1)Chapter One: Classification and Application of Advanced Composite Materials

Manish Srivastava*^a, Anamika Srivastava, Nirmala Kumari Jangid^a, Anjali Yadav^a, and Sunidhi^a

Department of Chemistry, Banasthali Vidyapith, Banasthali, Rajasthan, India

*Corresponding author email: sagermanish1@gmail.com

Abstract

1. Introduction

            1.1 Merits of Composite Materials

            1.2 Disadvantages and Limitations of Composite Materials

2. Classification of advanced composite materials

            2.1 Comparative Properties of Composite Materials

                                    2.1.1. Polymer Matrix Composites

                                    2.1.2 Metal Matrix Composites (MMCs)

                                    2.1.3 Ceramic Matrix Composites (CMCs)

                                    2.1.4 Carbon/Carbon Composites (C/Cs)

            2.2 Classification Based on Reinforcement

                                    2.2.1 Particulate reinforced Composites

                                    2.2.2 Structural Composites

                                    2.2.3 Fiber reinforced composites (FRCs)

            2.3 Carbon Nanotubes (CNTs) Based Nanocomposites

3. Fabrication and characterization of advanced composite materials

            3.1 Fabrication Technique

                                    3.1.1 Hand Layup

                                    3.1.2 Curing methods

                                    3.1.3 Alternative curing methods

                                    3.1.4 Cure monitoring

                                    3.1.5 Out-of-autoclave (OOA)

                                    3.1.6 Resin film infusion (RFI)

                                    3.1.7 Injection molding

            3.2 Fabrication methods of Nanocomposites Materials

                                    3.2.1 Ceramic Matrix Nanocomposites (CMNC)

                                    3.2.2 Metal Matrix Nanocomposites (MMNC)

                                    3.2.3 Polymer Matrix Nanocomposites (PMNC)

            3.3 Fabrication of polyaniline nanocomposites containing ZnO nanorods

                                    3.3.1 Characterization of polyaniline nanocomposites containing ZnO                                       nanorods

                                    3.3.3 SEM analysis

            3.4 Fabrication of Chitosan–polyaniline–copper (II) oxide hybrid composite

                                    3.4.1 Characterization of Chitosan–polyaniline–copper (II) oxide hybrid                                   composite

                                    3.4.2 XRD analysis

                                    3.4.3 SEM and TEM analysis

4. Applications of advanced composite materials

            4.1.1 Polymer Matrix Composite Applications

            4.1.2 Metal Matrix Composite Applications

            4.1.3 Carbon Matrix Composite Applications

            4.1.4 Ceramic Matrix Composite Applications

            4.2 Applications of advanced composite materials

                                    4.2.1 Aerospace

                                    4.2.2 Automotive Engineering

                                    4.2.3 Bioengineering

                                    4.2.4 Civil/Structural Engineering

                                    4.2.5 Domestic

                                    4.2.6 Electrical Engineering

                                    4.2.7 Marine Engineering

5. Conclusion

2)Chapter Two: Advanced Composites of Nanomaterials and their Applications

Department of Chemistry, Banasthali Vidyapith, Banasthali – 304022, Rajasthan, India

Corresponding author email: kavita_poonia8318@yahoo.co.in

1. Introduction

2. Synthesis of Nanomaterials

            2.1 Hydrothermal synthesis

            2.2 Sol-gel synthesis

            2.3 Polymerized complex strategy (Pechini prepare)

            2.5 Microwave irradiation

3. Types of Nanocomposites

            3.1 Ceramic Matrix Nanocomposites (CMNC)

            3.2 Metal Matrix Nanocomposites (MMNC)

            3.3 Polymer Matrix Nanocomposites (PMNC)

4. Applications

            4.1 Fuel cells

            4.2 Electronics

            4.3 Aerospace applications

                        4.4.1 Wound dressings

                        4.4.2 Catheters Silver

                        4.4.3 Bone cement

                        4.4.4 Dental materials

                        4.4.5 Bio-diagnosis

            4.5 Cosmetics Applications

            4.6 Nanoparticles in Paint Formulation

            4.7 Nanoparticles in Ceramics

            4.8 Nanoparticles in Textiles

5. Conclusion

     References

3)Chapter Three: Advances in Composites for Solid-phase (Micro) extraction

Yanjuan Liu^1,*, Zhen Wang¹, Min Sun^2,**

¹ School of Pharmacy, Linyi University, Shuangling Road, Linyi 276000, Shandong, China, Email address: liuyanjuan09@163.cm (Y. Liu)

² Key Laboratory of Interfacial Reaction & Sensing Analysis in Universities of Shandong, School of Chemistry and Chemical Engineering, University of Jinan, Jinan 250022, PR China, Email address: chm_sunm@ujn.edu.cn; sunmin-123456@163.com (M. Sun)

Abstract

1. Introduction

2. Solid-phase extraction

            2.1 Dispersive solid-phase extraction

                                    2.1.1 MOFs-based composites

                                    2.1.3 Carbon-based composites

                                    2.2.1 MOFs-based composites

                                    2.2.2 COFs-based composites

                                    2.2.3 Graphene and other carbon materials-based composites

            2.3 Magnetic solid-phase extraction

                                    2.3.1 MOFs-based magnetic composites

                                    2.3.2 COFs-based magnetic composites

                                    2.3.3 MIPs-based magnetic composites

                                    2.3.4 Carbon materials-based magnetic composites

                                               2.3.4.1 Graphene-based magnetic composites

                                               2.3.4.2 CNT-based magnetic composites

                                               2.3.4.3 Other carbon-based magnetic composites

3. Solid-phase microextraction

            3.1 MOFs-based composites

            3.2 COFs-based composites

            3.3 Graphene-based composites

            3.4 Other carbon-based composites

4. Conclusion

Acknowledgements

References

4)Chapter Four: Composite Materials for Ballistic Applications

Ali Imran AYTEN^1*, Mehmet Atilla TASDELEN^1*

¹Department of Polymer Materials Engineering, Faculty of Engineering, Yalova University, 77200 Yalova, Turkey

*Corresponding author email: tasdelen@yalova.edu.tr (M.A.T.)

            Abstract

            1. Introduction to Ballistics

            2. Ballistic Threats     

            3. Fiber Types for Ballistic Protection

                        3.1 Para-Aramid Fibers

                        3.2. Ultra-High Molecular Weight Polyethylene Fibers

                        3.3. Glass Fibers

                        3.4. Carbon Fibers

            4. Fabric Types

                        4.1 Fabric Structures

            5. Ballistic Impact Mechanisms

            5.2. Ballistic impact in composite laminates

            5.3. Failure Mechanisms of Fabrics and Composites

            5.4. Performance parameters of ballistic materials against ballistic impact                               loading

            5.5. Numerical modeling in ballistic fabric and composite structures

6. Future Trends

7. Summary

    References

5)Chapter Five: Additive manufacturing for complex geometries in polymer composites

López-Barroso Juventino¹, Flores-Hernández Cynthia Graciela¹, Martínez-Hernández Ana Laura¹, Gonzalo Martínez-Barrera², Velasco-Santos Carlos¹,*

¹División de Estudios de Posgrado e Investigación. Tecnológico Nacional de México Campus Querétaro, Santiago de Querétaro, Querétaro, 76000, México

² Facultad de Química. Universidad Autónoma del Estado de México, Toluca, Estado de México, 50210, México.

*Corresponding author E-mail: cylaura@gmail.com

Abstract

1. Introduction

2. Additive manufacturing for complex geometries 

3. Complex Geometry

            3.1 Fully functional assemblies (FFA)

            3.2 4D printed structures

            3.3 Gradient structures (GDS)

            3.4 Cellular materials

4. Design for AM complex geometries

            4.2 CAE tools

            4.3 CAM tools

5. Printing complex geometry composites

            5.1 Extrusion based composites

                        5.2.1 Stereolithography

                        5.2.2 The Digital Light Processing (DLP)

                        5.2.3 Continuous liquid interface production

            5.3 Selective laser sintering

            5.4 Material jetting

            5.5 Sheet lamination

6. Applications

            6.1 Medical field

            6.2 Electronic field

            6.3 Structural 3D composites

            6.4 Other applications

7. Future trends and limitation

8. Concluding remarks

6)Chapter Six: Eco/Friendly polymer based composites for nuclear shielding applications

F. Akman^1,2,*, H. Ogul^3,4, M.R. Kaçal⁵, H. Polat⁶, K. Dilsiz⁷, O. Agar⁸

¹Bingöl University, Vocational School of Social Sciences, Department of Property Protection and Security, Program of Occupational Health and Safety, 12000 Bingöl, Turkey

²Bingöl University, Central Laboratory Application and Research Center, 12000 Bingöl, Turkey

³Department of Nuclear Engineering, Faculty of Engineering and Architecture, Sinop University, Sinop, Turkey.

⁴Department of Physics and Astronomy, Faculty of Science, University of Iowa, Iowa City, IA, USA

⁵Giresun University, Faculty of Arts and Sciences, Department of Physics, 28100 Giresun, Turkey

⁶Bingöl University, Vocational School of Technical Sciences, Department of Architecture and Urban Planning, 12000, Bingöl, Turkey

⁷Bingöl University, Faculty of Art and Science, Department of Physics, 12000, Bingöl, Turkey

⁸Karamanoğlu Mehmetbey University, Department of Physics, Karaman, Turkey

*Corresponding author email: fakman@bingol.edu.tr

Abstract

1. Introduction

2. Literature Review on Polymer Based Shielding Composites

3. Materials and Method

            3.1. Production of polymer- based composites

            3.2. Radiation Shielding Performances

                        3.2.1. Theoretical background

                        3.2.2. Experimental details

                        3.2.4. Theoretical estimations

4. Results and Discussions

            4.1. Evaluation of Gamma Shielding Effect of the Material

            4.2. Evaluation of Neutron Shielding Effect of the Material

5. Summary

References

7)Chapter Seven: Mechanical and Tribological Behaviour of Hybrid Polymer and Hybrid Sandwich Composites

Vasavi Boggarapu ¹, Raghavendra Gujjala ^*1, Syam Prasad ², Shakuntala Ojha ³, Om Prakash Mingu ³

¹ Department of Mechanical Engineering, National Institute of Technology, Warangal, Telangana, India

² Department of Physics, National Institute of Technology, Warangal, Telangana, India

³ Department of Mechanical Engineering, Kakatiya Institute of Technology and Science, Warangal, Telangana, India

*Corresponding author email: raghavendra.gujjala@nitw.ac.in

Abstract

1. Introduction

2 Materials and Fabrication process

            2.1 Raw materials

            2.2 Fabrication of composite samples

                        2.2.1 Preparation of particulate composite samples

                        2.2.2 Manufacturing of hybrid polymer nano composite samples

                        2.2.3 Fabrication of novel hybrid sandwich composite samples

3. Experimental methods

            3.1 Mechanical testing

            3.2 Tribological testing

                        3.2.1 Erosion test

                        3.2.2 Abrasive wear test

4. Results and discussion

            4.1 Advance Particulate composites

                        4.1.1 Mechanical testing results

                        4.1.2 Erosion wear test results

                        4.1.3 Abrasive wear test results

            4.2 Hybrid polymer composites

                        4.2.1 Mechanical testing results

                        4.2.2 Erosion wear test results

                        4.3.1 Erosion wear test results

                                    4.3.1.1 Effect of impingement angle on erosion wear

                                    4.3.1.2 Effect of impact velocity on erosion wear

5. Conclusions

    References

8)Chapter Eight: Nanocomposites Based on Conducting Polymers and Nanomaterials Derived from Natural Polymers

Alessandra Alves Correa^1,2, Ana Carolina Correa^1,2, Kelcilene Bruna Ricardo Teodoro², José Manoel Marconcini^1,2, Lucia Helena Mascaro³

¹ PPCEM, Department of Materials Engineering, Center for Exact Sciences and Technology, Federal University of São Carlos (UFSCar), São Carlos, SP, Brazil

² Nanotechnology National Laboratory for Agriculture, Embrapa Instrumentação, São Carlos, SP, Brazil

³ PPGQ, Department of Chemistry, Center for Exact Sciences and Technology, Federal University of São Carlos (UFSCar), São Carlos, SP, Brazil

alealvescorrea@gmail.com; carol_correa@hotmail.com; kbr.teodoro@gmail.com; jose.marconcini@embrapa.br;

Corresponding author email: lmascaro@ufscar.br

Abstract

1. Introduction

            1.1. Conducting polymers: polyaniline, polypyrrole and polythiophene

            1.2. Examples of nanomaterials based in natural polymers

                        1.2.1. Polysaccharides

                        1.2.2. Polypeptides or Proteins

                        1.2.3. Polyester

                        1.2.4. Polyisoprenes

2. Conducting polymer-natural polymers nanocomposites

            2.1. Nanocomposites - thin films

            2.2. Nanocomposites - nanofibers

            2.3. Nanocomposites - conductive nanopapers and flexible substrates

3. Technological applications of conducting-natural polymers composites

            3.1. Sensors and biosensors

            3.2. Medical applications

            3.3. Energy storage devices

4. Final Remarks

   Acknowledgments

References

9)Chapter Nine: Mechanical and sliding wear performance of ZA27-Gr alloy composites for bearing applications: Analysis using Preference Selection Index Method

Ashiwani Kumar^1*, Mukesh Kumar²

¹Mechanical Engg.Dept., Feroze Gandhi Institute of Engg.& Tech., Rae Bareli-229316, U.P, INDIA

²Mechanical Engg. Dept., Malaviya National Institute of Tech., Jaipur-302017, Rajasthan, INDIA

*Corresponding author e-mail: ashi15031985@gmail.com

Abstract:        

1. Introduction          

2. Materials and methodology          

            2.1. Materials, Design and Fabrication procedure   

            2.2. Physical and Mechanical characterization         

            2.3. Multi-specimen dry sliding wear Tribo-meter   

            2.4. Experimental Design and Surface Morphology Studies          

            2.5. Preference Selection Index method algorithms

3. Result and discussion        

            3.1. Physical and Mechanical characteristics           

                        3.1.1. Effect of voids content / density of developed composite     

                        3.1.2. Effect of Hardness      

                        3.1.3. Effect of Flexural Strength     

                        3.1.4. Effect of tensile strength         

                        3.1.5. Effect of Impact strength        

                        3.1.6. Effect of compressive strength           

            3.2. Steady State Specific Wear Condition  

            3.3. Analysis of Experimental Results by Taguchi Experimental Design  

            3.4. Surface Morphology      

            3.5. Ranking Optimization using PSI Method.        

 4. Conclusions          

Acknowledgement:   

References:    

10)Chapter Ten: Mechanical and Tribological aspects of Aluminium alloy composites for Gear application - A Review

Ashiwani Kumar ¹*, Mukesh Kumar ²

¹ Mechanical Engg. Deptt., Feroze Gandhi Inst. of Engg. & Tech., Raebareli-229316, U.P., INDIA

² Mechanical Engg. Deptt., Malaviya National Inst.of Tech., Jaipur-302017, Rajasthan, INDIA

*Corresponding author e-mail: ashi15031985@gmail.com

Abstract:        

1.         Introduction   

2.         Mechanical characteristics of metal alloy composites         

3. Tribological behaviour      

            3.1 Effect of wear parameters

                        3.1.1. Normal load    

                        3.1.2. Sliding velocity           

                        3.1.3 Sliding distance

            3.2. Influence of material factors of metal alloy composite 

                        3.2.1.   Influence of reinforcement type of metal alloy composite  

                        3.2.2. Influence of reinforcement content of metal alloy composite           

                        3.2.3. Influence of particle size of metal alloy composite   

                        3.2.4. Influence of reinforcement shape of metal alloy composite  

            3.3. Wear mechanisms of metal alloy composites   

4. Scope for future research work

5. Conclusions

Acknowledgement    

References:    

11)Chapter Eleven: Microcavity Mediated Light Emissions from Plasmonic and Dielectric Composites

Xianguang Yang, Jiahao Yan, and Baojun Li

Institute of Nanophotonics, Jinan University, Guangzhou 511443, China

Correspondence to: xianguang@jnu.edu.cn or baojunli@jnu.edu.cn

Abstract

1. Introduction

2. Methods

3. Plasmonic composites

4. Dielectric composites

5. Conclusion

Acknowledgements

References

12)Chapter Twelve: Fabrication and Application of Graphene Composite Materials

^aDepartment of Chemistry, Banasthali Vidyapith, Banasthali, Rajasthan, India

*Corresponding author email: sagermanish1@gmail.com

Abstract

1. Introduction

            1.1 Importance of Graphene Composite:

            1.2 Graphene-Composite materials

2. Classification of   graphene composite materials

            2.1 Graphene/polymer composite

            2.2 Graphene/Inorganic composite

                        2.2.2 In-situ hybridization

                        2.2.3 Graphene-Aluminum Composites

3. Fabrication and characterization of graphene composite materials

            3.1 In Situ Polymerization/Crystallization

            3.2 Chemical Reduction

            3.3 Sol-Gel Methods

            3.4 Colloidal Processing

            3.5 Powder processing

            3.6 Microwave-assisted synthesis of metal/graphene composites

4. Fabrication of Advanced Graphene materials

            4.1Quantum dots of Graphene

                        4.1.1 Fabrication of quantum dots of Graphene

            4.2 Graphene and derived nano filler

                        4.2.1 Fabrication of graphene and derived nano filler

                        4.2.2 Significance of graphene and derived nano filler

                        4.2.3 Application of graphene and derived nano filler in energy and                                           electronics

            4.3 Graphene aerogels

            4.4 Hybrid graphene / microfiber composites

            4.5 Graphene bioactive composites

5. Applications of graphene composite materials

            5.1 Structural reinforcement materials

            5.2 Sensors

            5.3 Water treatment

            5.4 Biomedical Applications

                        5.4.2 Gene Delivery

                        5.4.3 Cancer Therapy

6. Conclusion

      Reference

13)Chapter Thirteen: Sustainable grinding performances of Nano SiC reinforced Al matrix composites under Minimum Quantity Lubrication (MQL)

A.Nandakumar¹ T.Rajmohan²  S.Vijayabhaskar³

¹Department of Mechanical Engineering, Sri Chandrasekharendra Saraswathi ²Viswa Maha Vidyalaya, Enathur, Kanchipuram, India – 631561,

¹nandakumar.a@kanchiuniv.ac.in, ²rajmohanscsvmv@yahoo.com

Abstract

1.   Introduction

2.   Materials and methods

      2.1 Materials

      2.2 Experimental design and procedure

3.   Results and discussions

      3.2 Development of D-optimal Design models based on RSM

      3.3 Examination of the Quadratic Mathematical Model

      3.4 Multi-response optimization of grinding parameters based on desirability             analysis

      3.5 Confirmation experiments

      3.6 Effect of grinding parameters on responses

      3.7 Effect of MQL systems on the desirability

      3.8 Surface morphology of the machined surface

      3.9 Surface Roughness Analysis using AFM

      3.10 Surface morphology of grinding wheel surface

4.   Conclusions

       References

14)Chapter Fourteen: Waste-based zeolites and their advanced composites for wastewater and environmental remediation applications

Niladri Shekhar Samanta^a, Piyal Mondal^b, Mihir K. Purkait^a,b*

^a Center for the Environment, Indian Institute of Technology Guwahati, Assam-781039 India

^b Department of Chemical Engineering, Indian Institute of Technology Guwahati, Assam-781039 India

Abstract

1.   Introduction

2. Zeolite and synthesis methods

      2.1. Zeolite minerals

      2.2 Zeolite synthesis methods

                              2.2.1 Direct Hydrothermal Method

                              2.2.2 Two-step Hydrothermal synthesis technique

                              2.2.3 Fusion-facilitated alkaline Hydrothermal Treatment

                              2.2.4 Microwave-assisted Method

                              2.2.5 Fusion-assisted ultrasonic (US) hydrothermal treatment

                              2.2.6 Molten-salt method

                              2.2.7 Microwave (MW) hydrothermal treatment with pulverization process

                              2.2.8 Ball milling, solvent-free synthesis

3. Zeolite properties

      3.1 Zeolite Structure

      3.2 Adsorption and ion exchange phenomena

                              3.2.1 Adsorption phenomena in zeolites

                              3.2.2 Ion exchange phenomena in zeolites

                              3.2.3 Cations and acidity in zeolites

4. Preparation of zeolites from wastes

      4.1. Industrial or plant waste

                              4.1.1. Coal fly ash (CFA)

      4.2. Biomass ash

                              4.2.1. Rice husk ash (RHA)

                              4.2.2. Palm oil mill fly ash (POMFA)

                              4.2.3. Sugarcane bagasse fly ash (SCBFA)

5. Zeolite-composites for environmental remediation applications

      5.1. Cation removal

      5.2. Dye removal

      5.3. Harmful-gas removal

6. Zeolite-composites membrane for environmental remediation applications

      6.1. Cation removal

      6.2. Dye removal

      6.3. Harmful-gas removal

7. Recent advancements and future scope

8. Conclusion

15)Chapter Fifteen: Advanced composites for drug adsorption

Thaís Strieder Machado¹*, Brenda Isadora Soares Damin², Giovana Marchezi³, Larissa Crestani³, Jeferson Steffanello Piccin^1,2,3

¹ Postgraduate Program in Civil and Environmental Engineering, Faculty of Engineering and Architecture, University of Passo Fundo, Passo Fundo/RS, Brazil.

² Postgraduate Program in Food Science and Technology, Faculty of Agronomy and Veterinary Medicine, University of Passo Fundo, Passo Fundo/RS, Brazil.

³ Chemical Engineering Course, Faculty of Engineering and Architecture, University of Passo Fundo, Passo Fundo/RS, Brazil.

*Corresponding author email: thaiis.strieder@hotmail.com

1. Introduction

 2. Composites classifications

            2.1 Composite definitions and classifications

                                    2.1.1 According to the matrix phase

                        2.1.2 According to the dispersed phase

3. General concepts of the adsorption technique in liquid medium

                        3.1 Physical and chemical adsorption and factors that influence this                             phenomenon

                        3.2 Adsorption isotherm

                        3.3 Adsorption kinetics

                        3.4 Fixed bed adsorption

                        3.5 Development of adsorbent composites used in adsorption

4. Composite materials for drug adsorption: bibliometric and systematic review

            4.1 Development of composites with organic materials

            4.2 Development of composites with inorganic materials

5. Conclusion and future perspectives

                Acknowledgments

16)Chapter Sixteen: Advances in manufacturing and process of discontinuous particle reinforced titanium matrix composites (TMCs)

^a Hubei Key Laboratory of Advanced Technology for Automotive Components, Wuhan University of Technology, Wuhan 430070, P.R. China

^b Hubei Collaborative Innovation Center for Automotive Components Technology, Wuhan University of Technology, Wuhan 430070, P.R. China

^c State Key Laboratory of Metal Matrix Composites, School of Materials Science and Engineering, Shanghai Jiao Tong University, No. 800 Dongchuan Road, Shanghai 200240, P.R. China

^d School of Engineering, Edith Cowan University, 270 Joondalup Drive, Joondalup, Perth, WA 6027, Australia

* Corresponding author emails: xielechun@whut.edu.cn, lechunxie@yahoo.com (L. Xie).

Abstract

1. Introduction

            1.1 Titanium matrix composites (TMCs)

            1.2 Advantages of TMCs

            1.3 Applications of TMCs

2. Process of discontinuous particle reinforced TMCs

            2.1 Synthesis of discontinuous particle reinforced TMCs

            2.2 In-situ processing technique

            2.3 Additive manufacturing on TMCs

                        2.3.1 Selective laser melting (SLM) on TMCs

                        2.3.2 Direct laser deposition (DLD) on TMCs

3. Treatment on TMCs

            3.1 Heat treatment on TMCs

            3.2 Electro-pulsing treatment (EPT) on TMCs

Acknowledgements   

References

17)Chapter Seventeen: Metal based Electrical Contact Materials

Temel Varol^a* and Onur Güler^a

^aDepartment of Metallurgical and Materials Engineering, Engineering Faculty,

Karadeniz Technical University, Trabzon, Turkey

^*tvarol@ktu.edu.tr

Abstract

1. Introduction to Electrical Contact Materials

2. Performance requirements of Electrical Contact Materials

3. Metal Based Electrical Contact Materials

4. Fabrication Methods of Electrical Contact Materials

      4.1. Casting

      4.2. Powder Metallurgy

      4.3. Internal Oxidation Process

      4.4. Infiltration Process

5. New Methods for the Fabrication of Electrical Contact Materials

      5.1. Development of Powder Properties

      5.2. Equal Channel Angular Pressing

      5.3. Additive Manufacturing Process

6. Conclusions

    Acknowledgement

    References

18)Chapter Eighteen: Organosulfur polymer composites by free radical polymerization of sulfur with vegetable oils

Amin Abbasi¹, Ali Shaan Manzoor Ghumman¹, Mohamed Mahmoud Nasef^2,*, Wan Zaireen Nisa Yahya¹, Muhammad Rashid Shamsuddin¹, and Muhammad Moniruzzaman¹

¹Chemical Engineering Department, Universiti Teknologi PETRONAS, 32610 Seri Iskandar, Perak, Malaysia.

²Department of Chemical and Environmental Engineering, Malaysia Japan International Institute of Technology, Universiti Teknologi Malaysia Kuala Lumpur, Jalan Sultan Yahya Petra 54100 Kuala Lumpur, Malaysia.

*Corresponding author email: mahmoudeithar@cheme.utm.my

Abstract

1. Introduction

2. Free radical polymerization of sulfur at molten state/Inverse vulcanization

3. Overview of organosulfur polymeric composites using vegetable oils

            3.1. Preparation of the organosulfur polymeric composites using vegetable oils

            3.2. Properties of the organosulfur polymeric composites using vegetable oils

                        3.2.1. Physical properties

                        3.2.2. Chemical Composition

                        3.2.3. Thermal behavior

                        3.2.4. Structural Properties

                        3.2.5. Morphological properties        

            3.3. Applications of the organosulfur polymeric composites using vegetable oils

4. Challenges and future perspective

5. Conclusion

    References:

Shadia J. Ikhmayies had received the B.Sc. and M.Sc. from the physics department in the University of Jordan in 1983 and 1987, respectively, and the Ph.D. in producing CdS/CdTe thin-film solar cells from the same university in 2002. Her research is focused on producing and characterizing semiconductor thin films and thin-film CdS/CdTe solar cells. Besides, she works in characterizing quartz in Jordan for the extraction of silicon for solar cells and characterizing different materials by computation. She is the founder and the editor of the book series “Advances in Material Research and Technology” published by Springer and the editor of several books.

This book presents a comprehensive collection of reviews and experimental research findings in the realm of composite materials. It explores manufacturing technologies and applications, as well as recent breakthroughs in nanomaterial-based composites, polymer-based composites, titanium matrix composites (TMCs), conducting polymers, natural polymers, graphene polymers, graphene composites, and organosulfur polymeric composites, alongside reinforced aluminum matrix composites. The mechanical and tribological aspects take center stage, with a focus on aluminum alloy composites as a superior alternative to traditional gear materials. The book also addresses cutting-edge composite materials developed for drug removal via adsorption techniques, radiation shielding, and their use as shielding absorbers for ionizing radiation. Furthermore, the significance of electrical contact materials and their performance is explored. The book unveils fabrication methods, sample preparation techniques, properties, and various applications of these remarkable composites. Topics range from additive manufacturing to solid-phase extraction and solid-phase microextraction utilizing diverse composites as adsorbents. Additionally, the inverse vulcanization process, a novel technique involving the copolymerization of elemental sulfur with different monomers based on their resource origins, is discussed. Technologies such as powder metallurgy (PM), mechanical alloying (MA), self-propagating high-temperature synthesis (SHS), and rapid solidification processing (RSP) are described. The book further delves into the preparation techniques of zeolite using both conventional and advanced methods, along with the synthesis of various zeolite-based composites, particularly their application in environmental remediation. The book culminates with a summary of analysis and modeling techniques used in composite materials, including those employed in ballistic applications.