Randall M. Feenstra, Colin E. C. Wood
Porous Silicon Carbide and Gallium Nitride
Epitaxy, Catalysis, and Biotechnology Applications
Randall M. Feenstra, Colin E. C. Wood
Porous Silicon Carbide and Gallium Nitride
Epitaxy, Catalysis, and Biotechnology Applications
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Porous Silicon Carbide and Gallium Nitride: Epitaxy, Catalysis, and Biotechnology Applications presents the state-of-the-art in knowledge and applications of porous semiconductor materials having a wide band gap. This comprehensive reference begins with an overview of porous wide-band-gap technology, and describes the underlying scientific basis for each application area. Additional chapters cover preparation, characterization, and topography; processing porous SiC; medical applications; magnetic ion behavior, and many more
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Porous Silicon Carbide and Gallium Nitride: Epitaxy, Catalysis, and Biotechnology Applications presents the state-of-the-art in knowledge and applications of porous semiconductor materials having a wide band gap. This comprehensive reference begins with an overview of porous wide-band-gap technology, and describes the underlying scientific basis for each application area. Additional chapters cover preparation, characterization, and topography; processing porous SiC; medical applications; magnetic ion behavior, and many more
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Hinweis: Dieser Artikel kann nur an eine deutsche Lieferadresse ausgeliefert werden.
Produktdetails
- Produktdetails
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 332
- Erscheinungstermin: 1. Mai 2008
- Englisch
- Abmessung: 235mm x 162mm x 24mm
- Gewicht: 620g
- ISBN-13: 9780470517529
- ISBN-10: 0470517522
- Artikelnr.: 23523304
- Verlag: Wiley & Sons
- 1. Auflage
- Seitenzahl: 332
- Erscheinungstermin: 1. Mai 2008
- Englisch
- Abmessung: 235mm x 162mm x 24mm
- Gewicht: 620g
- ISBN-13: 9780470517529
- ISBN-10: 0470517522
- Artikelnr.: 23523304
Randall M. Feenstra is professor in the Department of Physics at Carnegie Mellon University Pittsburgh (USA). He gained his PhD in applied physics at the California Institute of Technology (USA). His research interests include atomic structure, electronic spectroscopy of semiconductor materials and heterostructures, growth of semiconductor thin films by molecular beam epitaxy, and scanning probe microscopy. He has received awards from the Alexander von Humboldt Foundation, the Peter Mark Memorial Award of the American Vacuum Society and the IBM Outstanding Innovation Award. He has also been the co-organizer of the symposium on GaN and Related Alloys at the MRS Fall Meeting, has been part of the organizing committee for the Electronic Materials Conference, has been a member of the Organizing Committee and Conference Chair for the Conference on the Physics and Chemistry of Semiconductor Interfaces. Dr. Colin E. C. Wood has a PhD in physical chemistry from Nottingham University (UK). He has substantial industrial and academic experience including as senior physicist at the Philips Research Laboratory in Salford (UK), Senior Research Associate at Cornell University (USA), Assistant Director at GEC Hirst Research Centre Wembley (UK), COO at Northeast Semiconductor Inc., Ithaca (USA) and Research Professor at University of Maryland (USA). He is a Founder Member of the Cornell Sub-Micron Center (NRRFS now NNF) and a Founder Member of the UK Low-Dimensional Solids Programme. His awards include the Patterson Medal from the Institute of Physics (UK).
Preface.
1. Porous SiC Preparation, Characterization and Morphology
1.1 Introduction
1.2 Triangular Porous Morphology in n-type 4H-SiC.
1.3 Nano-columnar Pore Formation in 6H SiC.
1.4 Summary.
Acknowledgements.
References.
2. Processing Porous SiC: Diffusion, Oxidation, Contact Formation.
2.1 Introduction.
2.2 Formation of Porous Layer.
2.3 Diffusion in Porous SiC.
2.4 Oxidation.
2.5 Contacts to Porous SiC.
Acknowledgments.
References.
3. Growth of SiC on Porous SiC Buffer Layers.
3.1 Introduction.
3.2 SiC CVD Growth.
3.3 Growth of 3C-SiC on porous Si via Cold-Wall Epitaxy.
3.4 Growth of 3C-SiC on Porous 3C-SiC.
3.5 Growth of 4H-SiC on Porous 4H-SiC.
3.6 Conclusion.
Acknowledgements.
References.
4. Preparation and Properties of Porous GaN Fabricated by Metal-Assisted
Electroless Etching.
4.1 Introduction.
4.2 Creation of Porous GaN by Electroless Etching.
4.3 Morphology Characterization.
4.4 Luminescence of Porous GaN.
4.5 Raman Spectroscopy of Porous GaN.
4.6 Summary and Conclusions.
Acknowledgments.
References.
5. Growth of GaN on Porous SiC by Molecular Beam Epitaxy.
5.1 Introduction.
5.2 Morphology and Preparation of Porous SiC Substrates.
5.3 MBE Growth of GaN on Porous SiC Substrates.
5.4 Summary.
Acknowledgments.
References.
6. GaN Lateral Epitaxy Growth Using Porous SiNx, TiNx and SiC.
6.1 Introduction.
6.2 Epitaxy of GaN on Porous SiNx Network.
6.3 Epitaxial Lateral Overgrowth of GaN on Porous TiN.
6.4 Growth of GaN on Porous SiC.
Acknowledgements.
References.
7. HVPE Growth of GaN on Porous SiC Substrates.
7.1 Introduction.
7.2 PSC Substrate Fabrication and Properties.
7.3 Epitaxial Growth of GaN Films on PSC.
Summary.
References.
8. Dislocation Mechanisms in GaN Films Grown on Porous Substrates or
Interlayers.
8.1 Introduction.
8.2 Extended Defects In Epitaxially Grown GaN Thin Layers.
8.3 Dislocation Mechanisms in Conventional Lateral Epitaxy Overgrowth of
GaN.
8.4 Growth of GaN on Porous SiC Substrates.
8.5 Growth of GaN on Porous SiN and TiN Interlayers.
8.6 Summary.
Acknowledgments.
References.
9. Electrical Properties of Porous SiC.
9.1 Introduction.
9.2 Resistivity and Hall Effect.
9.3 Deep Level Transient Spectroscopy.
9.4 Sample Considerations.
9.5 Potential Energy Near a Pore.
9.6 DLTS Data and Analysis.
Acknowledgements.
References.
10. Magnetism of Doped GaN Nanostructures.
10.1 Introduction.
10. 2 Mn-Doped GaN Crystal.
10. 3 Mn-Doped GaN Thin Films.
10.4 Mn- and Cr-Doped GaN One-Dimensional Structures.
10.5 N-Doped Mn and Cr Clusters.
10.6 Summary.
Acknowledgments
References.
11 SiC Catalysis Technology.
11.1 Introduction.
11.2 Silicon Carbide Support.
11.3 Heat Effects During Reaction.
11.4 Reactions on SiC as Catalytic Supports.
11.5 Examples of SiC Catalyst Applications.
11.6 Prospects and Conclusions.
References.
12. Nanoporous SiC as a Semi-Permeable Biomembrane for Medical Use:
Practical and Theoretical Considerations.
12. 1. The Rationale for Implantable Semi-Permeable Materials.
12. 2. The Biology of Soluble Signaling Proteins in Tissue.
12. 3. Measuring Cytokine Secretion In Living Tissues and Organs.
12.4. Creating a Biocompatible Tissue - Device Interface: Advantages of
SiC.
12.5. The Testing of SiC Membranes for Permeability of Proteins.
12.6. Improving the Structure of SiC Membranes for Biosensor Interfaces.
12.7. Theoretical Considerations: Modeling Diffusion through a Porous
Membrane.
12.8. Future Development: Marriage of Membrane and Microchip.
12.9. Conclusions
Acknowledgments.
References.
1. Porous SiC Preparation, Characterization and Morphology
1.1 Introduction
1.2 Triangular Porous Morphology in n-type 4H-SiC.
1.3 Nano-columnar Pore Formation in 6H SiC.
1.4 Summary.
Acknowledgements.
References.
2. Processing Porous SiC: Diffusion, Oxidation, Contact Formation.
2.1 Introduction.
2.2 Formation of Porous Layer.
2.3 Diffusion in Porous SiC.
2.4 Oxidation.
2.5 Contacts to Porous SiC.
Acknowledgments.
References.
3. Growth of SiC on Porous SiC Buffer Layers.
3.1 Introduction.
3.2 SiC CVD Growth.
3.3 Growth of 3C-SiC on porous Si via Cold-Wall Epitaxy.
3.4 Growth of 3C-SiC on Porous 3C-SiC.
3.5 Growth of 4H-SiC on Porous 4H-SiC.
3.6 Conclusion.
Acknowledgements.
References.
4. Preparation and Properties of Porous GaN Fabricated by Metal-Assisted
Electroless Etching.
4.1 Introduction.
4.2 Creation of Porous GaN by Electroless Etching.
4.3 Morphology Characterization.
4.4 Luminescence of Porous GaN.
4.5 Raman Spectroscopy of Porous GaN.
4.6 Summary and Conclusions.
Acknowledgments.
References.
5. Growth of GaN on Porous SiC by Molecular Beam Epitaxy.
5.1 Introduction.
5.2 Morphology and Preparation of Porous SiC Substrates.
5.3 MBE Growth of GaN on Porous SiC Substrates.
5.4 Summary.
Acknowledgments.
References.
6. GaN Lateral Epitaxy Growth Using Porous SiNx, TiNx and SiC.
6.1 Introduction.
6.2 Epitaxy of GaN on Porous SiNx Network.
6.3 Epitaxial Lateral Overgrowth of GaN on Porous TiN.
6.4 Growth of GaN on Porous SiC.
Acknowledgements.
References.
7. HVPE Growth of GaN on Porous SiC Substrates.
7.1 Introduction.
7.2 PSC Substrate Fabrication and Properties.
7.3 Epitaxial Growth of GaN Films on PSC.
Summary.
References.
8. Dislocation Mechanisms in GaN Films Grown on Porous Substrates or
Interlayers.
8.1 Introduction.
8.2 Extended Defects In Epitaxially Grown GaN Thin Layers.
8.3 Dislocation Mechanisms in Conventional Lateral Epitaxy Overgrowth of
GaN.
8.4 Growth of GaN on Porous SiC Substrates.
8.5 Growth of GaN on Porous SiN and TiN Interlayers.
8.6 Summary.
Acknowledgments.
References.
9. Electrical Properties of Porous SiC.
9.1 Introduction.
9.2 Resistivity and Hall Effect.
9.3 Deep Level Transient Spectroscopy.
9.4 Sample Considerations.
9.5 Potential Energy Near a Pore.
9.6 DLTS Data and Analysis.
Acknowledgements.
References.
10. Magnetism of Doped GaN Nanostructures.
10.1 Introduction.
10. 2 Mn-Doped GaN Crystal.
10. 3 Mn-Doped GaN Thin Films.
10.4 Mn- and Cr-Doped GaN One-Dimensional Structures.
10.5 N-Doped Mn and Cr Clusters.
10.6 Summary.
Acknowledgments
References.
11 SiC Catalysis Technology.
11.1 Introduction.
11.2 Silicon Carbide Support.
11.3 Heat Effects During Reaction.
11.4 Reactions on SiC as Catalytic Supports.
11.5 Examples of SiC Catalyst Applications.
11.6 Prospects and Conclusions.
References.
12. Nanoporous SiC as a Semi-Permeable Biomembrane for Medical Use:
Practical and Theoretical Considerations.
12. 1. The Rationale for Implantable Semi-Permeable Materials.
12. 2. The Biology of Soluble Signaling Proteins in Tissue.
12. 3. Measuring Cytokine Secretion In Living Tissues and Organs.
12.4. Creating a Biocompatible Tissue - Device Interface: Advantages of
SiC.
12.5. The Testing of SiC Membranes for Permeability of Proteins.
12.6. Improving the Structure of SiC Membranes for Biosensor Interfaces.
12.7. Theoretical Considerations: Modeling Diffusion through a Porous
Membrane.
12.8. Future Development: Marriage of Membrane and Microchip.
12.9. Conclusions
Acknowledgments.
References.
Preface.
1. Porous SiC Preparation, Characterization and Morphology
1.1 Introduction
1.2 Triangular Porous Morphology in n-type 4H-SiC.
1.3 Nano-columnar Pore Formation in 6H SiC.
1.4 Summary.
Acknowledgements.
References.
2. Processing Porous SiC: Diffusion, Oxidation, Contact Formation.
2.1 Introduction.
2.2 Formation of Porous Layer.
2.3 Diffusion in Porous SiC.
2.4 Oxidation.
2.5 Contacts to Porous SiC.
Acknowledgments.
References.
3. Growth of SiC on Porous SiC Buffer Layers.
3.1 Introduction.
3.2 SiC CVD Growth.
3.3 Growth of 3C-SiC on porous Si via Cold-Wall Epitaxy.
3.4 Growth of 3C-SiC on Porous 3C-SiC.
3.5 Growth of 4H-SiC on Porous 4H-SiC.
3.6 Conclusion.
Acknowledgements.
References.
4. Preparation and Properties of Porous GaN Fabricated by Metal-Assisted
Electroless Etching.
4.1 Introduction.
4.2 Creation of Porous GaN by Electroless Etching.
4.3 Morphology Characterization.
4.4 Luminescence of Porous GaN.
4.5 Raman Spectroscopy of Porous GaN.
4.6 Summary and Conclusions.
Acknowledgments.
References.
5. Growth of GaN on Porous SiC by Molecular Beam Epitaxy.
5.1 Introduction.
5.2 Morphology and Preparation of Porous SiC Substrates.
5.3 MBE Growth of GaN on Porous SiC Substrates.
5.4 Summary.
Acknowledgments.
References.
6. GaN Lateral Epitaxy Growth Using Porous SiNx, TiNx and SiC.
6.1 Introduction.
6.2 Epitaxy of GaN on Porous SiNx Network.
6.3 Epitaxial Lateral Overgrowth of GaN on Porous TiN.
6.4 Growth of GaN on Porous SiC.
Acknowledgements.
References.
7. HVPE Growth of GaN on Porous SiC Substrates.
7.1 Introduction.
7.2 PSC Substrate Fabrication and Properties.
7.3 Epitaxial Growth of GaN Films on PSC.
Summary.
References.
8. Dislocation Mechanisms in GaN Films Grown on Porous Substrates or
Interlayers.
8.1 Introduction.
8.2 Extended Defects In Epitaxially Grown GaN Thin Layers.
8.3 Dislocation Mechanisms in Conventional Lateral Epitaxy Overgrowth of
GaN.
8.4 Growth of GaN on Porous SiC Substrates.
8.5 Growth of GaN on Porous SiN and TiN Interlayers.
8.6 Summary.
Acknowledgments.
References.
9. Electrical Properties of Porous SiC.
9.1 Introduction.
9.2 Resistivity and Hall Effect.
9.3 Deep Level Transient Spectroscopy.
9.4 Sample Considerations.
9.5 Potential Energy Near a Pore.
9.6 DLTS Data and Analysis.
Acknowledgements.
References.
10. Magnetism of Doped GaN Nanostructures.
10.1 Introduction.
10. 2 Mn-Doped GaN Crystal.
10. 3 Mn-Doped GaN Thin Films.
10.4 Mn- and Cr-Doped GaN One-Dimensional Structures.
10.5 N-Doped Mn and Cr Clusters.
10.6 Summary.
Acknowledgments
References.
11 SiC Catalysis Technology.
11.1 Introduction.
11.2 Silicon Carbide Support.
11.3 Heat Effects During Reaction.
11.4 Reactions on SiC as Catalytic Supports.
11.5 Examples of SiC Catalyst Applications.
11.6 Prospects and Conclusions.
References.
12. Nanoporous SiC as a Semi-Permeable Biomembrane for Medical Use:
Practical and Theoretical Considerations.
12. 1. The Rationale for Implantable Semi-Permeable Materials.
12. 2. The Biology of Soluble Signaling Proteins in Tissue.
12. 3. Measuring Cytokine Secretion In Living Tissues and Organs.
12.4. Creating a Biocompatible Tissue - Device Interface: Advantages of
SiC.
12.5. The Testing of SiC Membranes for Permeability of Proteins.
12.6. Improving the Structure of SiC Membranes for Biosensor Interfaces.
12.7. Theoretical Considerations: Modeling Diffusion through a Porous
Membrane.
12.8. Future Development: Marriage of Membrane and Microchip.
12.9. Conclusions
Acknowledgments.
References.
1. Porous SiC Preparation, Characterization and Morphology
1.1 Introduction
1.2 Triangular Porous Morphology in n-type 4H-SiC.
1.3 Nano-columnar Pore Formation in 6H SiC.
1.4 Summary.
Acknowledgements.
References.
2. Processing Porous SiC: Diffusion, Oxidation, Contact Formation.
2.1 Introduction.
2.2 Formation of Porous Layer.
2.3 Diffusion in Porous SiC.
2.4 Oxidation.
2.5 Contacts to Porous SiC.
Acknowledgments.
References.
3. Growth of SiC on Porous SiC Buffer Layers.
3.1 Introduction.
3.2 SiC CVD Growth.
3.3 Growth of 3C-SiC on porous Si via Cold-Wall Epitaxy.
3.4 Growth of 3C-SiC on Porous 3C-SiC.
3.5 Growth of 4H-SiC on Porous 4H-SiC.
3.6 Conclusion.
Acknowledgements.
References.
4. Preparation and Properties of Porous GaN Fabricated by Metal-Assisted
Electroless Etching.
4.1 Introduction.
4.2 Creation of Porous GaN by Electroless Etching.
4.3 Morphology Characterization.
4.4 Luminescence of Porous GaN.
4.5 Raman Spectroscopy of Porous GaN.
4.6 Summary and Conclusions.
Acknowledgments.
References.
5. Growth of GaN on Porous SiC by Molecular Beam Epitaxy.
5.1 Introduction.
5.2 Morphology and Preparation of Porous SiC Substrates.
5.3 MBE Growth of GaN on Porous SiC Substrates.
5.4 Summary.
Acknowledgments.
References.
6. GaN Lateral Epitaxy Growth Using Porous SiNx, TiNx and SiC.
6.1 Introduction.
6.2 Epitaxy of GaN on Porous SiNx Network.
6.3 Epitaxial Lateral Overgrowth of GaN on Porous TiN.
6.4 Growth of GaN on Porous SiC.
Acknowledgements.
References.
7. HVPE Growth of GaN on Porous SiC Substrates.
7.1 Introduction.
7.2 PSC Substrate Fabrication and Properties.
7.3 Epitaxial Growth of GaN Films on PSC.
Summary.
References.
8. Dislocation Mechanisms in GaN Films Grown on Porous Substrates or
Interlayers.
8.1 Introduction.
8.2 Extended Defects In Epitaxially Grown GaN Thin Layers.
8.3 Dislocation Mechanisms in Conventional Lateral Epitaxy Overgrowth of
GaN.
8.4 Growth of GaN on Porous SiC Substrates.
8.5 Growth of GaN on Porous SiN and TiN Interlayers.
8.6 Summary.
Acknowledgments.
References.
9. Electrical Properties of Porous SiC.
9.1 Introduction.
9.2 Resistivity and Hall Effect.
9.3 Deep Level Transient Spectroscopy.
9.4 Sample Considerations.
9.5 Potential Energy Near a Pore.
9.6 DLTS Data and Analysis.
Acknowledgements.
References.
10. Magnetism of Doped GaN Nanostructures.
10.1 Introduction.
10. 2 Mn-Doped GaN Crystal.
10. 3 Mn-Doped GaN Thin Films.
10.4 Mn- and Cr-Doped GaN One-Dimensional Structures.
10.5 N-Doped Mn and Cr Clusters.
10.6 Summary.
Acknowledgments
References.
11 SiC Catalysis Technology.
11.1 Introduction.
11.2 Silicon Carbide Support.
11.3 Heat Effects During Reaction.
11.4 Reactions on SiC as Catalytic Supports.
11.5 Examples of SiC Catalyst Applications.
11.6 Prospects and Conclusions.
References.
12. Nanoporous SiC as a Semi-Permeable Biomembrane for Medical Use:
Practical and Theoretical Considerations.
12. 1. The Rationale for Implantable Semi-Permeable Materials.
12. 2. The Biology of Soluble Signaling Proteins in Tissue.
12. 3. Measuring Cytokine Secretion In Living Tissues and Organs.
12.4. Creating a Biocompatible Tissue - Device Interface: Advantages of
SiC.
12.5. The Testing of SiC Membranes for Permeability of Proteins.
12.6. Improving the Structure of SiC Membranes for Biosensor Interfaces.
12.7. Theoretical Considerations: Modeling Diffusion through a Porous
Membrane.
12.8. Future Development: Marriage of Membrane and Microchip.
12.9. Conclusions
Acknowledgments.
References.