Thin film growth : physics, materials science and applications

摘要: Contributor contact details Praface Part I: Theory of thin film growth Chapter 1: Measuring nucleation and processes in films Abstract: 1.1 Introduction 1.2 Basic theory epitaxial 1.3 Observation method atomic steps 1.4 Two-dimensional-island step-flow modes 1.5 The motion on a growing evaporating Si(111) surface 1.6 Morphological instability 1.7 Conclusion future trends 1.9 Appendix 2: Quantum electronic stability atomically uniform 2.1 2.2 Electronic 2.3 Angle-resolved photoemission spectroscopy 2.4 Atomically 2.5 thermal 2.6 General principles nanostructure development 2.7 Beyond the particle-in-a-box 2.8 Future 2.9 Acknowledgments 3: Phase-field modeling 3.1 3.2 Modeling 3.3 Numerical results 3.4 4: Analysing roughness evolution 4.1 4.2 Roughness during homo-epitaxial 4.3 hetero- or non-epitaxial 4.4 5: Modelling deposition based real-time observation 5.1 Introduction: time resolved science 5.2 Basics relevant length timescales for in-situ 5.3 Experimental techniques studies 5.4 case 5.5 5.6 Sources further information advice II: Techniques 6: Silicon nanostructured grown templated surfaces by oblique angle 6.1 6.2 Preparation 6.3 Fan-out with normal incident flux 6.4 6.5 Control fan-out substrate rotations 6.6 Applications 7: Phase transitions colloidal crystal 7.1 7.2 tools 7.3 Description phases: historical survey 7.4 transition sequence 7.5 Conclusions 7.6 Acknowledgements 8: Thin thermally unstable noble-metal nitrides reactive magnetron sputtering 8.1 8.2 Deposition stoichiometric Cu3N 8.3 Nitrogen re-emission 8.4 Doping co-sputtering 8.5 9: Growth graphene layers 9.1 9.2 Large-scale pattern stretchable transparent electrodes 9.3 Roll-to-roll production 30-inch 9.4 10: Epitaxial single metal 10.1 10.2 Structure metals 10.3 10.4 10.5 10.6 11: properties adsorption behaviour polar character 11.1 to oxide polarity 11.2 Polar 11.3 11.4 Adsorption 11.5 11.7 11.6 12: Polarity controlled epitaxy III-nitrides ZnO molecular beam 12.1 12.2 Lattice detection methods 12.3 issues at heteroepitaxy homoepitaxy 12.4 GaN AlN 12.5 InN 12.6 12.7 13: Understanding plasticity buckling 13.1 13.2 observations 13.3 13.4 Discussion 13.5 14: Controlled compliant substrates electronics 14.1 14.2 Mechanics one-dimensional non-coplanar mesh design 14.3 two-dimensional 14.4 15: electrocaloric effect (ECE) ferroelectric polymer 15.1 15.2 Thermodynamic considerations materials large 15.3 Previous investigations 15.4 Large 15.5 15.6 15.7 16: Network behavior dynamics 16.1 16.2 Origins network 16.3 Monte Carlo simulations 16.4 Results discussion 16.5 Index