PORTALE DELLA DIDATTICA

PORTALE DELLA DIDATTICA

PORTALE DELLA DIDATTICA

Elenco notifiche



Electronic transport in crystalline and organic semiconductors

01UAZOQ, 01UAZPE

A.A. 2024/25

Course Language

Inglese

Degree programme(s)

Master of science-level of the Bologna process in Ingegneria Elettronica (Electronic Engineering) - Torino
Master of science-level of the Bologna process in Nanotechnologies For Icts (Nanotecnologie Per Le Ict) - Torino/Grenoble/Losanna

Course structure
Teaching Hours
Lezioni 39
Esercitazioni in laboratorio 21
Lecturers
Teacher Status SSD h.Les h.Ex h.Lab h.Tut Years teaching
Bertazzi Francesco Professore Ordinario IINF-01/A 22 0 21 0 6
Co-lectures
Espandi

Context
SSD CFU Activities Area context
ING-INF/01 6 B - Caratterizzanti Ingegneria elettronica
2023/24
Aim of the course is to present the theoretical foundations of electronic properties of materials, including polymeric and organic semiconductors, with particular emphasis on applications in the area of ICTs. This course plays a critical role in the development of an Engineer expert in Nanotechnologies, because it provides the elements for understanding the properties of semiconductors - both bulk and nanostructured - and prepares students for courses in quantum electronics.
The aim of the course is to present the theoretical foundations of electronic and carrier transport properties of materials, including crystalline, polymeric and organic semiconductors, with particular emphasis on applications in the area of ICTs. This course provides an introduction to advanced numerical techniques to understand the physics of (opto-)electronic devices, and prepares students for courses in quantum technologies.
Knowledge of elements of crystal structure. Knowledge of alternative approaches to the theoretical determination of the energy bands in semiconductors. Knowledge of scattering mechanisms in semiclassical theory of charge transport. Knowledge of the electronic and transport properties of polymeric and organic materials. Ability to use the empirical pseudopotential method to compute the electronic structure of crystalline semiconductors. Ability to solve the Boltzmann transport equation by means of a Monte Carlo particle-based approach. Ability to understand and analyze/design polymeric and organic (opto)electronic devices.
Theory of crystal structure. Full-Brillouin-zone descriptions of the electronic structure in crystalline semiconductors. Scattering theory in semiclassical carrier transport models. Basic elements of quantum transport in nanodevices. Ability to use the empirical pseudopotential method to compute the electronic structure of crystalline semiconductors. Ability to solve the Boltzmann transport equation by means of a Monte Carlo particle-based approach. Ability to solve the Schrödinger equation for nanostructured devices. Electronic and transport properties of polymeric and organic materials. Ability to understand and analyze/design polymeric and organic (opto)electronic devices.
Basics of quantum mechanics and solid-state physics. Operating principles of the most important electronic semiconductor devices. Fundamentals of numerical analysis.
Basics of quantum mechanics and solid-state physics. Basics of transmission lines and electromagnetic fields. Operating principles of the most important electronic semiconductor devices. Fundamentals of numerical analysis and Matlab.
Review of the crystal, electronic and transport properties of semiconductor materials and their alloys and heterostructures. Introduction to the empirical and ab initio approaches to the computation of the electronic structure of semiconductors. Details on the use of the empirical pseudopotential method for the approximation of the electronic structure of crystalline semiconductors (1.5 ECTS) Scattering theory: impurity scattering, carrier-phonon scattering, impact ionization scattering, radiative processes. Carrier transport in semiconductors, the Boltzmann transport equation, particle-based device simulation methods, the Monte Carlo approach (3 ECTS) Electronic properties of amorphous and crystalline polymers, conjugated polymers, organic conductors and semiconductors. Transport properties of organic semiconductors. Introduction to organic and polymeric based electronic devices. Inkjet printing technology of polymers (1.5 ECTS).
Review of the crystal, electronic and transport properties of semiconductor materials and their alloys and heterostructures. Introduction to the empirical and ab initio approaches to the computation of the electronic structure of semiconductors. Details on the use of the empirical pseudopotential method for the approximation of the electronic structure of crystalline semiconductors (1 ECTS). Scattering theory: impurity scattering, carrier-phonon scattering, impact ionization scattering, radiative processes. Carrier transport in semiconductors, the Boltzmann transport equation, particle-based device simulation methods, the Monte Carlo approach (3 ECTS). An introduction to quantum transport (1 ECTS). Electronic properties of amorphous and crystalline polymers, conjugated polymers, organic conductors and semiconductors. Transport properties of organic semiconductors. Introduction to organic and polymeric based electronic devices. Inkjet printing technology of polymers (1 ECTS).
The theory presented in class will be further illustrated through two numerical laboratories: (a) calculation of the electronic structure of crystalline semiconductor compounds and alloys with the empirical pseudopotential method; (b) development of a Monte Carlo simulation code for the study of electronic transport in semiconductors. Each laboratory will be organized in several sessions; the lab reports and the numerical codes written by the students will be discussed during the oral exam.
The theory presented in class will be further illustrated through three numerical laboratories 1) Development of a Monte Carlo simulation code for the study of semiclassical electronic transport in semiconductors (MC laboratory) 2) Calculation of the electronic structure of crystalline semiconductors with the empirical pseudopotential method (EPM laboratory) 3) Quantum transport in a superlattice by means of a transmission line approach (QT laboratory) Students must attend two laboratories: (i) the MC laboratory (mandatory for all students) and (ii) one laboratory (EPM or QT) selected by the teacher based on the student pathway program.
Detailed week-by-week syllabus, lecture notes, and laboratory/homework assignments will be posted on the course website. Supplementary texts include: M. Fischetti and W. G. Vandenberghe, Advanced Physics of Electron Transport in Semiconductors and Nanostructures, Springer 2016. C. Jacoboni and P. Lugli, The Monte Carlo Method for Semiconductor Device Simulation, ser. Computational Microelectronics, Springer 1989. D. Vasileska, S. M. Goodnick, and G. Klimeck, Computational Electronics. Semiclassical and Quantum Device Modeling and Simulation, CRC Press 2010. Ioannis Kymissis, Organic Field Effect Transistors: Theory, Fabrication and Characterization, Springer 2009.
Supplementary texts include: - M. Fischetti and W. G. Vandenberghe, Advanced Physics of Electron Transport in Semiconductors and Nanostructures, Springer 2016. - C. Jacoboni and P. Lugli, The Monte Carlo Method for Semiconductor Device Simulation, ser. Computational Microelectronics, Springer 1989. - D. Vasileska, S. M. Goodnick, and G. Klimeck, Computational Electronics. Semiclassical and Quantum Device Modeling and Simulation, CRC Press 2010. - Ioannis Kymissis, Organic Field Effect Transistors: Theory, Fabrication and Characterization, Springer 2009.
Slides; Dispense; Video lezioni tratte da anni precedenti;
Lecture slides; Lecture notes; Video lectures (previous years);
Modalità di esame: Prova scritta (in aula); Prova orale obbligatoria;
Exam: Written test; Compulsory oral exam;
... The exam includes a written test focused on organic semiconductors in the form of four open questions, and an oral discussion about the electronic structure and transport properties of crystalline semiconductors, based on the reports of the numerical laboratories that have to be submitted by the students during the course. The written test is closed-book (no use of any course material is allowed) and has a duration of 90 minutes; the objective of the oral test is to assess the capability of the student to explain the numerical results obtained with the empirical pseudopotential method and the analytic-band Monte Carlo code developed in the laboratories. Percentage-type breakdown of the course grades: completeness/correctness of the written test (20%), quality of the lab reports (40%), ability of the student to discuss her/his approach to the numerical laboratories during the oral discussion (40%).
Gli studenti e le studentesse con disabilità o con Disturbi Specifici di Apprendimento (DSA), oltre alla segnalazione tramite procedura informatizzata, sono invitati a comunicare anche direttamente al/la docente titolare dell'insegnamento, con un preavviso non inferiore ad una settimana dall'avvio della sessione d'esame, gli strumenti compensativi concordati con l'Unità Special Needs, al fine di permettere al/la docente la declinazione più idonea in riferimento alla specifica tipologia di esame.
Exam: Written test; Compulsory oral exam;
The exam includes a written test focused on the topics of the course: - two essay questions on scattering theory and Boltzmann transport equation - one essay question on the empirical pseudopotential method - one essay question on the introduction of quantum transport - two essay questions on organic semiconductors. A complete list of the questions will be provided to the students during the course. The written exam is a closed-book test (no use of any course material is allowed) and has a duration of 90 minutes. During the course, students are requested to submit two reports: a presentation of the results obtained in the MC laboratory, and a presentation of the results obtained in the assigned laboratory (EPM or QT). The objective of the oral test is to assess the capability of the student to explain the numerical results in the submitted presentations. Percentage-type breakdown of the course grades: - Completeness/correctness of the written test (40%) - Quality of the MC report and ability of the student to discuss her/his approach to the numerical laboratories during the oral discussion (40%) - Quality of the EPM/QT reports and ability of the student to discuss her/his approach to the numerical laboratories during the oral discussion (20%).
In addition to the message sent by the online system, students with disabilities or Specific Learning Disorders (SLD) are invited to directly inform the professor in charge of the course about the special arrangements for the exam that have been agreed with the Special Needs Unit. The professor has to be informed at least one week before the beginning of the examination session in order to provide students with the most suitable arrangements for each specific type of exam.
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