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|a 1547476294
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|z 9780443302008
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|a 9780443302015
|q (electronic bk.)
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|a 0443302014
|q (electronic bk.)
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|z 0443302006
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|z (OCoLC)1547476294
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|a 620.1/15
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|a TXAM
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|a Magnetic nanomaterials for plant and soil systems improvement /
|c edited by Azamal Husen.
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| 264 |
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1 |
|a [Place of publication not identified] :
|b Elsevier,
|c 2025.
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| 300 |
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|a 1 online resource.
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| 336 |
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|a text
|b txt
|2 rdacontent
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|a computer
|b c
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|a online resource
|b cr
|2 rdacarrier
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|a Micro and Nano Technologies
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| 520 |
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|a Magnetic Nanomaterials for Plant and Soil Systems Improvement discusses the impact of nanotechnology on plant growth, disease resistance, and soil enrichment, specifically focusing on magnetic nanomaterials like iron, iron oxide, cobalt, and nickel ferrite nanoparticles. The book starts with an introduction to the properties and fabrication processes of magnetic nanomaterials for plant and soil system application. It then extensively examines the influence of these materials on plant biology, growth, production, and the broader plant-soil system. This book includes discussions on the environmental safety of nanomaterials, plant stress management, plant disease control, and ethical considerations associated with the use of magnetic nanomaterials in plant and soil systems. Tailored for advanced students, scientists, and researchers in materials science, nanotechnology, and agriculture, this book provides a comprehensive exploration of how magnetic nanomaterials can effectively enhance crop performance.
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|a Online resource; title from PDF title page (ScienceDirect, viewed November 11, 2025).
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|a Husen-9780443302008_MNT_FC -- ELSST512-FM1_LR -- Front Matter -- ELSST512-FM2_LR -- Titlepage -- ELSST512-FM3_LR -- Copyright -- ELSST512-FM4_LR -- Dedication -- ELSST512-FM5_LR -- Contents -- ELSST512-FM6_LR -- Contributors -- ELSST512-FM7_LR -- About the Editor -- ELSST512-FM8_LR -- Preface -- ELSST512-01_LR -- Chapter 1 Magnetic nanomaterials fabrication and their uses in plant and soil system: An overview -- 1.1 Introduction -- 1.2 Fabrication of magnetic and other nanomaterials -- 1.2.1 Methods of synthesis -- 1.2 2 Physical methods -- 1.2 3 Biological methods -- 1.2.4 Surface functionalization techniques -- 1.2.5 Characterization methods -- 1.3 Applications in plant systems -- 1.3.1 Role in enhancing nutrient uptake -- 1.3.2 Delivery of agrochemicals -- 1.3.3 Magnetic nanoparticles as stress alleviators -- 1.3.4 Interaction with plant metabolism -- 1.4 Applications in soil systems -- 1.4.1 Soil remediation and heavy metal removal -- 1.4.2 Enhancement in soil fertility -- 1.4.3 Role in microbial communities and enzymatic activity of soil -- 1.5 Toxicity and environmental concerns -- 1.5.1 Potential phytotoxicity -- 1.5.2 Bioaccumulation in soil and plants -- 1.5.3 Long-term environmental impact -- 1.6 Case studies and practical applications -- 1.6.1 Successful applications in real-world scenarios -- 1.6.2 Challenges and limitations -- 1.7 Future perspectives -- 1.8 Conclusion -- References -- ELSST512-02_LR -- Chapter 2 Uptake, translocation, and transformation of magnetic nanomaterials in plants soil-plant system -- 2.1 Introduction -- 2.2 Uptake of magnetic nanomaterials by plants -- 2.3 Translocation within the plant system -- 2.4 Transformation and fate of nanomaterials in plants -- 2.5 Impact on plant physiology and growth -- 2.6 Detection and quantification techniques -- 2.7 Environmental considerations.
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|a 2.8 Agricultural applications and nanotechnology -- 2.9 Regulatory and safety aspects -- 2.10 Future research directions -- 2.11 Conclusion -- References -- ELSST512-03_LR -- Chapter 3 Effect of magnetic nanomaterials on seed germination and seedling growth -- 3.1 Introduction -- 3.2 Effects of magnetic nanomaterials on seed germination and seedling growth -- 3.3 Adverse effects of magnetic nanoparticles on seed germination and seedling growth -- 3.4 Mechanisms of action of magnetic nanoparticles with plant -- 3.5 Factors affecting the efficacy of metallic nanoparticles on plants -- 3.6 Other responses -- 3.7 Conclusion -- References -- ELSST512-04_LR -- Chapter 4 Magnetic nanocomposite for improved plant-soil system and underlying mechanism -- 4.1 Introduction -- 4.1.1 Nanotechnology in agriculture -- 4.1.2 Importance of soil-plant systems -- 4.1.3 Role of magnetic nanocomposites in improving plant-soil system -- 4.2 Magnetic nanocomposites: Synthesis and characterization -- 4.2.1 Synthesis techniques -- 4.2.2 Characterization methods -- 4.3 Mechanisms of magnetic nanocomposites in the plant-soil system -- 4.3.1 Interaction with soil components -- 4.3.2 Effects on soil microorganisms -- 4.3.3 Impact on root morphology and plant growth -- 4.4 Enhancing nutrient uptake with magnetic nanocomposites -- 4.4.1 Role in enhancing nitrogen, phosphorus, and potassium uptake -- 4.4.2 Effects on micronutrient availability -- 4.4.3 Mitigating soil nutrient deficiencies -- 4.5 Enhancement of soil quality and fertility through magnetic nanocomposites -- 4.5.1 Nutrient retention and controlled release -- 4.5.2 Improvement of soil structure -- 4.5.3 Mitigation of soil nutrient deficiencies -- 4.5.4 Environmental sustainability -- 4.6 Case studies on the magnetic nanocomposite to improve soil-plant system.
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|a 4.7 Long-term ecological influence of magnetic nanocomposites -- 4.8 Future directions and challenges -- 4.9 Conclusion -- References -- ELSST512-05_LR -- Chapter 5 Mitigation of heavy metals adverse effects in plant systems using magnetic nanoparticles -- 5.1 Introduction -- 5.1.1 Heavy metals in agriculture -- 5.1.2 Mechanisms of magnetic nanoparticles in mitigation of metal stress -- 5.2.3 Applications of MNPs in the agricultural industry -- 5.2 Conclusions and remarks -- 5.3 Challenges and future directions -- Acknowledgement -- References -- ELSST512-06_LR -- Chapter 6 Mitigation of drought and salinity stress in plants using magnetic nanomaterials -- 6.1 Introduction to drought and salinity stress in plants -- 6.1.1 Definition and causes of drought stress -- 6.1.2 Definition and causes of salinity stress -- 6.1.3 Effects of the drought and salinity stress on plant growth and productivity -- 6.1.4 Importance of addressing drought and salinity stress in agricultural practices -- 6.2 Understanding magnetic nanomaterials -- 6.2.1 Introduction to nanomaterials and their properties -- 6.2.2 Types of magnetic nanomaterials -- 6.2.3 Synthesis methods and characterization techniques -- 6.3 Mechanisms of drought and salinity stress mitigation by magnetic nanomaterials -- 6.3.1 Conversation of magnetic nanomaterials with plant systems -- 6.3.2 Regulation of water uptake and retention by magnetic nanomaterials -- 6.3.3 Amelioration of oxidative stress and ion imbalance in plants -- 6.3.4 Enhancement of plant growth and yield under stress conditions -- 6.4 Application of magnetic nanomaterials in plant stress management -- 6.5 Environmental and safety considerations -- 6.5.1 Security implications and concerns connected to utilization of magnetic nanomaterials in agriculture -- 6.6 Future perspectives and challenges.
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|a 6.6.1 Current developments and future prospects in the field of magnetic nanomaterials for plant stress management -- 6.6.2 Challenges and barriers to widespread adoption of nanomaterial-based approaches -- 6.6.3 Opportunities for interdisciplinary research and collaboration to address existing limitations -- 6.7 Conclusion -- References -- ELSST512-07_LR -- Chapter 7 Application of magnetic nanomaterials in soil science and agriculture practice -- 7.1 Introduction -- 7.2 Magnetic nanomaterials -- 7.2.1 Magnetic properties and their applications -- 7.2.2 Surface chemistry and functionalization -- 7.2.3 Biological interactions -- 7.2.4 Beneficial impacts ofamp -- #x00A0 -- magnetic nanoparticles onamp -- #x00A0 -- plants -- 7.3 Applications in soil science -- 7.3.1 Soil remediation -- 7.3.2 Nutrient retention and release -- 7.3.3 Soil health monitoring -- 7.4 Application in agriculture -- 7.4.1 Crop growth and yield enhancement -- 7.4.2 Pesticide and herbicide delivery -- 7.4.3 Water purification and management -- 7.4.4 Stress resistance in plants -- 7.5 Interactions with soil microorganisms -- 7.5.1 Microbial ecology and magnetic nanomaterials -- 7.5.2 Synergistic interactions -- 7.5.3 Challenges in maintaining soil biodiversity -- 7.6 Challenges and limitations -- 7.6.1 Environmental impacts -- 7.6.2 Effectiveness and stability -- 7.6.3 Economic viability -- 7.6.4 Ethical considerations -- 7.7 Future perspectives and opportunities -- References -- ELSST512-08_LR -- Chapter 8 Application of magnetic nanoparticles for labels in the determination of pathogens in magnetic immunoassays in plants -- 8.1 Introduction -- 8.1.1 Overview of plant pathogens -- 8.1.2 Importance of early pathogen detection in agriculture -- 8.1.3 Need for innovative approaches -- 8.2 Magnetic nanoparticles: Definition and types -- 8.2.1 Definition and unique characteristics.
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| 505 |
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|a 8.2.2 Types of magnetic nanoparticles -- 8.2.3 Common magnetic nanomaterials in biological systems -- 8.2.4 Role in pathogen detection -- 8.3 Magnetic immunoassays: Principles and mechanisms -- 8.3.1 Immunoassays in plant pathogen detection -- 8.3.2 ELISA and its limitations -- 8.3.3 Advantages of magnetic immunoassays -- 8.3.4 Role of magnetic nanoparticles in magnetic immunoassays -- 8.3.5 Labeling and detection mechanisms -- 8.3.6 Signal amplification -- 8.3.7 Mechanisms of magnetic immunoassays -- 8.3.8 Advances in detection techniques -- 8.3.9 Applications and future directions -- 8.4 Design and functionalization of magnetic nanoparticles for pathogen detection -- 8.4.1 Functionalization strategies -- 8.4.2 Covalent and noncovalent coupling with antibodies or aptamers -- 8.4.3 Stability and specificity considerations -- 8.4.4 Optimization of magnetic immunoassay protocols -- 8.4.5 Magnetic immunoassay in plant sample preparation -- 8.4.6 Magnetic immunoassay for plant target capture -- 8.4.7 Advanced design considerations -- 8.4.8 Applications in plant pathology -- 8.5 Case studies: Application in plant pathogen detection -- 8.5.1 Detection of bacterial pathogens -- 8.5.2 Detection of viral pathogens -- 8.5.3 Detection of fungal pathogens -- 8.5.4 Detection of nematode pathogens -- 8.5.5 Comparative analysis with conventional techniques -- 8.6 Advantages and limitations of using magnetic nanoparticles -- 8.6.1 Key Advantages -- 8.6.2 Enhanced sensitivity and specificity -- 8.6.3 Rapid detection -- 8.6.4 Adaptability and portability -- 8.6.5 Scalability and cost-effectiveness -- 8.6.6 Limitations and challenges -- 8.6.7 Technical and methodological challenges -- 8.6.8 Cost and scalability -- 8.6.9 Environmental and regulatory considerations -- 8.6.10 Field applicability -- 8.7 Future directions and innovations.
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| 650 |
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|a Nanostructured materials.
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| 650 |
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|a Magnetic materials.
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| 650 |
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|a Crop improvement.
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| 650 |
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|a Soil amendments.
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| 650 |
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6 |
|a Nanomatériaux.
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| 650 |
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6 |
|a Matériaux magnétiques.
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| 650 |
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|a Cultures
|x Amélioration.
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| 650 |
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|a Engrais et amendements.
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| 650 |
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|a fertilizer.
|2 aat
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| 655 |
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|a Electronic books.
|2 local
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| 700 |
1 |
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|a Husen, Azamal,
|e editor.
|1 https://id.oclc.org/worldcat/entity/E39PCjB9DWjgkyfcbfWd8YG6jy
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| 710 |
2 |
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|a ScienceDirect (Online service)
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| 776 |
0 |
8 |
|c Original
|z 0443302006
|z 9780443302008
|w (OCoLC)1509189078
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| 830 |
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0 |
|a Micro & nano technologies.
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| 856 |
4 |
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|z Connect to the full text of this electronic book
|t 0
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| 955 |
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|a Elsevier ScienceDirect 2026-2027
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| 994 |
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|a 92
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| 952 |
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|a Texas A&M University
|b College Station
|c Electronic Resources
|s www_evans
|d Available Online
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|e TA418.9.N35
|h Library of Congress classification
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| 998 |
f |
f |
|a TA418.9.N35
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|l Available Online
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