| 課程大綱 Syllabus |
學生學習目標
Learning Objectives |
單元學習活動
Learning Activities |
學習成效評量
Evaluation |
備註
Notes |
序
No. | 單元主題
Unit topic |
內容綱要
Content summary |
| 1 | Introduction-Part I |
Origin and development of nanomaterials |
1. Describe key milestones and the historical development of nanomaterials.
2. Explain major scientific breakthroughs shaping nanotechnology.
3. Analyze links between nanomaterial advances and industry needs. |
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| 2 | Introduction-Part II |
Classification of nanomaterials |
1. Classify nanomaterials by dimensionality and composition.
2. Distinguish metals, semiconductors, carbon-based, and composites.
3. Relate structure types to functional properties. |
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| 3 | Introduction-Part III |
Fundamental properties of nanomaterials |
1. Explain unique optical, electrical, and magnetic properties at the nanoscale.
2. Analyze surface-to-volume effects on reactivity.
3. Compare nanoscale properties with bulk materials. |
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| 4 | Introduction-Part IV |
Core nanotechnology concepts and techniques |
1. Differentiate top-down and bottom-up fabrication methods.
2. Explain principles of key characterization techniques.
3. Interpret basic nanoscale characterization data. |
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| 5 | Nanomaterial Technology Categories |
Classification of nanomaterial fabrication technologies |
1. Classify fabrication methods as physical, chemical, or biological.
2. Compare common synthesis techniques and their mechanisms.
3. Evaluate process parameters affecting material performance. |
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| 6 | Properties of Nanomaterials |
Fundamental properties of nanomaterials and size effects |
1. Explain size-dependent changes in electronic structure and band gap.
2. Analyze surface and quantum confinement effects.
3. Relate size variation to catalytic and optoelectronic behavior. |
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| 7 | Nanophotocatalysts |
Principles and applications of photocatalysis |
1. Explain charge generation and separation in photocatalysis.
2. Analyze band structure effects on photocatalytic efficiency.
3. Evaluate photocatalyst performance in energy and environmental uses. |
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| 8 | Midterm Exam |
Group oral presentation covering the first half of the course |
Midterm Exam |
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報告
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期中報告30% |
| 9 | Characterization I |
Surface area and porosity analysis |
1. Explain principles of surface area and pore size measurements.
2. Interpret adsorption–desorption isotherms and pore distribution data.
3. Correlate porosity with catalytic and transport performance. |
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| 10 | Characterization II |
Physical property characterization of nanomaterials |
1. Describe techniques for analyzing mechanical, thermal, and electrical properties.
2. Interpret experimental data from physical characterization methods.
3. Relate physical properties to nanoscale structure. |
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| 11 | Characterization III |
Chemical composition and bonding analysis |
1. Explain methods for elemental and chemical state analysis.
2. Interpret spectra to identify bonding environments.
3. Correlate composition and bonding with material functionality. |
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| 12 | Fabrication Methods I |
Sol-gel synthesis of nanomaterials |
1. Preparation of the nano photocatalysts through a sol-gel method.
2. Control synthesis parameters to tailor particle size and structure.
3. Evaluate the advantages and limitations of the sol–gel method. |
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| 13 | Fabrication Methods II |
Hydrothermal synthesis of nanomaterials |
1. 1. Preparation of the nano photocatalysts through a hydrothermal method.
2. Analyze effects of temperature and pressure on morphology.
3. Compare hydrothermal synthesis with other wet-chemical methods. |
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| 14 | Applications I |
Semiconductor applications of nanomaterials |
1. Explain nanoscale effects on semiconductor electronic properties.
2. Analyze nanomaterials in devices such as sensors and transistors.
3. Evaluate performance improvements from nanostructuring. |
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| 15 | Applications II |
Optoelectronic and ceramic applications of nanomaterials |
1. Explain the optical and electronic functions of nanomaterials.
2. Relate microstructure to mechanical and dielectric properties in ceramics.
3. Assess application potential in optoelectronic and advanced ceramic systems. |
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| 16 | Final Exam |
Comprehensive assessment of course topics |
Final Exam |
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報告
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期末報告30% |