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Electronic packaging science and technology / / King-Ning Tu, Chih Chen, Hung-Ming Chen
| Electronic packaging science and technology / / King-Ning Tu, Chih Chen, Hung-Ming Chen |
| Autore | Tu K. N (King-Ning), <1937-> |
| Pubbl/distr/stampa | Newark : , : John Wiley & Sons, , [2022] |
| Descrizione fisica | 1 online resource (330 pages) |
| Disciplina | 621.381046 |
| Soggetto topico | Electronic packaging |
| Soggetto genere / forma | Electronic books. |
| ISBN |
1-119-41833-X
1-119-41834-8 1-119-41832-1 |
| Formato | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Record Nr. | UNINA-9910555039203321 |
Tu K. N (King-Ning), <1937->
|
||
| Newark : , : John Wiley & Sons, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Electronic packaging science and technology / / King-Ning Tu, Chih Chen, Hung-Ming Chen
| Electronic packaging science and technology / / King-Ning Tu, Chih Chen, Hung-Ming Chen |
| Autore | Tu K. N (King-Ning), <1937-> |
| Pubbl/distr/stampa | Newark : , : John Wiley & Sons, , [2022] |
| Descrizione fisica | 1 online resource (330 pages) |
| Disciplina | 621.381046 |
| Soggetto topico | Electronic packaging |
| ISBN |
1-119-41833-X
1-119-41834-8 1-119-41832-1 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Electronic packaging. |
| Record Nr. | UNINA-9910830046703321 |
|
Tu K. N (King-Ning), <1937->
|
||
| Newark : , : John Wiley & Sons, , [2022] | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Kinetics in nanoscale materials / / King-Ning Tu, Andriy Gusak
| Kinetics in nanoscale materials / / King-Ning Tu, Andriy Gusak |
| Autore | Tu K. N (King-Ning), <1937-> |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , 2014 |
| Descrizione fisica | 1 online resource (308 p.) |
| Disciplina | 620.1/1599 |
| Soggetto topico |
Nanostructured materials
Chemical kinetics Nanostructured materials - Analysis Nanostructured materials - Computer simulation |
| ISBN |
1-118-74283-4
1-118-74314-8 1-118-74287-7 |
| Classificazione | TEC021000 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter 1. Introduction to kinetics in nanoscale materials -- 1.1 Introduction -- 1.2 Nanosphere: Surface energy equivalent to the Gibbs-Thomson potential -- 1.3 Nanosphere: Lower melting point -- 1.4 Nanosphere: Effect on homogeneous nucleation and phase diagram -- 1.5 Nanosphere: The Kirkendall effect and instability of hollow nanospheres -- 1.6 Nanosphere: The inverse Kirkendall effect in hollow alloy nanospheres -- 1.7 Nanosphere: Combining the Kirkendall effect and inverse Kirkendall effect on concentric bi-layer hollow nanospheres -- 1.8 Nanopore: Instability of a nanodonut hole in a membrane -- 1.9 Nanowire: Point contact reactions between metal and silicon nanowires -- 1.10 Nanowire: Nano gap in silicon nanowires -- 1.11 Nanowire: Lithiation in silicon nanowires -- 1.12 Nanowire: Point contact reactions between metallic nanowires -- 1.13 Nano-thin film: Explosive reaction in periodic multi-layered nano-thin films -- 1.14 Nano-microstructure in bulk sample: Nanotwins in Cu -- 1.15 Nano-microstructure on the surface of a bulk sample : surface mechanical attrition treatment (SMAT) of steel -- Chapter 2. Linear and Non-linear Diffusion -- 2.1 Introduction -- 2.2 Linear diffusion -- 2.3 Non-linear diffusion -- 2.3.1 Non-linear effect due to kinetic consideration -- Chapter 3. Kirkendall effect and inverse Kirkendall effect -- 3.1 Introduction -- 3.2 Kirkendall effect -- 3.3 Inverse Kirkendall effect -- Chapter 4. Ripening among nano precipitates -- 4.1 Introduction -- 4.2 Ham's model of growth of a large spherical precipitate -- 4.3 Mean field consideration -- 4.4 Gibbs-Thomson potential -- 4.5 Growth and dissolution of a spherical nano precipitate in a mean field -- 4.6 LSW Theory of kinetics of particle ripening -- 4.7 Continuity equation in size space -- 4.8 Size distribution function in conservative ripening -- Chapter 5. Spinodal decomposition -- 5.1 Introduction -- 5.2 Implication of diffusion equation in homogenization and in decomposition -- 5.3 Spinodal decompostion -- Chapter 6. Nucleation events in bulk materials, thin films, and nano-wires -- 6.1 Introduction -- 6.2 Thermodynamics and kinetics of nucleation -- 6.3 Heterogeneous nucleation in grain boundaries of bulk materials -- 6.4 No homogeneous nucleation in epitaxial growth of Si thin film on Si wafer -- Chapter 7. Contact reactions on Si; plane, line, and point contact reactions -- 7.1 Introduction -- 7.2 Bulk cases -- 7.3 Thin film cases -- 7.4 Nanowire cases -- Chapter 8. Grain growth in micro and nano scale -- 8.1 Introduction -- 8.2 Computer simulation to generate a 2D polycrystalline microstructure -- 8.3 Computer simulation of grain growth -- 8.4 Statistical distribution functions of grain size -- 8.5 Deterministic approach to grain growth modeling -- 8.6 Coupling between grain growth of a central grain and the rest of grains 8.7 Decoupling the grain growth of a central grain from the rest of grains in the normalized size space -- 8.8 Grain growth in 2D case in the normalized size space -- 8.9 Grain rotation of nano-grains -- Chapter 9. Self-sustained reactions in nanoscale multi-layered thin films -- 9.1 Introduction -- 9.2 The selection of a pair of metallic thin films for self-sustained reaction -- 9.3 A simple model of single-phase growth in self-sustained reaction -- 9.4 Estimate of flame velocity in steady state heat transfer -- 9.5 Comparison between reactions by annealing and by explosive reaction in Al/Ni -- 9.6 Self-explosive silicidation reactions -- Chapter 10. Formation and transformations of nano-twins in copper -- 10.1 Introduction -- 10.2 Formation of nano-twins in Cu -- 10.2.1 First principle calculation of energy of formation of nano-twins -- 10.3 Formation and transformation of oriented nano-twins in Cu -- 10.4 Potential applications of nano-twinned Cu References -- Appendix A: Laplace pressure of nano-cubic particles -- Appendix B: Derivation of interdiffusion coefficient as CMG -- Appendix C: Non-equilibrium vacancies -- Appendix D: Interaction between Kirkendall effect and Gibbs-Thomson effect in the formation of a spherical compound nanoshell. |
| Record Nr. | UNINA-9910132334703321 |
|
Tu K. N (King-Ning), <1937->
|
||
| Hoboken, New Jersey : , : Wiley, , 2014 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||
Kinetics in nanoscale materials / / King-Ning Tu, Andriy Gusak
| Kinetics in nanoscale materials / / King-Ning Tu, Andriy Gusak |
| Autore | Tu K. N (King-Ning), <1937-> |
| Edizione | [2nd ed.] |
| Pubbl/distr/stampa | Hoboken, New Jersey : , : Wiley, , 2014 |
| Descrizione fisica | 1 online resource (308 p.) |
| Disciplina | 620.1/1599 |
| Soggetto topico |
Nanostructured materials
Chemical kinetics Nanostructured materials - Analysis Nanostructured materials - Computer simulation |
| ISBN |
1-118-74283-4
1-118-74314-8 1-118-74287-7 |
| Classificazione | TEC021000 |
| Formato | Materiale a stampa |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione | eng |
| Nota di contenuto | Chapter 1. Introduction to kinetics in nanoscale materials -- 1.1 Introduction -- 1.2 Nanosphere: Surface energy equivalent to the Gibbs-Thomson potential -- 1.3 Nanosphere: Lower melting point -- 1.4 Nanosphere: Effect on homogeneous nucleation and phase diagram -- 1.5 Nanosphere: The Kirkendall effect and instability of hollow nanospheres -- 1.6 Nanosphere: The inverse Kirkendall effect in hollow alloy nanospheres -- 1.7 Nanosphere: Combining the Kirkendall effect and inverse Kirkendall effect on concentric bi-layer hollow nanospheres -- 1.8 Nanopore: Instability of a nanodonut hole in a membrane -- 1.9 Nanowire: Point contact reactions between metal and silicon nanowires -- 1.10 Nanowire: Nano gap in silicon nanowires -- 1.11 Nanowire: Lithiation in silicon nanowires -- 1.12 Nanowire: Point contact reactions between metallic nanowires -- 1.13 Nano-thin film: Explosive reaction in periodic multi-layered nano-thin films -- 1.14 Nano-microstructure in bulk sample: Nanotwins in Cu -- 1.15 Nano-microstructure on the surface of a bulk sample : surface mechanical attrition treatment (SMAT) of steel -- Chapter 2. Linear and Non-linear Diffusion -- 2.1 Introduction -- 2.2 Linear diffusion -- 2.3 Non-linear diffusion -- 2.3.1 Non-linear effect due to kinetic consideration -- Chapter 3. Kirkendall effect and inverse Kirkendall effect -- 3.1 Introduction -- 3.2 Kirkendall effect -- 3.3 Inverse Kirkendall effect -- Chapter 4. Ripening among nano precipitates -- 4.1 Introduction -- 4.2 Ham's model of growth of a large spherical precipitate -- 4.3 Mean field consideration -- 4.4 Gibbs-Thomson potential -- 4.5 Growth and dissolution of a spherical nano precipitate in a mean field -- 4.6 LSW Theory of kinetics of particle ripening -- 4.7 Continuity equation in size space -- 4.8 Size distribution function in conservative ripening -- Chapter 5. Spinodal decomposition -- 5.1 Introduction -- 5.2 Implication of diffusion equation in homogenization and in decomposition -- 5.3 Spinodal decompostion -- Chapter 6. Nucleation events in bulk materials, thin films, and nano-wires -- 6.1 Introduction -- 6.2 Thermodynamics and kinetics of nucleation -- 6.3 Heterogeneous nucleation in grain boundaries of bulk materials -- 6.4 No homogeneous nucleation in epitaxial growth of Si thin film on Si wafer -- Chapter 7. Contact reactions on Si; plane, line, and point contact reactions -- 7.1 Introduction -- 7.2 Bulk cases -- 7.3 Thin film cases -- 7.4 Nanowire cases -- Chapter 8. Grain growth in micro and nano scale -- 8.1 Introduction -- 8.2 Computer simulation to generate a 2D polycrystalline microstructure -- 8.3 Computer simulation of grain growth -- 8.4 Statistical distribution functions of grain size -- 8.5 Deterministic approach to grain growth modeling -- 8.6 Coupling between grain growth of a central grain and the rest of grains 8.7 Decoupling the grain growth of a central grain from the rest of grains in the normalized size space -- 8.8 Grain growth in 2D case in the normalized size space -- 8.9 Grain rotation of nano-grains -- Chapter 9. Self-sustained reactions in nanoscale multi-layered thin films -- 9.1 Introduction -- 9.2 The selection of a pair of metallic thin films for self-sustained reaction -- 9.3 A simple model of single-phase growth in self-sustained reaction -- 9.4 Estimate of flame velocity in steady state heat transfer -- 9.5 Comparison between reactions by annealing and by explosive reaction in Al/Ni -- 9.6 Self-explosive silicidation reactions -- Chapter 10. Formation and transformations of nano-twins in copper -- 10.1 Introduction -- 10.2 Formation of nano-twins in Cu -- 10.2.1 First principle calculation of energy of formation of nano-twins -- 10.3 Formation and transformation of oriented nano-twins in Cu -- 10.4 Potential applications of nano-twinned Cu References -- Appendix A: Laplace pressure of nano-cubic particles -- Appendix B: Derivation of interdiffusion coefficient as CMG -- Appendix C: Non-equilibrium vacancies -- Appendix D: Interaction between Kirkendall effect and Gibbs-Thomson effect in the formation of a spherical compound nanoshell. |
| Record Nr. | UNINA-9910823862103321 |
|
Tu K. N (King-Ning), <1937->
|
||
| Hoboken, New Jersey : , : Wiley, , 2014 | ||
| Materiale a stampa | ||
| Lo trovi qui: Univ. Federico II | ||
| ||