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El. knyga: Magnetic Nanoparticle-Based Hybrid Materials: Fundamentals and Applications

Edited by , Edited by (Assistant Professor, Bu-Ali Sina University, Hamedan, Islamic Republic of Iran), Edited by (Assistant Professor, School of Electr), Edited by , Edited by (Professor for Measurement, Physics, and Textile Technologies, Bielefeld University of Applied Sciences, Germany)
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Magnetic Nanoparticle-Based Hybrid Materials: Fundamentals and Applications introduces the principles, properties, and emerging applications of this important materials system. The hybridization of magnetic nanoparticles with metals, metal oxides and semiconducting nanoparticles may result in superior properties. The book reviews the most relevant hybrid materials, their mechanisms and properties. Then, the book focuses on the rational design, controlled synthesis, advanced characterizations and in-depth understanding of structure-property relationships. The last part addresses the promising applications of hybrid nanomaterials in the real world such as in the environment, energy, medicine fields.

Magnetic Nanoparticle-Based Hybrid Materials: Fundamentals and Applications comprehensively reviews both the theoretical and experimental approaches used to rapidly advance nanomaterials that could result in new technologies that impact day-to-day life and society in key areas such as health and the environment. It is suitable for researchers and practitioners who are materials scientists and engineers, chemists or physicists in academia and R&D.

  • Provides in-depth information on the basic principles of magnetic nanoparticles-based hybrid materials such as synthesis, characterization, properties, and magnon interactions
  • Discusses the most relevant hybrid materials systems including integration of metals, metal oxides, polymers, carbon and more
  • Addresses the emerging applications in medicine, the environment, energy, sensing, and computing enabled by magnetic nanoparticles-based hybrid materials

Recenzijos

"Many new advances in magnetic nanoparticle materials (MNPs) and a plethora of new applications have recently occurred in a wide variety of scientific fieldsThis book provides the background and review of the  most recently developments in hybrid nanomaterials, their fundamentals, both theoretical and experiemental, and properties...." --IEEE - Electrical Insulation Magazine

List of contributors
xv
Part I Basic principles
1(250)
1 Magnetic nanoparticles: synthesis and characterization
3(30)
Ladan Rashidi
1.1 Introduction
3(1)
1.2 Synthesis of magnetic nanoparticles
3(17)
1.3 Characterization of magnetic nanoparticles
20(5)
1.4 Conclusion
25(8)
References
25(8)
2 Magnetic nanoparticles: fabrication, characterization, properties, and application for environment sustainability
33(32)
Paritosh Patel
Aditya Nandi
Ealisha Jha
Adrija Sinha
Swabhiman Mohanty
Pritam Kumar Panda
Suman Mishra
Suresh K. Verma
Mrutyunjay Suar
2.1 Introduction
33(2)
2.2 Applications of nanoparticles
35(4)
2.3 Magnetic nanoparticles
39(3)
2.4 Synthesis of magnetic nanoparticles
42(6)
2.5 Characterization of magnetic nanoparticles
48(3)
2.6 Magnetic nanoparticle applications
51(1)
2.7 Application for environmental sustainability
52(4)
2.8 Conclusion
56(9)
References
57(8)
3 Ferrite-gold magnetoplasmonic nanohybrids for bimodal heating by magnetic hyperthermia and photothermia
65(26)
Enzo Bertuit
Ali Abou-Hassan
3.1 Introduction
65(2)
3.2 Magnetic ferrite nanoparticles
67(7)
3.3 Magnetic properties of ferrite nanoparticles
74(5)
3.4 Magnetoplasmonic nanohybrids
79(7)
3.5 Conclusion
86(5)
References
86(5)
4 Magnetic polymer hybrid nanomaterials
91(30)
Anca Florea
Bogdan Feier
Mihaela Tertis
Oana Hosu
Adrian Blidar
Cecilia Cristea
4.1 Introduction
91(1)
4.2 Stability of magnetic polymer nanoparticles
92(1)
4.3 Classification of metal-polymer nanoparticles
92(3)
4.4 Preparation of magnetic polymer nanoparticles
95(2)
4.5 Magnetic nanoparticles as support for molecularly imprinted polymers
97(3)
4.6 Applications of magnetic nanoparticle-polymer hybrid materials
100(13)
4.7 Conclusions
113(8)
Acknowledgments
113(1)
References
113(8)
5 Hybrid Magnetic nanoparticles--Carbonaceous nanomaterials (carbon nanotube/graphene)
121(18)
Seyyed Mojtaba Mousavi
Khadije Yousefi
Seyyed Alireza Hashemi
Sonia Bahrani
5.1 Introduction
121(1)
5.2 Classification of magnetic carbon nanostructures
122(1)
5.3 Methods of magnetic-graphene preparation
123(8)
5.4 Therapeutic applications
131(4)
5.5 Conclusion
135(4)
References
135(4)
6 Magnetic nanoparticle-polymer hybrid materials
139(44)
Samoa Salem
Erkan Yilmaz
6.1 Introduction
139(1)
6.2 Metal and metal oxide nanoparticles
140(2)
6.3 Dilute magnetic semiconductors
142(1)
6.4 Polymer-based magnetism
142(1)
6.5 Synthesis of magnetic nanoparticles
143(9)
6.6 Properties of magnetic nanoparticles
152(1)
6.7 Applications of magnetic nanoparticles
153(1)
6.8 Magnetic nanocomposites
154(3)
6.9 Synthesis of magnetic polymer nanocomposites
157(7)
6.10 Removal of heavy metals
164(1)
6.11 Cancer diagnosis and therapy
165(2)
6.12 Conclusions
167(16)
References
168(15)
7 Magnetic nanoparticle-polymer nanohybrids
183(26)
Marziyeh Fathi
Elaheh Dalir Abdollahinia
Nazanin Amiryaghoubi
Hossein Omidian
Yadollah Omidi
7.1 Introduction
183(1)
7.2 Preparation, modification, and characterization of magnetic nanoparticle-polymer nanohybrids
184(1)
7.3 Applications
185(10)
7.4 Toxicity of magnetic nanoparticles polymers nanohybrids
195(4)
7.5 Clinical relevance and future prospects
199(2)
7.6 Conclusion
201(8)
References
201(8)
8 Magnetic nanomaterial turbulent flow considering ferrohydrodynamics
209(22)
M. Sheikholeslami
M. Jafaryar
Mikhail A. Sheremet
Ahmad Shafee
8.1 Introduction
209(1)
8.2 Configuration of pipe and modeling
210(2)
8.3 Result and discussion
212(16)
8.4 Conclusion
228(3)
References
228(3)
9 Magnon-electron interaction in magnetic nanoparticle--based hybrid materials
231(20)
Nahid Ahmadi
Ali Ramazani
9.1 Introduction
231(1)
9.2 Electron-magnon interaction in ferromagnetic semiconductors
232(4)
9.3 The effect of electron-magnon interaction on electronic and magnetic properties
236(5)
9.4 The effect of electron-magnon interaction on the band structure
241(1)
9.5 Electron-magnon interaction effect in charge and spin currents
242(5)
9.6 Conclusion
247(4)
References
248(3)
Part II Biomedical applications
251(248)
10 Biomedical applications of magnetic hydrogels
253(20)
Mari C. Manas-Torres
Cristina Gila-Vilchez
Juan D.G. Durdn
Modesto T. Lopez-Lopez
Luis Alvarez de Cienfuegos
10.1 Introduction
253(3)
10.2 Drug delivery applications
256(2)
10.3 Tissue engineering applications
258(3)
10.4 Injectable hydrogels
261(2)
10.5 Biosensors and biomarkers
263(2)
10.6 Conclusion
265(8)
Acknowledgments
265(1)
References
265(8)
11 Coprecipitation synthesis, stabilization, and characterization of oleic acid-coated iron oxide nanoparticles for magnetically oriented hybrid system vectorization
273(30)
Maria Ines Ferreira
Tarda Cova Jose A. Paixdo
Alberto Pais
Carla Vitorino
11.1 Introduction
273(1)
11.2 Approaches to iron oxide nanoparticles synthesis
273(2)
11.3 Designing iron oxide nanoparticles: an example
275(2)
11.4 Optimizing iron oxide nanoparticles
277(11)
11.5 Oleic acid-coated iron oxide nanoparticles: toward magnetically oriented hybrid nanosystems
288(3)
11.6 Computationally assisted design of hybrid iron oxide nanoparticles
291(5)
11.7 Conclusions
296(7)
Acknowledgments
296(1)
References
297(6)
12 Magnetic nanoparticles-based hybrid materials for hyperthermia cancer treatments
303(16)
Laura M. Sanchez
12.1 Introduction
303(1)
12.2 Hyperthermia and hybrid magnetic nanomaterials
303(8)
12.3 Conclusions and future perspectives
311(8)
Acknowledgments
313(1)
References
313(6)
13 Magnetic hybrid nanoparticles for drug delivery
319(24)
Swati Singh
Harshita Chawla
Amrish Chandra
Seema Garg
13.1 Introduction
319(1)
13.2 Methods for the synthesis of magnetic nanoparticles
319(3)
13.3 Types of magnetic field
322(1)
13.4 Advantages of magnetic nanoparticle-based drug delivery systems
323(1)
13.5 Factors affecting magnetic nanoparticle-based drug delivery
324(1)
13.6 Application of magnetic hybrid nanoparticles in drug delivery
325(9)
13.7 Limitations of magnetic nanoparticle-based drug delivery
334(1)
13.8 Conclusion
334(9)
References
335(8)
14 Hybrid magnetic nanoparticles for multimodal molecular imaging of cancer
343(44)
Yurena Luengo Morato
Marzia Marciello
Laura Lozano Chamizo
Karina Ovejero Paredes
Marco Filice
14.1 Introduction
343(1)
14.2 Cancer biology
344(1)
14.3 Basic elements of cancer disease useful for nanoparticle applications
344(3)
14.4 Multimodal molecular imaging in cancer disease
347(3)
14.5 Magnetic nanoparticles for magnetic resonance imaging
350(8)
14.6 Hybrid magnetic nanoparticles as magnetic resonance imaging-optical dual-mode imaging agents
358(6)
14.7 Hybrid magnetic nanoparticles for magnetic resonance imaging-positron emission tomography (MRI-PET), magnetic resonance imaging-single-photon emission computed tomography (MRI-SPECT) or magnetic resonance imaging-computed tomography (MRI-CT) dual-mode imaging agents
364(4)
14.8 Magnetic nanoparticle-based nontraditional multimodal imaging
368(8)
14.9 General remarks and future perspectives
376(11)
Acknowledgments
377(1)
References
377(10)
15 Magnetic nanoparticle-based hybrid materials in the biomedical field: fundamentals and applications
387(38)
Kwaku Baryeh
Mohammed Attia
Joshua Chaj Ulloa
Jing Yong Ye
15.1 Brief history of magnetic materials and their nanohybrids
387(2)
15.2 Synthesis and functionalization/hybridization
389(9)
15.3 Magnetic nanocomposites for imaging and diagnostic application
398(5)
15.4 Magnetic nanohybrids for biosensing application
403(3)
15.5 Therapeutics based on magnetic nanohybrids
406(5)
15.6 Summary and perspectives
411(14)
References
412(13)
16 Magnetic nanoparticles in cancer therapy
425(22)
Mohsen Khodadadi Yazdi
Payam Zarrintaj
Ali Khodadadi
Mohammad Reza Ganjali
Babak Bagheri
Sajjad Habibzadeh
Mohammad Reza Saeb
Masoud Mozafari
16.1 Introduction
425(2)
16.2 Physical properties of MNPs
427(2)
16.3 Synthesis, surface decoration, and functionalization of MNPs
429(1)
16.4 MNPs in cancer diagnosis
430(1)
16.5 MNPs in cancer treatment
431(1)
16.6 Theranostic MNPs
432(2)
16.7 Mathematical modeling
434(5)
16.8 Conclusion
439(8)
References
440(7)
17 Medical applications of multifunctional magnetic nanoparticles
447(16)
Ayuob Aghanejad
Hossein Omidian
Yadollah Omidi
17.1 Introduction
447(1)
17.2 A glance at magnetic nanoparticle synthesis and modification
448(1)
17.3 Basic and clinical applications of magnetic nanoparticles
449(8)
17.4 Conclusion
457(6)
Conflict of interests
458(1)
References
458(5)
18 Biomedical applications of magnetic nanoparticles
463(36)
Muzahidul I. Anik
M. Khalid Hossain
Imran Hossain
Isteaque Ahmed
Rashed M. Doha
18.1 Introduction
463(1)
18.2 Magnetic nanoparticles
464(4)
18.3 Biomedical applications
468(17)
18.4 Conclusion and outlook
485(14)
Acknowledgments
486(1)
References
486(13)
Part III Environmental applications
499(118)
19 Antimicrobial activity of hybrid organic--inorganic core--shell magnetic nanocomposites
501(28)
Dmitry Zablotsky
Izolda Segal
Alia Zablotskaya
Mikhail Maiorov
Tuan Anh Nguyen
19.1 Introduction
501(2)
19.2 Inorganic core
503(6)
19.3 Surface functionalization
509(9)
19.4 Conclusion
518(11)
References
519(10)
20 Environmental applications of magnetic nanoparticles
529(18)
Ilgook Kim
Hee-Man Yang
Chan Woo Park
In-Ho Yoon
Youngho Sihn
20.1 Introduction
529(1)
20.2 Removal of contaminants using magnetic nanoparticles
530(8)
20.3 Toxic effects of magnetic nanoparticles on the environment
538(2)
20.4 Conclusions
540(7)
References
541(6)
21 Magnetic nanoparticles in wastewater treatment
547(44)
Javad Farahbakhsh
Wahid Vatanpour
Mohammad Reza Ganjali
Mohammad Reza Saeb
21.1 Introduction
547(2)
21.2 Different types of MNPs
549(3)
21.3 Synthesis of MNPs
552(4)
21.4 Magnetic nanoadsorbents in wastewater treatment
556(11)
21.5 Magnetic nanophotocatalysts for removal of pollutants from wastewater
567(2)
21.6 The use of MNPs in filtration process
569(5)
21.7 The demulsification of oil wastewaters using MNPs
574(1)
21.8 Magnetic flocculation technology
575(2)
21.9 Recent developments
577(1)
21.10 Major challenges and future prospects
578(13)
References
579(12)
22 Magnetic hybrid nanoparticles for environmental remediation
591(26)
Elvis Ikechukwu Nosike
Yujie Zhang
Aiguo Wu
22.1 Introduction
591(2)
22.2 Application in the removal of heavy metal ions
593(2)
22.3 Application in the removal of organic contaminants and dyes
595(3)
22.4 Application in the remediation of oil spills
598(1)
22.5 Application in environmental sensing
599(2)
22.6 Application as photocatalysts
601(1)
22.7 Application in water splitting for generation of environmentally friendly hydrogen
602(3)
22.8 Other environmental applications of magnetic nanoparticles
605(1)
22.9 Conclusion
606(11)
Acknowledgments
607(1)
References
607(10)
Part IV Applications for sensor, catalysis and analytical processes
617(104)
23 Magnetic hybrid nanocatalysts
619(18)
Reza Taheri-Ledari
Ali Maleki
23.1 Introduction to the magnetic nanocatalysts
619(1)
23.2 Classification of the magnetic nanocatalysts
620(2)
23.3 Effects of the structure, size, and morphology on the catalytic performance
622(1)
23.4 Synergies in the catalytic applications
622(4)
23.5 Biodegradability and biocompatibility
626(1)
23.6 Organic catalysis by magnetic nanocomposites
627(3)
23.7 Turnover number and turnover frequency
630(1)
23.8 Recyclability
631(1)
23.9 Conclusion and future perspective
631(6)
References
632(5)
24 Magnetic hybrid nanoparticles for improvements in analytical processes
637(42)
Rosa Carmen Rodriguez Martih-Doimeadios
Angel Ribs
Francisco Javier Guzman Bernardo
Mohammed Zougagh
24.1 Introduction
637(1)
24.2 Improvements in sample preparation
638(12)
24.3 Improvements in analyte separation
650(3)
24.4 Improvements in analyte detection
653(11)
24.5 Conclusions and perspectives
664(15)
References
665(14)
25 Hybrid magnetic nanoparticles for electrochemical biosensors
679(42)
Anabel Villalonga
Reynaldo Villalonga
Diana Vilela
25.1 Introduction
679(2)
25.2 Hybrid magnetic nanoparticles
681(7)
25.3 Methods for the synthesis of hybrid magnetic nanoparticles for electrochemical biosensing
688(6)
25.4 Applications of hybrid magnetic nanoparticles for electrochemical biosensors
694(15)
25.5 Conclusions and outlook
709(12)
Acknowledgments
710(1)
Abbreviations and acronyms
710(1)
References
711(10)
Index 721
Dr. Andrea Ehrmann is a full professor for measurement, physics, and textile technologies at Bielefeld University of Applied Sciences in Germany. After studying physics at RWTH Aachen, she earned a PhD in the area of magneto-optical investigations on exchange-bias systems. Afterwards, Dr. Ehrmann worked at Niederrhein University of Applied Sciences on Intelligent Textiles, knitted fabrics etc. Dr. Mazaher Ahmadi received his Ph.D. in Analytical Chemistry from Bu-Ali Sina University in 2017. He has been to Alicante University, Spain, and Stockholm University, Sweden, as a visiting researcher in 2015-2016 and 2016-2017, respectively. He became an Assistant Professor of Analytical Chemistry at Bu-Ali Sina University in 2019. His professional experiences also include two post-doctorate research courses at Shiraz University of Medical Science, Iran, and Bu-Ali Sina University, Iran, in 2017-2018 and 2018-2019, respectively. Dr. Ahmadi is an expert in nanotechnology, analytical method development, pollutant removal, and wastewater treatment. He has edited six Elsevier books. He also has contributed eleven book chapters with Elsevier. Dr. Ali Farmani is an Assistant Professor in the Department of Electrical Engineering at Lorestan University in Khorramabad, Iran. His research focuses on optical nanostructured materials. DEA (ENSCMul, France) and PhD (Cnam of Paris, France 2009). He worked as an assistant professor at Cnam of Paris (2009-2011) and researcher at ETS, Montreal, Canada (2011-2015) before joining to University of Montreal as research officer (Prud'homme's Group). His main research interests are polymer blends, crystallization of ultra thin films, nanostructuration, agrocomposites, polymer ageing, personal protective materials, rupture mechanisms of polymer material Tuan Anh Nguyen is a Senior Principal Research Scientist at the Institute for Tropical Technology, Vietnam Academy of Science and Technology, Hanoi, Vietnam. He received a BS in physics from Hanoi University in 1992, a BS in economics from Hanoi National Economics University in 1997, and a PhD in chemistry from the Paris Diderot University, France, in 2003. He was a Visiting Scientist at Seoul National University, South Korea, in 2004, and the University of Wollongong, Australia, in 2005. He then worked as a Postdoctoral Research Associate and Research Scientist at Montana State University, United States in 2006-09. In 2012 he was appointed as the Head of the Microanalysis Department at the Institute for Tropical Technology. His research areas of interest include smart sensors, smart networks, smart hospitals, smart cities, complexiverse, and digital twins. He has edited more than 74 books for Elsevier, 12 books for CRC Press, 1 book for Springer, 1 book for RSC, and 2 books for IGI Global. He is the Editor-in-Chief of Kenkyu Journal of Nanotechnology & Nanoscience.
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