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To inform the student about the magnetic properties of nanomaterials, to enable the student to understand this most basic property of nanomaterials, and thus to enable them to develop projects using nanomaterials in technology.

Chapter 1. What are Nanos?

1.1. What are we talking about?

Chapter 2. Some Science to Get You Started

2.1. Quantum physics, basic explanation

Chapter 3. The Revolution in Techniques Used in Observation and Imagery.

Chapter 4. The Uses of Nanotechnologies

Chapter 5. Magnetic Fields and magnetic materials

5.1.  Magnetic fields

5.2. Magnetic materials,

5.3. Magnetic materials under field – The hysteresis loop,

5.4. Domains and domain walls.

Chapter 6. Units in Magnetism, Defining magnetic Field H and  Defining magnetization M

Chapter 7. The various types of magnetic energy

7.1. Zeeman Energy

7.2. Magnetic anisotropy energy

7.4. Exchange energy

7.5. Magnetostatic energy

7.6. Characteristic quantities

Chapter 8. Handling dipolar interactions

8.1. Simple views on dipolar interactions

8.2. Various ways to handle magnetostatics

8.3. Demagnetizing factors

Chapter 9. The Bloch domain wall

9.1.  Simple variational model

9.2. Exact model

9.3. Defining the width of a domain wall

Chapter 10. Magnetometry and magnetic imaging

10.1 Extraction and vibrating magnetometers,

10.2. Faraday and Kerr effects,

10.3 X-ray Magnetic Dichroism techniques

     10.3.1. X-RAY MAGNETIC CIRCULAR DICHROISM

     10.3.2. XMCD PHOTO-EMISSION ELECTRON MICROSCOPY

     10.3.3. XMCD TRANSMISSION X-RAY MICROSCOPY

10.4 Scanning probe microscopies

     10.4.1. MAGNETIC FORCE MICROSCOPY

     10.4.2. SPIN-POLARIZED SCANNING TUNNELING MICROSCOPY

     10.4.3. NV-CENTER MICROSCOPY

10.5 Electron microscopies

     10.5.1. LORENTZ MICROSCOPY AND HOLOGRAPHY

     10.5.2. SCANNING ELECTRON MICROSCOPY WITH POLARIZATION ANALYSIS (SEMPA)

     10.5.3. SPIN-POLARIZED LOW-ENERGY ELECTRON MICROSCOPY (SPLEEM)