Nanomaterials Introduction Series

Learning Nanomaterial Science through Python Practice

About This Series

This series is an educational content that systematically covers Nanomaterials from fundamentals to practical data analysis and materials design. You will learn property prediction and materials design methods using machine learning and data-driven approaches for representative nanomaterials such as carbon nanotubes, graphene, quantum dots, and metal nanoparticles.

Target Audience

Undergraduate and graduate students (Engineering, Materials Science, Chemistry, Physics)
Beginners in nanomaterials research
Researchers and engineers who want to apply machine learning to materials development
Those considering a career in nanotechnology

Learning Objectives

Upon completing this series, you will acquire the following skills:

✅ Understanding basic principles of nanomaterials and size effects
✅ Knowledge of nanoparticle synthesis and characterization techniques
✅ Nanomaterial data analysis and visualization with Python
✅ Prediction of nanomaterial properties using machine learning
✅ Practical nanomaterial design using Bayesian optimization
✅ Problem-solving skills through real-world application cases

Prerequisites

Required: High school mathematics (statistics, calculus), Python basics
Recommended: University-level physics and chemistry (year 1-2), linear algebra, basic concepts of machine learning

Series Structure

📘 Chapter 1: Introduction to Nanomaterials

Reading Time: 20-25 min | Level: Beginner

Learn about the definition of nanomaterials, size effects, quantum effects, and classification (0D to 3D nanomaterials). Understand the characteristics and application fields of representative nanomaterials such as carbon nanotubes, graphene, quantum dots, and metal nanoparticles.

Learning Content:
- Definition of nanoscale and size effects
- Quantum effects and quantum confinement effects
- Dimensional classification of nanomaterials
- Application fields (energy, electronics, medicine, environment)

👉 Read Chapter 1

📗 Chapter 2: Fundamental Principles of Nanomaterials

Reading Time: 25-30 min | Level: Beginner to Intermediate

Learn about nanomaterial synthesis methods, characterization techniques, size-dependent properties, and surface/interface effects. Understand measurement techniques such as TEM, SEM, XRD, and UV-Vis, as well as the mechanisms of property emergence unique to nanomaterials.

Learning Content:
- Bottom-up and top-down synthesis methods
- Characterization techniques (TEM, SEM, XRD, UV-Vis, Raman)
- Size-dependent properties (melting point depression, optical properties, magnetic properties)
- Surface area/volume ratio and surface energy

👉 Read Chapter 2

💻 Chapter 3: Python Practical Tutorial

Reading Time: 30-40 min | Level: Intermediate

Practice nanomaterial data analysis and visualization using Python, property prediction using machine learning, and materials design using Bayesian optimization. Through 30-35 executable code examples, you will acquire techniques that can be used in actual nanomaterials research.

Learning Content:
- Analysis and visualization of nanoparticle size distributions
- Prediction of optical properties (plasmon resonance, quantum dot emission)
- Property prediction using five types of regression models
- Nanomaterial design using Bayesian optimization
- Analysis of molecular dynamics (MD) data
- Prediction interpretation using SHAP analysis

Libraries Used:

pandas, numpy, matplotlib, seaborn, scikit-learn,
lightgbm, scipy, scikit-optimize, shap

👉 Read Chapter 3

🏭 Chapter 4: Real-World Applications and Careers

Reading Time: 20-25 min | Level: Intermediate

Learn about actual success stories in nanomaterials research through five case studies. Understand the problem-solving process through practical application cases of carbon nanotube composite materials, quantum dots, gold nanoparticle catalysts, graphene, and nanomedicines.

Case Studies:
1. Mechanical Property Optimization of Carbon Nanotube (CNT) Composite Materials
2. Emission Wavelength Control of Quantum Dots
3. Activity Prediction of Gold Nanoparticle Catalysts
4. Electrical Property Control of Graphene
5. Design of Nanomedicines (Drug Delivery)

Career Information:
- Academia vs Industry
- Job types and salaries in the nanomaterials field
- Required skill sets

👉 Read Chapter 4

How to Study

Recommended Learning Path

flowchart LR A[Chapter 1< br>Introduction] --> B[Chapter 2< br>Fundamentals] B --> C[Chapter 3< br>Python Practice] C --> D[Chapter 4< br>Applications] style A fill:#e1f5ff style B fill:#fff4e1 style C fill:#e8f5e9 style D fill:#fce4ec

Study Method

Chapter 1-2 (Fundamentals): First, understand the concepts thoroughly
- Basic principles of nanomaterials and size effects
- Synthesis methods and characterization techniques
Chapter 3 (Practice): Learn by doing
- Execute all code examples yourself
- Change parameters and observe behavior
- Work on exercises
Chapter 4 (Applications): Think about application to real problems
- Apply case studies to your own research
- Concretize your career plan

Environment Setup

The following environment is required for Chapter 3 practice:

Recommended Environment:
- Python 3.8 or higher
- Jupyter Notebook or Google Colab
- Main libraries: pandas, scikit-learn, lightgbm, scipy, scikit-optimize

Installation instructions are explained in detail in Chapter 3.

Series Features

🎯 Practice-Oriented

You can acquire techniques that can be used in actual nanomaterials research through 30-35 executable Python code examples.

📊 Data-Driven Approach

Learn the latest methods of nanomaterial design using machine learning and Bayesian optimization.

🔬 Real Application Cases

Understand the flow of actual research and development projects through five detailed case studies.

🌐 Learn in English

Technical terms are provided with both English and Japanese, building a foundation for reading international literature.

Related Series

This site also publishes the following series:

- AI/ML application to materials science in general
Introduction to Process Informatics - Chemical process optimization and digital twins

References and Resources

Main Textbooks

Cao, G. & Wang, Y. (2011). Nanostructures and Nanomaterials: Synthesis, Properties, and Applications (2nd ed.). World Scientific. DOI: 10.1142/7885
Pokropivny, V. V. & Skorokhod, V. V. (2007). Classification of nanostructures by dimensionality and concept of surface forms engineering in nanomaterial science. Materials Science and Engineering: C, 27(5-8), 990-993. DOI: 10.1016/j.msec.2006.09.023
Roduner, E. (2006). Size matters: why nanomaterials are different. Chemical Society Reviews, 35(7), 583-592. DOI: 10.1039/B502142C

Online Resources

MIT OpenCourseWare: Nanomaterials courses
Coursera: Nanotechnology specialization
Materials Project: Nanomaterials database (https://materialsproject.org)

Feedback and Questions

For questions and feedback regarding this series, please contact:

Dr. Yusuke Hashimoto
Institute of Multidisciplinary Research for Advanced Materials (IMRAM)
Tohoku University
Email: yusuke.hashimoto.b8@tohoku.ac.jp

License

This content is published under Creative Commons Attribution 4.0 International License.

Free use for educational and research purposes is welcome. Please use the following format for citations:

Yusuke Hashimoto (2025) 'Nanomaterials Introduction Series v1.0' Tohoku University
https://yusukehashimotolab.github.io/wp/knowledge/nm-introduction/

Last Updated: October 16, 2025
Version: 1.0

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