria- Erythropoietic Disorders Due to Defects in Porphyrin Metabolism 262

10.4.1 Acute Porphyrias 263

10.4.1.1 Hepatic Porphyrias 264

10.4.2 Cutaneous Porphyrias 264

10.4.2.1 Acute Intermittent Porphyria (AIP) 265

10.4.2.2 Hereditary Coproporphyria (HCP) 266

10.4.2.3 Congenital Erythropoietic Porphyria (cep) 266

10.4.2.4 Porphyria Cutanea Tarda (PCT) 267

10.4.2.5 Variegate Porphyria (VP) 268

10.4.2.6 Erythropoietic Protoporphyria (EPP) 268

10.5 Acquired Porphyrias Due to EXCESsive Arsenic and Lead Exposure 268

10.6 Diagnosis of Porphyrias 269

10.7 Newer Therapeutics for Porphyrias: Givosiran Treatment and Afamelanotide Application 270

10.8 Conclusion 270

Bibliography 271

11 Porphyrin-Based Nanoparticles and Their Potential Scopes for Targeted Drug Delivery and Cancer Therapy 273
Prem Rajak, Sayanti Podder, Satadal Adhikary, Suchandra Bhattacharya, Saurabh Sarkar, Moutushi Mandi, Abhratanu Ganguly, Manas Paramanik and Sudip Paramanik

11.1 Introduction 274

11.2 Physico-Chemical Properties of Porphyrin and Their Advantage in Medical Science 276

11.3 Porphyrin-Based Nanoparticles (PBNPs) 279

11.3.1 Porphysome 279

11.3.2 Cerasomes 280

11.4 Porphyrin-Based Micelles 280

11.4.1 Porphyrin-Based Polymeric NPs 281

11.4.2 Nanocarriers (NCs) 281

11.5 Porphyrin-Conjugated Mesenchymal Stem Cells 282

11.6 Metal-Metalloporphyrin Frameworks (MMPFs) 282

11.7 Porphyrin-Loaded Covalent-Organic Frameworks (COFs) 282

11.8 Porphyrin-Based Noble Metallic NPs 283

11.9 Porphyrin-Based Quantum Dots 284

11.10 Implication of PBNPs in Targeted Drug Delivery 285

11.11 Potential Scope of PB-NPs in Disease Diagnosis and Treatment 288

11.12 Limitations 290

11.13 Conclusions 291

References 292

12 Role and Scope of Porphyrin Composites in Biotechnology 299
Elif Esra Altuner, Ghassan Issa, Fatih Sen and Umar Ali Dar

12.1 Introduction 300

12.2 Therapeutic Roles of Porphyrins 301

12.3 The Role of Porphyrins in Medical Imaging 303

12.3.1 Magnetic Resonance Imaging (MRI) and the Role of Porphyrins 304

12.3.2 Photoacoustic Imaging (PAI) and Its Role in Porphyrins 305

12.3.3 Fluorescence Imaging and Its Role in Porphyrins 306

12.4 Bifunctional Functions of Porphyrin Conjugates 306

12.5 Conclusion 307

References 308

13 Porphyrin Composites for Energy Storage and Conversion 315
Shazia Nabi and Umar Ali Dar

13.1 Introduction 316

13.2 Porphyrin-Based Composites 318

13.2.1 Functionalization of the Porphyrin with Conducting Polymers (CPs) 319

13.2.2 Functionalization with Carbon Nanomaterials (CNMs) 320

13.2.3 Porphyrin-Based Framework Materials 322

13.3 Porphyrin Composites for Energy Storage 324

13.3.1 Porphyrin Composites as Capacitors 324

13.3.2 Porphyrin Composites as Batteries 330

13.4 Porphyrin Composites for Energy Conversion 338

13.4.1 Oxygen Evolution Reaction 341

13.4.2 Oxygen Reduction Reaction (ORR) 344

13.4.3 Carbon Dioxide Reduction Reaction (CO 2 Rr) 348

13.5 Summary and Conclusions 352

References 354

14 Porous Organic Frameworks Based on Porphyrinoids for Clean Energy 367
Kharu Nisa, Ishfaq Ahmad Lone, Waseem Arif and Preeti Singh

14.1 Introduction 368

14.2 COFs in Catalysis 368

14.3 COF-Based Organic Materials and Their Synthesis 369

14.3.1 Interfacial Synthesis 369

14.3.2 Conventional Synthetic Methods 370

14.3.3 Strategies of Multistep Synthesis (MSS) and Multicomponent Reaction (MCR) 371

14.4 Designing of Porphyrin-Based COF Catalysts 372

14.4.1 Post-Modification Methods 373

14.4.2 MOFs as Electrocatalysts for CO 2 Rr 373

14.5 Conclusion 376

Acknowledgment 377

References 377

15 Porphyrin Composite Materials as an Electrode, a Material for Thin Films and Battery Components 383
Md. Al-Riad Tonmoy, Sidur Rahman, Md. Iqbal Hossain, Abu Shahid Ahmed and A.K.M. Ahsanul Habib

15.1 Introduction 384

15.2 Porphyrin Composites as Electrode Materials 385

15.2.1 Role of the Electrode in Energy Storage Devices 385

15.2.1.1 Energy Storage 385

15.2.1.2 Charge Transfer 386

15.2.1.3 Electrode Design 388

15.2.2 Electrochemical Properties of Porphyrin Composites 389

15.2.2.1 Electron Transfer Capability 389

15.2.2.2 Catalytic Activity 390

15.2.2.3 Electroactive Sites 392

15.2.2.4 Charge Storage 392

15.2.2.5 Stability and Reversibility 393

15.2.3 Role as Electrode in Fuel Cell 394

15.2.3.1 Electrocatalyst in ORR of Fuel Cells 395

15.3 Porphyrin Composites in Battery Components 398

15.3.1 Lithium-Ion Batteries (LIB) 399

15.3.1.1 Porphyrin Composite as Cathode Materials in LIB 399

15.3.1.2 Porphyrin Composite as Anode Materials in LIB 402

15.3.2 Lithium-Sulfur Batteries 404

15.3.3 Sodium-Ion Batteries 405

15.3.4 Redox-Flow Batteries 406

15.4 Thin Films of Porphyrin Composites 408

15.4.1 Thin Film Deposition Techniques for Porphyrin Composites 408

15.4.1.1 Physical Vapor Deposition (PVD) 408

15.4.1.2 Chemical Vapor Deposition (CVD) 410

15.4.1.3 Comparison with PVD and CVD 411

15.5 Liquid-Phase Epitaxy (LPE) 412

15.6 Structural and Morphological Properties of Porphyrin Composite Thin Films 415

15.6.1 Electronic and Optoelectronic Properties of Porphyrin Thin Films 416

15.6.2 Electronic Band Structure and Conductivity 416

15.7 Applications of Porphyrin Thin Films in Various Sectors 417

15.7.1 Sensors 417

15.7.2 Photovoltaic (PV) Cells 419

15.8 Future Directions and Emerging Trends 420

15.9 Current State of Porphyrin Composite Research 420

15.10 Emerging Trends in Porphyrin Composite Materials 420

15.11 Future Prospects and Potential Breakthroughs 421

15.12 Conclusion 422

References 423

16 Porphyrin Composite Materials as Electronic Component: Electronic Devices and Electronic Gadgets 431
Meenakshi Patyal, Kirandeep Kaur, Nidhi Gupta and Ashok Kumar Malik

16.1 Introduction 431

16.2 Synthesis of Porphyrin and Porphyrin Composite Materials 433

16.2.1 Synthesis of Porphyrin 433

16.2.2 Synthesis of Porphyrin Composite Materials 434

16.3 Porphyrin Composite Materials for Electronic Gadgets and Devices 434

16.3.1 Porphyrin Composite–Based Metal-Organic Frameworks (PP-MOFs) 435

16.3.2 Porphyrin Composite–Based Covalent Organic Frameworks (PP-COFs) 436

16.3.3 Metal Phthalocyanine (MPc)–Based Organic Thin-Film Transistors 438

16.3.4 Metal-Based Porphyrin Composites as Functional Devices 438

16.4 Conclusions and Future Perspective 440

References 440

17 Advances of Porphyrin Composites for the Effective Adsorption and Degradation of Pollutants 443
Vemula Madhavi and A. Vijaya Bhaskar Reddy

17.1 Introduction 444

17.2 Structural Features of Porphyrin Composites 446

17.3 Synthesis and Properties of Different Porphyrin Composites 448

17.3.1 Metal-Porphyrin Composites/Metalloporphyrins 449

17.3.2 Metal-Organic Framework (MOF) Porphyrin Composites 450

17.3.3 Polymer-Based Porphyrins 451

17.3.4 Nanomaterial-Based Porphyrin 452

17.4 Porphyrin-Based Materials for Selective Adsorption of Pollutants 456

17.4.1 Adsorptive Removal of Organic Contaminants 456

17.4.2 Adsorptive Degradation of Inorganic Contaminants 460

17.5 Desorption, Regeneration, and Reusability of Porphyrin Materials 463

17.6 Concluding Remarks 464

References 465

18 Thin Film of Porphyrin for Heavy Metal Ion Sensing 473
Parul Taneja and R.K. Gupta

18.1 Introduction 474

18.2 Monolayer of Free Base Porphyrin Molecule and Its Characterization 475

18.2.1 Experimental Setup of Surface Manometry 475

18.2.2 Surface Manometry of Porphyrin Molecule 477

18.2.3 Deposition of Monolayer on Piezoelectric-Based Transducer Surface 479

18.2.4 Characterization of Porphyrin Film 480

18.3 Sensing Application of Tetraphenylporphyrin 481

18.3.1 Piezoelectric-Based Sensing Setup 481

18.3.2 Sensing of Cationic Species Using ILS Film of Porphyrin 484

18.3.3 Characterization of Sensing Layer After Interaction with Metal Ions 486

18.4 Conclusion 488

References 489

19 Porphyrin Composite in the Agriculture and Food Industries 491
Debarpan Dutta

19.1 Introduction 491

19.2 Background 493

19.3 Impact on Agriculture 494

19.3.1 Supply of Agrochemicals 494

19.3.2 Detection of Poisonous Chemicals (Toxins) 497

19.3.3 Removal of Toxins 500

19.3.4 Detection of Toxic Metal Ions 502

19.3.5 Removal of Poisonous Metal Ions 503

19.3.6 Photo-Radiated Anti-Microbial Action 504

19.4 Impact on Food Industry 506

19.4.1 Some Recent Investigations of Metal-Porphyrin Related to Food Industry 506

19.4.2 Use as Food Colorants 508

19.5 Conclusion 511

References 512

20 Porphyrin Nanocomposites for Synergistic Treatment and Diagnostics: Biostability, Biocompatibility, and Therapeutic Efficacy 519
Arindam Mitra

20.1 Introduction 520

20.2 Biostability of Porphyrin Nanocomposites 521

20.2.1 Challenges of Biostability of Porphyrin Nanocomposites 521

20.2.2 Strategies to Address the Biostability of Porphyrin Nanocomposites 522

20.2.3 Evaluation of Biostability of Porphyrin Nanocomposites 523

20.3 Biocompatibility of Porphyrin Nanocomposites 524

20.3.1 Challenges of Biocompatibility of Porphyrin Nanocomposites 524

20.3.2 Strategies to Improve the Biocompatibility of Porphyrin Nanocomposites 525

20.3.3 Assessments of Biocompatibility In Vitro and In Vivo 527

20.4 Therapeutic Efficacy of Porphyrin Nanocomposites 527

20.4.1 Diagnostics Applications of Porphyrin Composites 530

20.5 Future Perspectives and Challenges 532

20.6 Conclusions 534

References 536

21 Diversity, Stability, and Selectivity for Porphyrin-Based Composite Materials 539
Aafaq Tantray, Nitin Rode, Lina Khandare and Umar Ali Dar

21.1 Introduction 539

21.2 Diversity in Porphyrin-Based Composite Materials 541

21.2.1 Metalloporphyrins 541

21.2.2 Covalent Porphyrin Frameworks (CPF) 542

21.2.3 Porphyrin-Based Polymer Materials 542

21.2.4 Porphyrin Nanoparticles 542

21.2.5 Self-Assembled Porphyrin Materials 542

21.3 Introduction to Various Composite Materials Incorporating Porphyrins 542

21.3.1 Organic-Inorganic Hybrids 542

21.3.2 Metal-Organic Frameworks (MOFs) 543

21.3.3 Covalent Organic Frameworks (COFs) 543

21.3.4 Polymers and Polymer Composites 543

21.4 Stability of Porphyrin-Based Composite Materials 544

21.4.1 Chemical Stability 544

21.4.2 Thermal Stability 546

21.4.3 Mechanical Stability 546

21.5 Strategies to Enhance Stability of Porphyrins 547

21.5.1 Design and Synthesis Approaches 547

21.5.2 Surface Modifications and Encapsulation Techniques 547

21.5.3 Post-Synthetic Stabilization Methods 548

21.6 Conclusions 548

References 549

22 Future Scope, Performance, Challenges, and Opportunities of Porphyrin Composite Materials 553
N. H. Vasoya and K. B. Modi

22.1 Introduction 553

22.2 Future Scope of Porphyrin Composite Materials 554

22.2.1 Enhanced Optoelectronic Properties 554

22.2.2 Advanced Energy Conversion Systems 555

22.2.3 Catalysis and Environmental Applications 556

22.2.4 Biomedical Applications and Therapeutics 558

22.2.5 Sensing and Detection 559

22.2.6 Emerging Fields and Cross-Disciplinary Applications 560

22.3 Performance Characteristics of Porphyrin Composite Materials 562

22.3.1 Optical Properties 562

22.3.2 Electrical Conductivity 564

22.3.3 Thermal Stability 565

22.3.4 Mechanical Strength and Flexibility 566

22.3.5 Chemical Stability 568

22.3.6 Charge Transfer and Transport Properties 569

22.4 Challenges in Developing Porphyrin Composite Materials 571

22.4.1 Scalability and Manufacturing Processes 571

22.4.2 Stability and Longevity 572

22.4.3 Cost-Effectiveness 574

22.4.4 Toxicity and Environmental Concerns 575

22.5 Opportunities for Porphyrin Composite Materials 577

22.5.1 Energy Conversion and Storage 577

22.5.2 Photocatalysis and Water Splitting 580

22.5.3 Environmental Remediation 581

22.5.4 Biomedical Imaging and Therapeutics 584

22.5.5 Chemical and Biological Sensing 587

22.5.6 Smart Materials and Electronics 589

22.6 Conclusion 594

References 594

Index 597

Discover the transformative potential of porphyrin-based composites in Porphyrin-Based Composites where readers will learn how these innovative materials enhance industrial sectors by combining multiple porphyrin components to create durable, sensitive, and efficient technologies that outperform traditional materials.

This book highlights the benefits of adopting porphyrin composites and discusses how they are used in different industrial sectors. Combining multiple porphyrin components is used to create materials with properties that are not possible with individual components, remove restrictions of water-insolubility, and ultimately lead to the development of durable and more sensitive technological materials. Composite materials have been essential to human life for thousands of years, beginning with the construction of houses by the first civilizations and advancing to modern technologies. Originating in the mid-twentieth century, composite materials show promise as a class of engineering materials that offer new opportunities for contemporary technology and have been beneficially incorporated into practically every sector due to their ability to choose elements, tune them to achieve the desired qualities, and efficiently use those features through design. Additionally, composite materials offer greater strength- and modulus-to-weight ratios than standard engineering materials. Materials based on porphyrin composites are used in a wide range of applications, including sensors, molecular probes, electrical gadgets, electronic devices, construction materials, catalysis, medicine, and environmental and energy applications.

Readers will find the book:

• Provides an overview of several porphyrin composites as model materials for commercial settings;
• Discusses fundamental, experimental, and theoretical research on structural and physicochemical properties of porphyrin composites;
• Demonstrates how complementary and alternative material designs that use porphyrin composites have evolved;
• Emphasizes important uses for cutting-edge, multipurpose materials that might contribute to a more sustainable society;
• Opens new possibilities by examining the role of developing unique hybrid, composite, and higher-order hierarchical materials that may be utilized to make valuable chemicals.

Audience

Researchers, academicians, chemists, industry experts, and students working in the fields of materials and environmental sciences, engineering, textiles, biology, and medicine.