Master degree in Materials Science

Materials for energy: superconductors, H2 storage and batteries

Materials for energy: superconductors, H2 storage and batteries

Academic year 2021/2022

Sommario del corso

• Course objectives
• Results of learning outcomes
• Course delivery
• Learning assessment methods
• Program
• Suggested textbooks and readings
• Notes
• Teaching tools

Course objectives

Energy production, harvesting, storage, use and saving represent crucial issues for the development of sustainable  economies and societies. The development of advanced materials along with their relevant technologies plays an important role in implementing effective solutions for these challenges. The present course is intended to face these problems by presenting the properties of a few classes of materials that are playing  an increasing role in the life cycle of energy. Among them, metallic low temperature superconductors as well as high-temperature superconducting oxides will be discussed from the point of view of their structure, properties, governing physics, main applications, economical opportunities and limits of their performances.   

Moreover, materials for energy storage,  energy harvesting and batteries will be discussed with special attention to hydrogen storage materials and thermoelectric materials. Principles for energy storage, energy harvesting and batteries will be described together with the strategies for the development of materials suitable for the applications.

Results of learning outcomes

• Ability to describe the fundamental properties of various classes of superconducting materials and their respective fields of application, with special care to energy-related applications
• Ability to master the basic concepts underlying the properties of superconducting materials
• Ability to understand and manage fundamental physical models describing the properties of superconductors
• Ability to describe the fundamental principles of hydrogen storage and energy harvesting.
• Knowledge of the main hydrogen storage materials, thermoelectric materials and materials for batteries and knowledge of their properties
• Understanding of the relationship between compositions, microstructures and properties of hydrogen storage materials and thermoelectric materials

Course delivery

Lectures 32 hours.

Attendance to lecture is advised but not compulsory.

Learning assessment methods

The exam consists of oral questions on the topics dealt with during the lectures

Program

• BEHAVIOR OF NORMAL METALS: Pauli paramagnetism
• PHENOMENOLOGY OF SUPERCONDUCTING MATERIALS: superconducting transition, critical magnetic field, critical current density.
• THERMODYNAMICS OF THE SUPERCONDUCTING TRANSITION: difference in Gibbs free energy, entropy and specific heat between superconducting and normal state.
• TYPE II SUPERCONDUCTORS: vortexes and their involvement in energy dissipation and in magnetic levitation.
• CRYSTAL STRUCTURE AND ELECTRONIC PROPERTIES: Most common structures, role of oxygen doping in high-Tc superconductors, defect production for vortex pinning.
• APPLICATIONS OF SUPERCONDUCTING MATERIALS: cables for electricity transport, power generators, electrical motors, levitation systems, electromagnets for research and medicine, digital circuits.
• PHYSICAL DESCRIPTION OF SUPERCONDUCTING BEHAVIOR: The first London equation for non-dissipating electrons. The second London equation for perfect diamagnetism and magnetic penetration depth. Intuitive description of Cooper pairing.
• Principles of energy storage
• Description of batteries
• Description of the different materials for hydrogen storage: metal compounds and relative metal hydrides; complex hydrides
• Principles of energy harvesting
• Description of materials for energy harvesting: thermoelectric materials

Teachers’ notes.

Class schedule

Note

A copy of slides is avaiable in Moodle

• Teaching materials
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