Budapest University of Technology and Economics, Faculty of Electrical Engineering and Informatics

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    Novel Technologies and Renewables

    A tantárgy neve magyarul / Name of the subject in Hungarian: Újfajta technológiák megújuló energiákkal

    Last updated: 2014. április 3.

    Budapest University of Technology and Economics
    Faculty of Electrical Engineering and Informatics
    Novel Technologies and Renewables
    Course ID Semester Assessment Credit Tantárgyfélév
    VIAUM019   2/0/1/v 4  
    3. Course coordinator and department Dr. Rakos Balázs,
    Web page of the course get.bme.hu
    4. Instructors Dr. Balázs Rakos, Associate Professor
    6. Pre-requisites
    Kötelező:
    Training.Code=("2N-MG0")
    VAGY
    Training.Code=("2N-MM0")
    VAGY
    Training.Code=("2N-MW0")
    VAGY
    Training.Code=("2N-MT0")
    VAGY
    EgyenCsoportTagja("Brazil 2015-16-1_erk")

    A fenti forma a Neptun sajátja, ezen technikai okokból nem változtattunk.

    A kötelező előtanulmányi rend az adott szak honlapján és képzési programjában található.

    7. Objectives, learning outcomes and obtained knowledge

    Demands for novel, high-performance, low energy-consuming, low-cost electronic and electromechanical devices are increasing rapidly. Novel technologies are applied and are being developed in order to fulfill these requirements. The course offers an introduction to the main trends in such contemporary technologies and devices with an emphasis on progress in micro/nanoelectronics and micro/nanoelectroechanical (MEMS/NEMS) devices. Furthermore, the students will learn about new solutions and possibilities related to renewable energy harvesting and storage.

    8. Synopsis

    1st week: Introduction to micro- and nanoelectronics (main concepts, aims, trends, advantages/disadvantages).

    2nd week: Fabrication methods in microelectronics (photolithography, etching, thin film deposition, semiconductor doping).

    3rd week: Characterization methods in microelectronics.

    4th week: Physical background and modeling of microelectronic and microelectromechanical devices.

    5th week: Novel trends and devices in microelectronics (novel sensors, transistors, photonic devices).

    6th week: Novel trends and devices in microelectronics (microelectromechanical systems).

    7th week: Fabrication methods in nanoelectronics (top-down, bottom-up approaches, electron beam lithography, nanoimprint lithography, scanning probe lithography, focused ion beam machining, atomic layer deposition, self-assembly, other nanolithography and nanomanipulation methods).

    8th week: Characterization methods in nanoelectronics (electron microscopy, atomic force microscope, scanning tunneling microscope, other scanning probes).

    9th week: Novel trends and devices in nanoelectronics (novel sensors, photonic devices, molecular electronic devices).

    10th week: Novel trends and devices in nanoelectronics (nanoelectromechanical systems).

    11th week: Utilization of renewable energy sources with the aid of micro/nanoelectronics.

    12th week: Novel microelectronics-based device concepts related to conversion of renewable energies to electricity (novel solar cell concepts, conversion of heat to electricity, energy scavenging devices, novel electric energy storage concepts).

    13th week: Novel nanoelectronics-based device concepts related to conversion of renewable energies to electricity (novel solar cell concepts, conversion of heat to electricity, energy scavenging devices, novel electric energy storage concepts).

    14th week: Summary.

    9. Method of instruction Lecture, project laboratory.
    10. Assessment

    a) in term-period

    Presentation, and submission of a written document about the results of the project work done during the in-term period. The project work is scored, which is part of the final score. The maximum achievable score is 30 points.

     

    b) in examination period

    The maximum achievable score of the exam is 70 points. The sum of the results of the exam and project work gives the final score (max. 100 pts.)

    The final marks are offered as follows:

    0-39     failed (1)

    40-55   satisfactory (2)

    56-70   average (3)

    71-85   good (4)

    86-100 excellent (5).

    12. Consultations

    By email appointments.

    13. References, textbooks and resources

    1. ecture notes.

    2. Additional literature will be announced during the first lecture.

    14. Required learning hours and assignment
    Contact hours28
    Home study for the courses18
    Laboratory project
    56
     Home study for exam
    18
     Totally120
    15. Syllabus prepared by Dr. Balázs Rakos, Associate Professor