Nanoscale processes on insulating surfaces:
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| Format: | Elektronisch E-Book |
| Sprache: | English |
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World Scientific Pub. Co.
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| Online-Zugang: | FAW01 FAW02 Volltext |
| Beschreibung: | Includes bibliographical references (p. 163-181) and index 1. Crystal structures of insulating surfaces. 1.1. Halide surfaces. 1.2. Oxide surfaces -- 2. Preparation techniques of insulating surfaces. 2.1. Ultra high vacuum. 2.2. Preparation of bulk insulating surfaces. 2.3. Deposition of insulating films, metals and organic molecules -- 3. Scanning probe microscopy in ultra high vacuum. 3.1. Atomic force microscopy. 3.2. Scanning tunneling microscopy. 3.3. Atomistic modeling of SPM -- 4. Scanning probe microscopy on bulk insulating surfaces. 4.1. Halide surfaces. 4.2. Oxide surfaces. 4.3. Modeling AFM on bulk insulating surfaces -- 5. Scanning probe microscopy on thin insulating films. 5.1. Halide films on metals. 5.2. Halide films on semiconductors. 5.3. Heteroepitaxial growth of alkali halide films. 5.4. Oxide films. 5.5. Modeling AFM on thin insulating films -- 6. Interaction of ions, electrons and photons with halide surfaces. 6.1. Ion bombardment of alkali halides. 6.2. Electron and photon stimulated desorption -- - 7. Surface patterning with electrons and photons. 7.1. Surface topography modification by electronic excitations. 7.2. Nanoscale pits on alkali halide surfaces -- 8. Surface patterning with ions. 8.1. Ripple formation by ion bombardment. 8.2. A case study : ion beam modifications of KBr surfaces -- 9. Metal deposition on insulating surfaces. 9.1. Metals on halide surfaces. 9.2. Metals on oxide surfaces. 9.3. Metals on thin insulating films. 9.4. Modeling AFM on metal clusters on insulators -- 10. Organic molecules on insulating surfaces. 10.1. Chemical structures of organic molecules. 10.2. Organic molecules on halide surfaces. 10.3. Organic molecules on oxide surfaces. 10.4. Organic molecules on thin insulating films. 10.5. Modeling AFM on organic molecules on insulators -- - 11. Scanning probe spectroscopy on insulating surfaces. 11.1. Force spectroscopy on insulating surfaces. 11.2. Tunneling spectroscopy on thin insulating films. 11.3. Tunneling spectroscopy on metal clusters. 11.4. Tunneling spectroscopy on organic molecules -- 12. Nanotribology on insulating surfaces. 12.1. Friction mechanisms at the atomic scale. 12.2. Friction on halide surfaces. 12.3. Nanowear processes on insulating surfaces. 12.4. Modeling nanotribology on insulating surfaces -- 13. Nanomanipulation on insulating surfaces. 13.1. Nanomanipulation experiments on insulating surfaces. 13.2. Modeling nanomanipulation on insulating surfaces Ionic crystals are among the simplest structures in nature. They can be easily cleaved in air and in vacuum, and the resulting surfaces are atomically flat on areas hundreds of nanometers wide. With the development of scanning probe microscopy, these surfaces have become an ideal "playground" to investigate several phenomena occurring on the nanometer scale. This book focuses on the fundamental studies of atomically resolved imaging, nanopatterning, metal deposition, molecular self-assembling and nanotribological processes occurring on ionic crystal surfaces. Here, a significant variety of structures are created by nanolithography, annealing and irradiation by electrons, ions or photons, and are used to confine metal particles and organic molecules or to improve our basic understanding of friction and wear on the atomic scale. Metal oxides with wide band gap are also discussed. Altogether, the results obtained so far will have an undoubted impact on the future development of nanoelectronics and nanomechanics |
| Beschreibung: | 1 Online-Ressource (xiv, 186 p.) |
| ISBN: | 9789812837622 9789812837639 9812837620 9812837639 |
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| 500 | |a - 7. Surface patterning with electrons and photons. 7.1. Surface topography modification by electronic excitations. 7.2. Nanoscale pits on alkali halide surfaces -- 8. Surface patterning with ions. 8.1. Ripple formation by ion bombardment. 8.2. A case study : ion beam modifications of KBr surfaces -- 9. Metal deposition on insulating surfaces. 9.1. Metals on halide surfaces. 9.2. Metals on oxide surfaces. 9.3. Metals on thin insulating films. 9.4. Modeling AFM on metal clusters on insulators -- 10. Organic molecules on insulating surfaces. 10.1. Chemical structures of organic molecules. 10.2. Organic molecules on halide surfaces. 10.3. Organic molecules on oxide surfaces. 10.4. Organic molecules on thin insulating films. 10.5. Modeling AFM on organic molecules on insulators -- | ||
| 500 | |a - 11. Scanning probe spectroscopy on insulating surfaces. 11.1. Force spectroscopy on insulating surfaces. 11.2. Tunneling spectroscopy on thin insulating films. 11.3. Tunneling spectroscopy on metal clusters. 11.4. Tunneling spectroscopy on organic molecules -- 12. Nanotribology on insulating surfaces. 12.1. Friction mechanisms at the atomic scale. 12.2. Friction on halide surfaces. 12.3. Nanowear processes on insulating surfaces. 12.4. Modeling nanotribology on insulating surfaces -- 13. Nanomanipulation on insulating surfaces. 13.1. Nanomanipulation experiments on insulating surfaces. 13.2. Modeling nanomanipulation on insulating surfaces | ||
| 500 | |a Ionic crystals are among the simplest structures in nature. They can be easily cleaved in air and in vacuum, and the resulting surfaces are atomically flat on areas hundreds of nanometers wide. With the development of scanning probe microscopy, these surfaces have become an ideal "playground" to investigate several phenomena occurring on the nanometer scale. This book focuses on the fundamental studies of atomically resolved imaging, nanopatterning, metal deposition, molecular self-assembling and nanotribological processes occurring on ionic crystal surfaces. Here, a significant variety of structures are created by nanolithography, annealing and irradiation by electrons, ions or photons, and are used to confine metal particles and organic molecules or to improve our basic understanding of friction and wear on the atomic scale. Metal oxides with wide band gap are also discussed. Altogether, the results obtained so far will have an undoubted impact on the future development of nanoelectronics and nanomechanics | ||
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Datensatz im Suchindex
| _version_ | 1804175594265509888 |
|---|---|
| any_adam_object | |
| author | Gnecco, Enrico |
| author_facet | Gnecco, Enrico |
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| dewey-hundreds | 500 - Natural sciences and mathematics |
| dewey-ones | 502 - Miscellany |
| dewey-raw | 502.82 |
| dewey-search | 502.82 |
| dewey-sort | 3502.82 |
| dewey-tens | 500 - Natural sciences and mathematics |
| discipline | Allgemeine Naturwissenschaft |
| format | Electronic eBook |
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| id | DE-604.BV043142989 |
| illustrated | Not Illustrated |
| indexdate | 2024-07-10T07:18:46Z |
| institution | BVB |
| isbn | 9789812837622 9789812837639 9812837620 9812837639 |
| language | English |
| oai_aleph_id | oai:aleph.bib-bvb.de:BVB01-028567180 |
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| spelling | Gnecco, Enrico Verfasser aut Nanoscale processes on insulating surfaces Enrico Gnecco, Marek Szymonski Singapore World Scientific Pub. Co. c2009 1 Online-Ressource (xiv, 186 p.) txt rdacontent c rdamedia cr rdacarrier Includes bibliographical references (p. 163-181) and index 1. Crystal structures of insulating surfaces. 1.1. Halide surfaces. 1.2. Oxide surfaces -- 2. Preparation techniques of insulating surfaces. 2.1. Ultra high vacuum. 2.2. Preparation of bulk insulating surfaces. 2.3. Deposition of insulating films, metals and organic molecules -- 3. Scanning probe microscopy in ultra high vacuum. 3.1. Atomic force microscopy. 3.2. Scanning tunneling microscopy. 3.3. Atomistic modeling of SPM -- 4. Scanning probe microscopy on bulk insulating surfaces. 4.1. Halide surfaces. 4.2. Oxide surfaces. 4.3. Modeling AFM on bulk insulating surfaces -- 5. Scanning probe microscopy on thin insulating films. 5.1. Halide films on metals. 5.2. Halide films on semiconductors. 5.3. Heteroepitaxial growth of alkali halide films. 5.4. Oxide films. 5.5. Modeling AFM on thin insulating films -- 6. Interaction of ions, electrons and photons with halide surfaces. 6.1. Ion bombardment of alkali halides. 6.2. Electron and photon stimulated desorption -- - 7. Surface patterning with electrons and photons. 7.1. Surface topography modification by electronic excitations. 7.2. Nanoscale pits on alkali halide surfaces -- 8. Surface patterning with ions. 8.1. Ripple formation by ion bombardment. 8.2. A case study : ion beam modifications of KBr surfaces -- 9. Metal deposition on insulating surfaces. 9.1. Metals on halide surfaces. 9.2. Metals on oxide surfaces. 9.3. Metals on thin insulating films. 9.4. Modeling AFM on metal clusters on insulators -- 10. Organic molecules on insulating surfaces. 10.1. Chemical structures of organic molecules. 10.2. Organic molecules on halide surfaces. 10.3. Organic molecules on oxide surfaces. 10.4. Organic molecules on thin insulating films. 10.5. Modeling AFM on organic molecules on insulators -- - 11. Scanning probe spectroscopy on insulating surfaces. 11.1. Force spectroscopy on insulating surfaces. 11.2. Tunneling spectroscopy on thin insulating films. 11.3. Tunneling spectroscopy on metal clusters. 11.4. Tunneling spectroscopy on organic molecules -- 12. Nanotribology on insulating surfaces. 12.1. Friction mechanisms at the atomic scale. 12.2. Friction on halide surfaces. 12.3. Nanowear processes on insulating surfaces. 12.4. Modeling nanotribology on insulating surfaces -- 13. Nanomanipulation on insulating surfaces. 13.1. Nanomanipulation experiments on insulating surfaces. 13.2. Modeling nanomanipulation on insulating surfaces Ionic crystals are among the simplest structures in nature. They can be easily cleaved in air and in vacuum, and the resulting surfaces are atomically flat on areas hundreds of nanometers wide. With the development of scanning probe microscopy, these surfaces have become an ideal "playground" to investigate several phenomena occurring on the nanometer scale. This book focuses on the fundamental studies of atomically resolved imaging, nanopatterning, metal deposition, molecular self-assembling and nanotribological processes occurring on ionic crystal surfaces. Here, a significant variety of structures are created by nanolithography, annealing and irradiation by electrons, ions or photons, and are used to confine metal particles and organic molecules or to improve our basic understanding of friction and wear on the atomic scale. Metal oxides with wide band gap are also discussed. Altogether, the results obtained so far will have an undoubted impact on the future development of nanoelectronics and nanomechanics SCIENCE / Microscopes & Microscopy bisacsh Scanning probe microscopy Nanoelectronics Ionic crystals Thin films Surfaces Nanostruktur (DE-588)4204530-7 gnd rswk-swf Oberfläche (DE-588)4042907-6 gnd rswk-swf Nichtleiter (DE-588)4123451-0 gnd rswk-swf Nichtleiter (DE-588)4123451-0 s Oberfläche (DE-588)4042907-6 s Nanostruktur (DE-588)4204530-7 s 1\p DE-604 Szymoński, Marek Sonstige oth World Scientific (Firm) Sonstige oth http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=340499 Aggregator Volltext 1\p cgwrk 20201028 DE-101 https://d-nb.info/provenance/plan#cgwrk |
| spellingShingle | Gnecco, Enrico Nanoscale processes on insulating surfaces SCIENCE / Microscopes & Microscopy bisacsh Scanning probe microscopy Nanoelectronics Ionic crystals Thin films Surfaces Nanostruktur (DE-588)4204530-7 gnd Oberfläche (DE-588)4042907-6 gnd Nichtleiter (DE-588)4123451-0 gnd |
| subject_GND | (DE-588)4204530-7 (DE-588)4042907-6 (DE-588)4123451-0 |
| title | Nanoscale processes on insulating surfaces |
| title_auth | Nanoscale processes on insulating surfaces |
| title_exact_search | Nanoscale processes on insulating surfaces |
| title_full | Nanoscale processes on insulating surfaces Enrico Gnecco, Marek Szymonski |
| title_fullStr | Nanoscale processes on insulating surfaces Enrico Gnecco, Marek Szymonski |
| title_full_unstemmed | Nanoscale processes on insulating surfaces Enrico Gnecco, Marek Szymonski |
| title_short | Nanoscale processes on insulating surfaces |
| title_sort | nanoscale processes on insulating surfaces |
| topic | SCIENCE / Microscopes & Microscopy bisacsh Scanning probe microscopy Nanoelectronics Ionic crystals Thin films Surfaces Nanostruktur (DE-588)4204530-7 gnd Oberfläche (DE-588)4042907-6 gnd Nichtleiter (DE-588)4123451-0 gnd |
| topic_facet | SCIENCE / Microscopes & Microscopy Scanning probe microscopy Nanoelectronics Ionic crystals Thin films Surfaces Nanostruktur Oberfläche Nichtleiter |
| url | http://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=340499 |
| work_keys_str_mv | AT gneccoenrico nanoscaleprocessesoninsulatingsurfaces AT szymonskimarek nanoscaleprocessesoninsulatingsurfaces AT worldscientificfirm nanoscaleprocessesoninsulatingsurfaces |