Chapter 2D Synthesis and stabilization of metallic nanoparticles
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Saurabh Vyas
Abstract
The development of varied methodologies for the synthesis of MNPs (metal nanoparticles) has gained tremendous boast because of the unique properties of the nanoparticles as compared to their bulk counterparts. The quantization of electronic effects results in special optical and magnetic properties. Moreover, a high surface-tovolume ratio promotes exceptional mechanical, thermal, and catalytic properties. Therefore, the synthesis and stabilization of metal nanoparticles are of paramount importance. Herein, we have highlighted the synthesis, stabilization, and applications of transition metallic nanoparticles like Pd, Ag, Au, Pt, Cu, and Co, using different methods, which include the sol-gel method, chemical reduction method, green method (natural resources), and colloidal injection method. Furthermore, we have elaborately discussed the different types of stabilizers used to stabilize the metallic nanoparticle. Moreover, the role of stabilizers and the effect on the size of nanoparticles have also been discussed.
Abstract
The development of varied methodologies for the synthesis of MNPs (metal nanoparticles) has gained tremendous boast because of the unique properties of the nanoparticles as compared to their bulk counterparts. The quantization of electronic effects results in special optical and magnetic properties. Moreover, a high surface-tovolume ratio promotes exceptional mechanical, thermal, and catalytic properties. Therefore, the synthesis and stabilization of metal nanoparticles are of paramount importance. Herein, we have highlighted the synthesis, stabilization, and applications of transition metallic nanoparticles like Pd, Ag, Au, Pt, Cu, and Co, using different methods, which include the sol-gel method, chemical reduction method, green method (natural resources), and colloidal injection method. Furthermore, we have elaborately discussed the different types of stabilizers used to stabilize the metallic nanoparticle. Moreover, the role of stabilizers and the effect on the size of nanoparticles have also been discussed.
Kapitel in diesem Buch
- Frontmatter I
- Contents V
- Common abbreviations VII
- Preface 1
-
Section 1: Overview of nanoscience and nanochemistry
- Chapter 1 Nanochemistry: development of nanomaterials 31
-
Section 2: Focus on synthesis methods
- Chapter 2A Wet-chemistry-derived nanomaterials and their multidisciplinary applications 131
- Chapter 2B Bottom-up synthesis of nanomaterials 239
- Chapter 2C Green pathways to synthesize nanomaterials 267
- Chapter 2D Synthesis and stabilization of metallic nanoparticles 307
-
Section 3: Focus on characterization methods
- Chapter 3A Advances in understanding electrochemical reaction mechanisms of highly dispersed metal sites using X-ray absorption spectroscopy 327
- Chapter 3B In situ spectroscopic studies of the electrochemistry 357
- Chapter 3C Integrated X-ray scattering and molecularscale simulation approaches to probe the behavior of confined fluids for a sustainable energy future 437
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Section 4: Focus on select example applications of nanoscience in energy, environment, and health
- Chapter 4A Electrocatalytic hydrogen production 461
- Chapter 4B Nanostructured materials for electrocatalytic hydrogen evolution reaction 489
- Chapter 4C Recent progress in cobalt-based nanosheets for electrochemical water oxidation 537
- Chapter 4D Nanoapplication: carbon capture and conversions 565
- Postface: social impact, consequences, and results of nanotechnology 583
- Biography of the editors 593
- Biography of the authors 595
- Author list 603
- Index 607
Kapitel in diesem Buch
- Frontmatter I
- Contents V
- Common abbreviations VII
- Preface 1
-
Section 1: Overview of nanoscience and nanochemistry
- Chapter 1 Nanochemistry: development of nanomaterials 31
-
Section 2: Focus on synthesis methods
- Chapter 2A Wet-chemistry-derived nanomaterials and their multidisciplinary applications 131
- Chapter 2B Bottom-up synthesis of nanomaterials 239
- Chapter 2C Green pathways to synthesize nanomaterials 267
- Chapter 2D Synthesis and stabilization of metallic nanoparticles 307
-
Section 3: Focus on characterization methods
- Chapter 3A Advances in understanding electrochemical reaction mechanisms of highly dispersed metal sites using X-ray absorption spectroscopy 327
- Chapter 3B In situ spectroscopic studies of the electrochemistry 357
- Chapter 3C Integrated X-ray scattering and molecularscale simulation approaches to probe the behavior of confined fluids for a sustainable energy future 437
-
Section 4: Focus on select example applications of nanoscience in energy, environment, and health
- Chapter 4A Electrocatalytic hydrogen production 461
- Chapter 4B Nanostructured materials for electrocatalytic hydrogen evolution reaction 489
- Chapter 4C Recent progress in cobalt-based nanosheets for electrochemical water oxidation 537
- Chapter 4D Nanoapplication: carbon capture and conversions 565
- Postface: social impact, consequences, and results of nanotechnology 583
- Biography of the editors 593
- Biography of the authors 595
- Author list 603
- Index 607
