PHYSICS AND TECHNOLOGY OF TWO-DIMENSIONAL MATERIALS AND DEVICES

The fundamental training objective consists in the acquisition of in-depth knowledge relating to the properties, preparation and stability of two-dimensional materials (semimetals, semiconductors and metals) and the transport mechanisms in disordered low-dimensional materials.

At the end of the course the student will be able to understand and frame in a general context the most recent developments relating to synthesis, optical and transport properties in two-dimensional materials (giant Faraday rotation, anomalous Berry phase, Klein tunneling), focusing on the example of graphene and transition metal dichalcogenides. In a second part, the course will focus on the study of transport in disordered and granular two-dimensional materials, addressing the theory of localisation (localised and extended states, Anderson localization, finite temperatures and inelastic scattering effects), transport between localized states at finite temperatures and transport by hopping (VRH, NNH, ES-VRH), strong and weak localization concepts for disordered metallic materials and for low-dimensional structures.

Furthermore, with reference to the so-called Dublin Descriptors, this course helps to acquire the following transversal skills:

Knowledge and understanding abilities

• Critical understanding of the most advanced developments of Modern Physics, both theoretical and experimental, and their interrelations, also across different subjects
• Remarkable acquaintance with the scientific method, understanding of nature, and of the research in Physics

Applying knowledge and understanding ability

• Ability to identify the essential elements in a phenomenon, in terms of orders of magnitude and approximation level, and being able to perform the required approximations
• Ability to use analogy as a tool to apply known solutions to new problems (problem solving)
• Ability to plan and apply experimental and theoretical procedures to solve problems in academic or applied research, or to improve existing results

Ability of making judgements

• Ability to convey own interpretations of physical phenomena, when discussing within a research team

Communication skills

• Ability to discuss about advanced physical concepts, both in Italian and in English
• Ability to present one's own research activity or a review topic both to an expert and to an non-expert audience

Learning skills

• Ability to access to specialized literature both in the specific field of one's expertise, and in closely related fields
• Ability to exploit databases and bibliographical and scientific resources to extract information and suggestions to better frame and develop one's study and research activity

Teaching

Lectures (remote teaching may be adopted, if restriction apply following University’s guidances).

During each lesson, students will always be given time for questions and comments. The lecturer-student interaction will be one of the fundamental element during lectures.

Prerequisites

Extensive and in-depth knowledge of: Thermodynamics, Electromagnetism, Quantum Mechanics, Structure of matter, Physics of the solid state are fundamental.

Attendance to lectures

Mandatory

Should the circumstances require full or partial online teaching, appropriate modifications to what is hereby stated may be introduced in order to achieve the main objectives of the course.

Exams

Exams may take place online, depending on circumstances.

1) Introduction to graphene and two-dimensional materials: from 3D materials with Van der Waals bonds to two-dimensional materials. The example of graphene.
2) The electronic structure and the electrical and optical properties: transport of charge carriers in graphene. Graphene nanostructured films. Quantum phenomena originating in two-dimensional structures (quantum Hall effect and Faraday rotation).
3) Optical properties of 2D materials in the visible and near infrared.
4) Synthesis of two-dimensional materials: Mechanical exfoliation, Chemical vapor deposition, Solution Processing (Liquid phase, chemical routes), Nano-composites.
5) Nanostructured devices: junctions of 2D materials. Hybrid junctions and 1D-2D hybrid devices or quantum-dots / graphene. Field-effect transistor with 2D materials.
6) Transparent and conductive thin films: Comparison with TCO, applications in flexible and printed electronics.
7) Transport in disordered and granular materials.
8) Concepts of strong and weak localization for disordered metal materials and for low-dimensional structures.
9) Theory of localization (localized and extended states, Anderson localization, finite temperatures and inelastic scattering effects).
10) Transport between localized states at finite temperatures and transport via hopping (VRH, NNH, ES-VRH).

1) “Nanotechnology for Microelectronics and Optoelectronics”, J. M. Martinez-Duart, R. J. Martin-Palma, F.

Agullo-Rueda, Elsevier 2006

2) “Quantum Transport-Atom to transistor”, S. Datta, Cambridge University Press 2005

3) “Transport in Nanostructures”, D. K. Ferry, S. M. Goodnick, J. Bird, Cambridge University Press 2009

4) “The Physics of low-dimensional semiconductors-an introduction”, J. H. Davies, Cambridge University

5) “The Physics of graphene”, M. I. Katsnelshon, Cambridge University Press.