DESCRIPTION OF THE COURSE NAME OF THE …oldweb.tu-sofia.bg/eng_new/ECTS/ectas/ectas12-13/feet/ME_EN/FETT...“Introduction to Microsystem ... 9652794, email: [email protected], Department

DESCRIPTION OF THE COURSE

NAME OF THE COURSE:

NANOMATERIALS

CODE: ММТН01 SEMESTER: 1

TYPE OF TEACHING:

LECTURES AND LABORATORY WORK

LESSONS PER

WEEK: L-2H, LW-2H

NUMBER OF

CREDITS: 6

LECTURERS:

Assoc. prof. PhD Valentine Videkov, phone 965 3101, e-mail: [email protected]; Technical University

of Sofia, Faculty of Electronics, Department "Microelectronics" and

Assist. prof. PhD Mariya Aleksandrova, phone 965 30 85, email: [email protected],

Department of Microelectronics, Faculty of Electronics, Technical University of Sofia.

Assoc. Prof. PhD Iva Betova, phone: 965 2258, e-mail: [email protected], Technical University of

Sofia, Faculty of Electronics, Department of Chemistry.

COURSE STATUS IN THE CURRICULUM: Compulsory for students of "Microtechnology and

nanoengineering”, MSc program.

AIMS AND OBJECTIVES OF THE COURSE:

The aim of the course "Nanomaterials" is to acquaint students with the current state and prospects for the

near future development of nanomaterials and nanotechnology. During the exercises they get a practical

idea of nanomaterials and methods for their identification.

DESCRIPTION OF THE COURSE: During the course students will gain theoretical knowledge of the

newest nanomaterials in electronics and practical will be acquainted with the modern methods used for

qualitative and quantitative analysis of nanomaterials.

PREREQUISITES: Basic knowledge in materials in microelectronics, physics, chemistry, measurement

electronics.

TEACHING METHODS:

The lectures are held in hall with multimedia projecting. The course management is by using a site

http://ecad.tu-sofia.bg/nanomat. We present additional materials there. Each visit of lecture brings

additional points for the final evaluation. There are additional questions for self preparing. For further

questions or clarifications students use the forum in the discipline’s web site.

METHOD OF ASSESSMENT: Written exam at the end of the first semester. The examination can be by

full questions development or test (sample questions for the test are previously provided). Can be applied

electronic forms of testing.

TEACHING LANGUAGE: Bulgarian with possibility for English teaching.

BIBLIOGRAPHY:

1. А. Попов, Наноматериали и нанотехнологии, Изд. СУ-София, 2008; 2. Г. Младенов,

Нанотехнологии и наноелектроника, Акад. издателство „Проф. Марин Дринов”, София, 2010.

mailto:[email protected]



Name of the course:

Micro- and Nanosystems Technologies

Code: МMTN02 Semester: 1

Type of teaching:

Lectures and laboratory works

Lessons per week

L-2 hours LW-2 hours

Number of credits

6

LECTURERS:

Assoc. Prof. PhD Krassimir Denishev, 9653185, еmail: [email protected],

Assist. Prof. Ph.D. Mariya Aleksandrova, phone: 9653085, email: [email protected],

Technical University of Sofia, Faculty of Electronic Engineering and Technologies (FETT),

Department of Microelectronics.

COURSE STATUS OF THE CURRICULUM:

Compulsory course for the students specialty "Microtechnologies and Nanoingeneering" MEng programme

of FETT, Faculty of Industrial Technology (FIT) and Faculty of Telecommunications (FTC) at Technical

University of Sofia.

AIMS AND OBJECTIVES OF THE COURSE

The purpose of the education on “Micro- and Nanosystem Technologies” is the students to get knowledge

on the technological processes, used for creation of structures, devices and blocks in Microelectronics,

Nanoelectronics, Micro Electro Mechanical Systems (MEMS) and Nano Electro Mechanical Systems

(NEMS). The Laboratory Works give the students knowledge on deposition and structuring of layers of

different materials, the creation of 2D and 3D configurations with high complexity, created in the volume

and on top of the substrates. The received knowledge will allow the students to know the main

technological processes of Microelectronics and Mechathronics, as well as to be able to define the

necessary processes and procedures for designing and producing of Microelectronics and Mechathronics

devices.

DESCRIPTION OF THE COURSE:

In the course, the main methods for deposition and structuring of layers of different materials, the creation

of 2D and 3D configurations with high complexity, with minimal dimensions in the ranges of micrometers

and nanometers, created in the volume and on top of the substrates, are reviewed

PREREQUISITES:

Physics, Chemistry, Microelectronics, Material Science, Nanomaterials.

TEACHING METHODS:

The lectures are conducted with the aim of visual samples. Laboratory works are carried out by

“Laboratory Work Guide” and protocols. Optional - choosing and preparation of Course project.

METHOD OF ASSESSMENT:

Written exam at the end of second semester.

INSTRUCTION LANGUAGE: Bulgarian (English is possible)

BIBLIOGRAPHY: 1. “Introduction to Microsystem Technology : A Guide for Students” by Gerald Gerlach, Wolfram Dotzel, Dorte Muller, John Wiley & Sons Inc, ISBN 0470058617, New York, 2008. 2. “Mechatronics: An Introduction” by Robert H. Bishop, CRC Pr I Llc, ISBN 0849363586, New York,

2005.




Name of the course:

Fundamental principles and

application of micro and

nanosystems

Code: MMTN03 Semester: 1

Type of teaching:

Lectures and laboratory work

Lessons per week


Number of credits

6

LECTURERS:

Prof. Ph. D. Todor Todorov, phone: 9652794, email: [email protected], Department of Theory of

Mechanisms and machines;

Prof. Ph. D. Georgy Todorov, phone: 9652574, еmail: [email protected];

Technical University of Sofia, Faculty of Industrial Technology.

COURSE STATUS IN THE CURRICULUM:

Compulsory subject for the students of specialty "Microtechnology and nanoengineering" MSc

program of FIT.


The aim of the education of the subject “Fundamental principles and application of micro and

nanosystems” is students to acquire knowledge for the basic operational principles, design and

application of micro and nanosystems. The so obtained knowledge and abilities allow the students

to solve problems involving the design and application of micro and nanosystems.


The fundamental transducing principles and the various applications of the micro and nanosystems are

considered in the course as it is accented on the specific micro and nanoscale features of these systems.

The students learn modern micro and nanosystems which are applied in miniaturized portable

devices, sensors and actuators with diverse application.

PREREQUISITES:

Knowledge of mechanics, strength of materials, theory of elasticity, electrical engineering,

electronics and material science are required.

TEACHING METHODS:

The lectures are conducted by the aim of samples and video projector. Laboratory works are

implemented by the help of modern evaluation setups. There is optional course project in this

subject.

METHOD OF ASSESSMENT: Written exam in the end of 1th semester.

INSTRUCTION LANGUAGE: Bulgarian. 1. BIBLIOGRAPHY: Todorov T., MEMS modeling and application, Part 1: Basic transducer

principles, TU-Sofia, 2013, 211 p. (in Bulgarian).

2. Todorov G., Todorov T., Manual for laboratory work of technology and design of MEMS, TU–

Sofia, 2001, 81 p. (in Bulgarian).

3. Gianchandani Y. B., Tabata О, Zappe H, Comprehensive Microsystems, Elsevier, 2007, p.1805

4. Nen T. R., Uusitalo M., A.,Ikkala O., Inen A. R., Nanotechnologies for Future Mobile Devices,

Cambridge University press, 2010.


Name of the course:

Nano communication devices and

networks

Code: МMTN04

Semester: 1

Type of teaching:

Lectures, laboratory work and Course task

Lessons per week


Number of credits

6

LECTURER:

Associate professor Galia Marinova, phone: 9653188, email: [email protected]

Technical University of Sofia, Telecommunications Faculty, Department of Technologies and

Management of Telecommunication Systems


Compulsory for the students in specialty "Microtechnologies and Nano Engineering" MEng

programme of FETT.


The objective of the course “NCDN” is students to get knowledge of the advanced approaches for

communication devices realization through nano technologies and with nano communication

networks as the next step in communication technologies. Fundamental requirements for

communication networks are predefined, as well as design algorithms, architecture, topology,

connectivity, routing, reliability and security of nano networks.


The course considers topics as electromagnetic nano networks, neural networks for nano

communications, molecular and bacterial communications. Examples of nano communication

devices are given as nano tube radio, nano sensor node, antennas from graphene or carbon,

Terahertz channel, as well as piezoelectric nano connections for energy harvesting. Other topics are

protocols for nano communication devices, nano communication networks security. modeling and

simulation of nano communication devices and networks with the software tools MATLAB,

COMSOL Multiphysics, CST Microwave Studio, QCAD Design, etc.

PREREQUISITES:

Communication networks.

TEACHING METHODS:

The lectures are e-presentations and video clips assisted. Laboratory works are carried out through

“laboratory work guide” and protocols. Course tasks are individual for each student.


Written exam in the end of 1st semester

INSTRUCTION LANGUAGE: Bulgarian (English is possible also) BIBLIOGRAPHY:

1. D. Molchanov, Lectures ELT-53406, Special course on networking, Tampere University of Technology. 2013,

http://www.cs.tut.fi/kurssit/ELT-53406/

2. F. Dressler, F. Karglb, Towards Security in Nano-communication: Challenges and Opportunities, Elsevier Nano

Communication Networks 3(3) (2012) 151-160.

3. I. F. Akyildiz, F, Brunetti, C, Blazquez , Nanonetworks: A new communication paradigm, Computer Networks 52

(2008) pp.2260–2279

4. M. S. Islam, Logeeswaran VJ, Nanoscale Materials and Devices for Future Communication Networks, IEEE

Communications Magazine, June 2010, pp.112-120

http://www.cs.tut.fi/kurssit/ELT-53406/


Name of the course:

Project Management

Code: MMTN 05 Semester: I

Type of teaching: Lectures

and Seminary Course

work

Lessons per week:

L – 2 hours; SW – 2 hour

Number of credits: 6

LECTURER:

Prof. DSc. Ph.D. Eng. Nikolai Petrov Anguelov (MTF) – tel.: 359 2 965 3669,

email: [email protected] or with private site http://nangelov.wix.com/nikiangelov , Technical

University of Sofia.


Mandatory training course for students in Electronics Techniques and Technology Faculty, Machin-

Technological Faculty and Telecommunication Faculty of TU-Sofia, degree of "magister".


At the end of the course " Project Management”, students can submit financial projects to obtain funds

from various financing programs, funds and foundations for the realization of their management

projects.

DESCRIPTION OF THE COURSE: In the course of lectures and seminars to discuss issues relating to the formulation of purpose and

determination of the required activities for the project, timetable for their implementation, financial

sources, the team writing the project and the conclusion of the contract approaches the very project

management achievement of the required quality, prevention of risk, audit, compilation of the report and

its defense.

PREREQUISITES: Basic knowledge of macroeconomics, mathematical analysis, mathematical statistics, theory of quality,

the theory of risk, and others.

TEACHING METHODS:

Slide-show lectures realize with the PowerPoint to Microsoft. Seminars include completing pre-

circulated and justified advanced protocols and writing a project on-line ore papers in selected student

financial program and fund.

METHOD OF ASSESSMENT: Continuous assessment based on the development of protocols in seminars (50 points), filling in the

blanks for the project (30 points) and discussion during lectures (20 points).

INSTRUCTION LANGUAGE: Bulgarian or English.

BIBLIOGRAPHY: Angelov N.P., N.V.Koleva, European programs and projects, Publishing of Technical University, Sofia. 2010. (in Bulgarian)

Angelov N.P., N.V.Koleva, Training aids of European programs and projects, Publishing of Technical University, Sofia. 2011. (in Bulgarian)

Andreev, O. D., Project Management, Publishing "Softtreyd" 2006. (in Bulgarian)

Koleva, NV, N.P.Angelov, Textbooks protocols in EU programs and projects, Publishing of Technical

University, 2013. (in Bulgarian)

Balashov, AI, E.M.Rogova, M.V.Tihonova, E.A.Tkachenko, Projects Management, Moscow, "Juraj"

Publish., 2013. (textbook, 383 p., in Russian) http://www.hse.ru/pubs/lib/data/access/ram/ticket/23/1422718127439792667.pdf

British Standard BS 6079-1:2000. Project management - Part 1: Guide to Project Management.

Zarenkov, V.A., Project Management, Moscow-Petersburg, "ACB" Publishing, 2010. (textbook, 312 p.

in Russian)


Name of the course:

Mathematical Methods for

Data Processing

Code: MMTN06 Semester: 2

Type of teaching:

Lectures and seminars

Lessons per week:

L – 1 hours; S – 1 hours


LECTURER:

Assoc. Prof. Ph.D. George Venkov (FAMI), tel: 02 965 3357, e-mail: [email protected],

Technical University of Sofia


Compulsory course in the Master’s degree, specialty “Microtechnologies and nanoengineering” in

the Faculty of Electronic Engineering and Technology at Technical University of Sofia.


The course aims to introduce the main algorithms employed for performing useful operations on

signals, in either discrete or continuous time.


The main topics concern: basic Functional analysis; general theory of Fourier series; Fourier

transform; convolution operator; discrete sequences and systems; introduction to signal processing;

linear time-invariant systems; models for linear systems and signals; δ-function and step function;

discrete convolution and correlation operators; time and frequency domains; discrete Fourier

transform; circular convolution theorem and cross-correlation theorem.

PREREQUISITES:

Linear algebra, Mathematical analysis, Signals and systems.

TEACHING METHODS:

Lectures and seminars


Continuous assessment and coursework at the end of the semester.

INSTRUCTION LANGUAGE:Bulgarian.

BIBLIOGRAPHY:

1. Todd K. Moon, Mathematical methods and algorithms for signal processing, Prentice-Hall,

New Jersey, 2000.

2. Richard G. Lyons, Understanding digital signal processing, Prentice-Hall, New Jersey,

2001.

3. David Brandwood, Fourier transforms in radar and signal processing, Artech House, Boston,

2003.

Борислав Доневски, Математичски методи за цифрова обработка, Изд. Технически

Университет, София, 2003.



Name of the course:

CAD software for Micro- and

Nanodevices

Code: МMTN07.1 Semester: 2

Type of teaching:

Lectures, laboratory exercises and

seminars

Lessons per week

L-1 hours LE-2 hours,

S - 1 hour

Number of credits

5

LECTURER:

Assoc. Prof. Dr. Rossen Radonov, phone: 9653115, email: [email protected], Technical

University of Sofia, Faculty of Electronic Engineering and Technologies,Department of

Microelectronics


Optional for the students specialty "Microtechnology and nanoengineering" MEng programme of

FETT.


The purpose of CAD software for Micro- and Nanodevices is to acquaint students with CAD

systems in microelectronics that were required as a global industry standard.


The course covers mainly two systems: complete design of analog, digital and digital-to-analog

integrated circuits and system design of digital integrated circuits by description by high-level

language to the realization of the level layout. For each system are considered the main stages of the

design: the introduction of the project, simulation and debugging, optimization, design verification,

generation of output file.

PREREQUISITES:

Basic knowledge in the field of semiconductors, theory of electronic circuits, analog and digital

electronics, design of electronic circuits and others.

TEACHING METHODS:

Lectures using visual aids. Laboratory work performed under lab. guidance and protocols produced

by the students and checked by the teacher. Seminar exercise, analyzing different types of project

the problems of integrated circuits. Optionally, students develop a project.


Written exam in the end of 2нд

semester

INSTRUCTION LANGUAGE: Bulgarian BIBLIOGRAPHY:

1. Hristov M., R. Radonov, B. Donchev, CAD Systems in Microelectronics (in Bulgarian),

Technical University of Sofia, Sofia, 2004, ISBN 954-438-410-3.

2. Hristov M., R. Radonov, B. Donchev, K. Mihaylova, D. Pukneva, O. Antonova, D.

Arabadzhiev, O. Manchev, I. Partenov, Manual for Practical Exercises in CAD Systems in

Microelectronics (in Bulgarian), Technical University of Sofia, Sofia, 2004, ISBN 954-438-

411-1.

3. Nancheva-Philippova, K., M. Hristov, V. Hristov, I. Panayotov, (v)HDL for analyses of

electronic hardware (in Bulgarian), Sofia, 2004.


Name of the course:

Quantum physics

Code: MMTN07.2 Semester: 2

Type of teaching:

Lectures, seminar and laboratory

works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Georgi Angelov (FEET), phone 9653115, email: [email protected]



Elective for students in "Microtechnology and nanoengineering" for the degree "Master".


The aim of the course "Quantum Physics" is to familiarize students with basic phenomena,

processes and theory of quantum mechanics and its applications in the modern nanotechnology. The

knowledge and skills will allow them to gain knowledge about the applications of quantum

phenomena and effects in electronics.


Students study about the basic aspects of quantum physics: Introduction to quantum physics - a

historical aspects; Dimensional quantum mechanics - wave mechanics, potential barriers-,

function; Operator methods in quantum mechanics; Multidimensional quantum mechanics - angular

momentum, central potential; Motion in a magnetic field; Variational methods for computing

stationary states - method of Wentzel-Kramers-Brillouin (WKB); Identical particles, quantum

statistics; Structure of atoms; Field theory - photons, phonons, quantum electrodynamics; The time-

dependent perturbation theory; Radiation transitions; Theory of scattering;

PREREQUISITES:

Basic knowledge in physics and mathematics are needed.

TEACHING METHODS:

Lectures using visual aids. Seminars conducted based on materials given by assistants, during

which students have the opportunity to learn about the studied phenomena and theory.


Exam at the end of the semester.

TEACHING LANGUAGE:

Bulgarian

BIBLIOGRAPHY:

1. М. Д. Матеев и А. Д. Донков, „Квантова механика“, Издателство на СУ, София, 2010.

2. Roger G. Newton, „Quantum Physics. A Text for Graduate Students”, Springer-Verlag, New

York, 2002.


Name of the course:

Reliability of nanoscale circuits and

systems


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Anna Andonova, phone 965 3263, e-mail: [email protected]; Technical

University of Sofia, Faculty of Electronics, Department "Microelectronics.




Mandatory elective course from the master program specialization "Testing of micro-and

nanosystems" specialty "Microtechnology and nanoengineering" for Master of Scinse degree.


The aim of the course is to teach students of design, evaluation and implementation of schemes and

fail-safe systems.


At the end of the course students will: provide solutions and guidelines for dealing with problems of

reliability of the scheme, systems, architectures and methodological level, designing reliable

systems from unreliable components; Fault-tolerant design architecture modeling failures, assess

reliability; know different techniques for fault tolerance and to evaluate their suitability for

nanoscale circuits and systems; selecting a mix of two or more specific designs, according to its use

and purpose.

PREREQUISITES:

Basic knowledge in technology for micro-and nanosystems, nanomaterials, basic principles and

application of micro-and nanosystems, nanocommunicational devices and networks, are necessary.

TEACHING METHODS:

Lectures are held in the hall with multimedia. The laboratory group perform a topic under the

guidance of the supervisior.


Exam at the end of the semester.

TEACHING LANGUAGE:

Bulgarian

BIBLIOGRAPHY:

1. M. Stanisavljevic, • A. Schmid, •Y. Leblebici, Reliability of Nanoscale Circuits and Systems.

Methodologies and Circuit Architectures, Springer, 2011.

2. Nanoelectronics and information technologies, Reiner Waser (Ed.), WILEY-VCH, 2012.


Name of the course: 3D modelling and

simulation of micro&nano systems

Number: MMTN 08.1 Semester: II

Type of teaching: Lectures (L), Seminars(S)

and Labs (Lab.)

Lessons per week: L- 1

h; S-l h, Lab- 2 h


^

LECTURER: Prof. Ph.D. Georgi D. Todorov (TMMM, FIT), tel. 9653323, e-mail: gdt@tu-

sofia.bg. Technical University of Sofia

COURSE STATUS IN THE CURRICULUM: Optional for the students of specialty "Micro

Technologies& Nano Engineering" of the Faculty of Electronics and Faculty of Industrial

Technology, Master Engineering degree.

AIMS AND OBJECTIVES OF THE COURSE; At the end of the course the students are

expected to be able to apply 3D System in Micro Systems, especially in 3D Design and Simulation.

To have advanced knowledge and practical skills to design and simulate for subsequent training in

specialized courses in this area and following design projects.


The course is focused to increasing and enlarging of student's practical skills in field of

effective application of 3D intelligence modelers for design and optimization of micro

systems and behavior simulation . In course are used CAD/CAE Systems; Finite Elements

Method software for design calculations and analyses and Software for process and system

behavior simulation.

PREREQUISITES:

Necessary basic knowledge in computers and foregoing courses in Mechanical Engineering,

CAD/CAE Systems

TEACHING METHODS: Lectures are read using slides. Also there is a corresponding textbook in script format. The

laboratory work is fully computer-aided with a corresponding to the given problem written

manuals. Each student follows common project for entire semester, separated to " step by

step" approach. Each step have to be done during the laboratory class in same order.

METHODS OF ASSESSMENT;

The acquired knowledge during the laboratory work is assessed by the final project

presentation. On the end of the second semester - a written exam.

INSTRUCTION LANGUAGE: Bulgarian

BIBLIOGRAPHY: 1. ТОДОРОВ, Г СКРИПТ КУРС ЛЕКЦИИ ПО КПМПС

2. ТОДОРОВ, Г., Г. НИКОЛЧЕВА. КОМПЮТЪРНО ПРОЕКТИРАНЕ НА СЛОЖНИ

ФОРМООБРАЗУВАЩИ

ПОВЪРХНИНИ(КАРШ TOOLING), Изд.ТУ СОФИЯ, СОФИЯ 2011, ISBN 978-954-438-915-4, 330

СТР;

3. PHAM, D.T., S.S. DIMOV. RAPID MANUFACTURING. SPRINGER-VERLAG LONDON LIMITED, 2001.

4. Тодоров, Н., Д. Чакърски. Автоматизация на проектирането в машиностроенето. С,

Техника, 1994,

5. Kunwoo, lee,-PRINCIPLES OF CAD/CAM/CAE Systems, Addison Wesley Publishers Ltd,

New York,2009


Name of the course:

Surface nanochemistry


Type of teaching:

Lectures, laboratory works and tutorials

Lessons per week

L-1 hour, LW-2 hours T-1hour

Number of credits:

5

LECTURER:

Assoc. Prof. Ph.D. Boriana Rangelova Tzaneva, e-mail: [email protected],

Assist. Prof. Ph.D. Mladenka Hristova Loukaycheva, е-mail: [email protected],

Technical University of Sofia, Faculty of Electronic Engineering and Technologies,

Department of Chemistry, phone: 9653663


Optional for the students specialty "Microtechnology and nanoengineering" MEng programme of the

Faculty of Electronic Engineering and Technologies.


The objective of the course “Surface nanochemistry” is that students receive knowledge of the general

processes and phenomenon taking place on different surfaces and phase interfaces. During the

laboratory works students acquire skills to characterize there parameters. The gain knowledge and

abilities will allow the students to solve important practical tasks in the field of material science.


Concepts as surface tension, wetting, capillarity, adsorption and orientation of interface are introduced.

The thermodynamic criterions for spontaneous or forced occurrence of chemical reactions during

monomolecular and thin layers formation as well as some of the electrokinetic phenomenon as

electrophoresis, electroosmosis and electrocapillarity connected with interface surface charge are

discussed. Special attention is paid of processes of nucleation, growth and agglutination of clusters

leading to different nanostructures formation. All processes and phenomenon discussed above are in the

base of self structuring in nanolevel, nanomatrix and nanopatterns formation.

PREREQUISITES:

Physics, Chemistry, Materials science, Nanomaterials

TEACHING METHODS:

Lectures delivered by using visual aids. Laboratory works are carried under instructions of assistant

professor according “laboratory work guide”, students prepare reports. Optional choose and elaboration

of course project. Tutorials are dedicated to preliminary theoretical preparation for laboratory works and

deepening in material from lectures.


Current assessment during laboratory works and tutorials (40 %) and written examination (2 hours) in

the end of 2th

semester (60 %).

INSTRUCTION LANGUAGE: Bulgarian (English is also possible)

BIBLIOGRAPHY:

1. H.Y. Erbil, Surface Chemistry of Solid and Liquid Interfaces, Blackwell Publishing, ISBN-10: 1-4051-

1968-3, 2006

2. D. J. Shaw, Introduction to Colloidal and Surface Chemistry, Elsevier Science, 2003.

3. A.W. Adamson, Physical Chemistry of Surfaces, Wiley, ISBN 0-471-14873-3, 1997.


Name of the course:

Micromechanics and Nanotribology


Type of teaching:

Lectures, seminar and laboratory work

Lessons per week

L-2 hours, SW–1 hours

LW-2 hours

Number of credits:

5

LECTURER:

Associated Prof. Ph. D. Mara Kandeva-Ivanova, MTF, tel.: 965 2643,

e-mail: [email protected], Dep. “Theory of Mechanisms and Machines”

Faculty of Industrial Technology, Technical University of Sofia


Eligible course for full-time students of the specialty „Mictotechnology and

NanoEngineering” pursuing the educational and qualification degree “Master of Science”


The aim of the course "micromechanics and nanotribologiya" is to contribute to the deepening

and broadening of knowledge in the field of micromechanical motion and characteristics, the

nature and characteristics of the tribological processes-friction, wear, lubrication of macro-,

micro-and nano-scale the direction of their effective use in the design, operation and

development of microtechnology and MEMS.


Considered free, forced, damping vibrations and strain-stress state of the bearing elements in

micromechanical systems. Study the mechanisms, effects, characteristics and modeling of

tribological processes - friction, wear and lubrication of macro, micro and nanoscale.

Laboratory work related to the study of methods and techniques for measuring and testing of

mechanical and tribological parameters in micromechanical systems

PREREQUISITES:

mechanics, physics, mathematics, materials science, chemistry. TEACHING METHODS:

The lectures are conducted with the aim of samples. Laboratory exercises are performed with

micro-mechanical equipment, macro, micro and nanotribological testers - UNMT with AFM

(Ambios Technology), profilometer 3G, profilometer PRO500 3D, TABER ABRASER,

electronic scales, Scanning electron microscope EVO MA10, optical microscope and others.

Each student will develop an independent project.


Written exam


BIBLIOGRAPHY: 1. V. Timofeev, Tehnicheskaya micro mechanics, Moscow, binomial, 2011.

2. Manolov N., M. Kandeva, General Tribology, "St. Ivan Rilski ", Sofia, 20041. Rassovska M.M.,

3.Bhushan, B., Sr. Sundararajian, Micro/Nanotribology , Boca Raton:CRC Press LLC, 1999

4.Rymuza Z., Tribology of Miniature Systems, ELSEVER, 1989

5.Jost, H.P., The Presidential address, World Tribology Congress 2009, Kyoto, Japan, 06-11.09.2009.

COURSE DESCRIPTION

NAME OF THE COURSE:

Micromechanical piezoelectric systems and

sensors for frequency control

CODE: MMTN02 SEMSTER: 1

Type of teaching:

Lectures, seminar and laboratory works

LESSONS PER

WEEK:

L-1 h,SW-1 h, LW-2 h

NUMBER OF

CREDITS: 5

LECTURERS:

1. Prof. Ph. D. Todor Todorov, phone: 9652794, email: [email protected], Department of Theory of

Mechanisms and machines;

2. Assoc. Prof. Ph. D Ventsislav Yantchev, Guest lecturer fro Department of Solid State Electronics,

Uppsala University, Sweden, contact information: Uppsala University, Dept. Solid State Electronics, Box

534, 75121 Uppsala, Sweden, E-mail: [email protected]

3. Assistant, PhD Elitsa Gieva, phone: 029653115, e-mail: [email protected], Department of

Microelectronics, FETT, Technical University of Sofia.


Optional course of the Master in " Microtechnology and nanoengineering" , MSc program.


The course complements the knowledge acquired in the course "Basic principles and application of

MEMS". Here, the specific frequency is regarded piezoelectric micro - electromechanical systems with a

commercial application in the field of sensors, and optical communications. The laboratory exercises are

carried out practical experiments to confirm the theory and identify opportunities for their application. The

knowledge and skills will enable students to solve problems concerning the design and application of

micro and nanosystems.


The main topic of the lecture is microwave mechanics and its application in treatment of wave signals.

Viewed is the use of piezoelectric MEMS management of optical signals . Explained the principles of

MEMS -based passive RFID applications in tracking goods and those who identify wireless sensors for

industrial needs. Discussed are the current challenges to the MEMS industry related to the possibility of

their technological integration with electronic integrated circuits and the creation of new features and

applications.

PREREQUISITES:

The course requires students basic training in physics and mathematics. Preliminary expertise in MEMS

would be beneficial but not mandatory .

TEACHING METHODS:

Lectures by using visual aids. Laboratory work conducted by modern laboratory stands . Optionally,

students develop a project .

METHOD OF ASSESSMENT: The final assessment of the course is calculated by adding together the

points : exam ( with a weight of 0.8 ) and evaluation laboratories ( by a factor of 0.2) . Thus evaluated as

received basic knowledge and theoretical and experimental skills to apply in practice in research and

development of MEMS. Examination paper consists of questions with multiple choice answers and

problem solving questions and tasks cover all aspects of the syllabus . Examination work aims to establish

the level of basic knowledge of the student, as well as its ability to give meaning to what they have learned

and apply it to solve specific tasks.


TEACHING LANGUAGE: Bulgarian

BIBLIOGRAPHY:

1. Surface Acoustic Wave Devices in Telecommunications, Ken-ya Hashimoto, Springer

2. RF Bulk Acoustic Wave Filters for Communications, Ken-ya Hashimoto, Artech. House

3. G. Piazza et. al., “Piezoelectric aluminum nitride thin films for microelectromechanical systems”, MRS

Bulettin, Vol 37, pp. 1051-1061 , November 2012

4. Practical MEMS, Ville Kaajakari, Small Gear Publishing

5. V. Plessky, L. Reindl, “Review on SAW RFID Tags”, IEEE TUFFC 57(3), pp. 654-668.

6. V. Laude et. al., An introduction to phononic crystals, http://www.femto-st.fr/en/Popularization/An-

introduction-to-phononic-crystals

7. M. Gedge and M. Hill, “Acoustofluidics 17: Theory and applications of surface acoustic wave devices

for particle manipulation”, Lab Chip, 2012, 12, 2998–3007

8. Y. Zhang , Y. Liu, Z. Wang, “Fundamental Theory of Piezotronics”, 2011 Adv. Mat., pp. 1-10

9. Introduction to COMSOL Multiphysics, 1998-2012 COMSOL


Name of the course:

Nanotechnologies for Еnvironmental

Еffectiveness in Telecommunications


Type of teaching:

Lectures, laboratory and seminary work

Lessons per week

L-1 hour LW-2 hours

SW-1 hour

Number of credits

5

LECTURER:

Assoc. Prof. Ph. D. Boyanka Nikolova, phone: 965 3135, еmail: [email protected]; Technical

University of Sofia, Faculty of Telecommunications, Department of Technology and Management of

Communication Systems

Assoc. Prof. Ph. D. Valentin Videkov, phone: 9653101, email: [email protected]; Technical

University of Sofia, Faculty of Electronic Engineering and Technologies, Department of

Microelectronics


Optional for the students in master’s degree in "Microtechnology and nanoinzhenering".


The aim of the course is to provide students with a general overview of base methods for

environmental effectiveness in telecommunications through the use of nanotechnologies and

nanomaterials.


The main topics concern: Sources of electromagnetic radiation (EMR); Mechanisms of effects of

EMR on humans; Standards governing the safety of EMR; Methods for EMR protection; Shielding

of electromagnetic fields; Nanomaterials (nanostructured and nanodispersed) for the design and

implementation of compact electromagnetic screens for wide frequency range; Methods and tools

for reducing energy intensity and dimensions of telecommunications equipment; Utilization of

telecommunications equipment.

PREREQUISITES: The course is based on knowledge in the fields of Chemistry, Physics,

Material Sciences, Nanomaterials

TEACHING METHODS:

Lectures held by the lecturer and aided by means of auxiliary materials. Laboratory and seminary

exercises are performed under the guidance of an assistant professor.

METHOD OF ASSESSMENT: Written exam in the end of 2 semester

INSTRUCTION LANGUAGE: Bulgarian BIBLIOGRAPHY:

1. Borbotko Т. V., N. V. Kolbun, L. М. Linkov "Anthropogenic sources of electromagnetic

radiation. Human safety", Minsk 2008.

2. V. А. Bogush, Т. V. Borbotko , А. V. Gusinskii, L. М. Linkov, А. А. Tamelo "Electromagnetic

radiation. Methods and Remedies", Minsk 2003.

3. Anwar, Sohail (Editor), M. Yasin Akhtar Raja (Editor), Salahuddin Qazi (Editor), Mohammad

Ilyas (Editor), “Nanotechnology for Telecommunications”, CSC Press, 2010.


Name of the course: Metrology and

mechanical tests of micro and

nanosystems


Type of teaching: Lectures, seminars and

laboratory work Lessons per week L-l

hours, S-l,LW-2 hours Number of credits 5

LECTURERS: Assoc. prof. Vasil Bogev, Department of Precise techniques and apparatus, phone: 9653239, email:

bogev@tu-sofia, prof. Ph. D. Todor Todorov, phone: 02/9652794, email: [email protected], Department

of Theory of Mechanisms and machines. COURSE STATUS IN THE CURRICULUM: Metrology and mechanical tests of micro and nanosystems is optional course of Master course in

"Microtechnology and nanoengineering", AIMS AND OBJECTIVES OF THE COURSE The aim of the course is learning and applying of methods and technical tools for measuring in the field

of micro and nanotechnologies, and to model and test the operational functions and precision of

measuring devices. DESCRIPTION OF THE COURSE: The main topic lectures include: Fundamentals of metrology and nanometrology, methods and tools for

nanometrical measurements, unity of nanometric measurments and quantum metrology. Laboratory

workshops embrace mechanical characteristic test of measuring devices for micro and nano objects,

determination of metrological characteristics of data acquisition systems for micro and nanosystems,

metric evaluation of micro accelerometers, investigation of thermo micro and nano effects, indirect and

predictive methods for investigation of micro and nanosystems. The tutorials involve metric chains in

micro and nanosystems, determining the influence of geometry and mutual position errors and scaling

factor method of measurement. PREREQUISITES: Knowledge of Physics, Engineering metrology Signal Theory and Sensors are

required. TEACHING METHODS: Lectures are held using by visual and virtual technique. Laboratory

exercises are conducted through modern laboratory evaluation setups. METHOD OF ASSESSMENT: Exam at the end of the second semester. The final grade is calculated as sum of 70% of exam grade and 30% of laboratory mark. INSTRUCTION LANGUAGE: Bulgarian BIBLIOGRAPHY: l.Radev H.,(editor), Metrology and measurement techniques. Vol. 3. Softreid, 2012. 2. Dixler К. Е, Engines of creation 2.0. The comong era of nanotechnology, Doubledayv, 20th

aniversary edition. 2007. 3. Jackson M. J., Micro and nanomanufacturing, Springer Science+Business Media, LLC, 2007. 4. Benjamin Fry К. К., Nanotechnology-Enabled Sensors, Springer Science+Business Media, LLC,

2008.


Name of the course:

Modeling and control of thermal

effects in microsystems

Code: MMTN 10.1 Semester: 2

Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):




This is an optional course of specialty "Microtechnology and nanoengineering" for Master of Scinse

degree.


The aim of the course is to provide students with knowledge of the fundamental problems of heat

transfer, thermal modeling in the design to ensure reliable performance and affordable price of

microsystems. It gradually examines the issues at the level of materials, components, modules and

systems.


At the end of the course students will: develop skills to assess the influence of external heat and

power dissipation in the system, and knowledge of using thermal analysis and simulation tool for

the evaluation and management of the heat distribution in the design; can assess the impact of the

size of nanomaterials, methods of calculation, thermal routes, the use of software for modeling and

simulation of components, heat removal, application of thermal management; knows the need for

thermal management, heat, thermal design, mechanisms and modes of heat transfer and thermal

properties of materials.

PREREQUISITES:



TEACHING METHODS:


guidance of the supervisior.

METHOD OF ASSESSMENT: Current estimation

TEACHING LANGUAGE:

Bulgarian

BIBLIOGRAPHY:





Name of the course:

Microelectronics for Information and

Communication Technologies


Type of teaching:

Lectures, seminars and laboratory

work

Lessons per week

L-1 hour, S-1 hour

LW-2 hours

Number of credits

5

LECTURER:

Prof. Ph.D. Slavka Tzanova, phone: 9652589, email: [email protected], Technical

University of Sofia, Faculty of Electronic Engineering and Technologies, Department of

Microelectronics


Elective for the students specialty "Microtechnology and nanoengineering" MSc programme of

FETT.


This course is aimed at providing knowledge and skills in the fundamental micro- and

nanoelectronics applications for information and communication technologies (ICT). At the end of

the course the students will know the functioning principles, main characteristics and parameters,

classification and peculiarities of processors, memories, interfaces used in ICT, and they will be

able to design parts of ICT systems, applying their knowledge on the fundamentals of submicron

technology.


The course treats the functioning principles, the classification and the construction of micro- and

nanoelectronic devices and systems for ICT. The emphasis is on the latest developments and trends

in the field of digital ICs fabricated in sub-micron technologies. Furthermore, separate specialized

modules cover the principles of operation and design of computer and smartphone screens,

technological foundations of OLED displays. They are all supported by examples and demos.

PREREQUISITES:

Microelectronics, Fundamentals of computer science

TEACHING METHODS:

Lectures through multimedia presentations including animations and videos. The students work in

groups of two or three on one a topic under the guidance of an assistant. Assistant introduces the

topic of the practical work, the methods, equipment, software and defines the tasks to be performed.


Written exam in the end of 2nd

semester

INSTRUCTION LANGUAGE: Bulgarian (English is possible also) BIBLIOGRAPHY:

1. Таков Т., Цанова С., Ангелов Г., Микроелектронна схемотехника, Технически

университет-София, ISBN 978-954-438-867-6, 2010.

2. Zhang, G. Q., Roosmalen, A, More than Moore. Creating High Value Micro/

Nanoelectronics Systems, ISBN 978-0-387-75593-9, 2009

3. Hübner, M., Becker, J., Multiprocessor System-on-Chip, Hardware Design and Tool

Integration, ISBN 978-1-4419-6460-1, 2011.



Name of the course:

Thin film electronics


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Krassimir Denishev, phone 965 31 85, e-mail: khd@ tu-sofia.bg; Technical





“Thin film electronics” is optional course in specialty "Microtechnology and nanoengineering" for

Master of Scinse degree.


The aim of the course is to give knowledge to the students about the properties and application of

the most advanced devices in the field of microelectronics, designed as a organic and inorganic

coatings with nanoscale thickness on solid or flexible substrate.


There will be reviewed and studied practically thin-film technologies for fabrication of passive

components in microelectronic circuits; Thin-film transistors (TFT); Thin film optical components

and thin-film optoelectronic devices (LEDs and photovoltaics); Modern displays for smartphones

and e-readers. micro displays; Thin-film batteries and other microelectronic alternative sources of

energy; Thin-film sensor elements. Applications in medicine and for control of environmental

parameters.

PREREQUISITES:

Knowledge in material science, nanomaterials, physics, nanochemistry surface technology for

micro-and nanosystems is necessary.

TEACHING METHODS:

Lectures are held in hall with multimedia. The seminars are related to the laboratory works’ topics.

The laboratory group conduct experimental topic under the guidance of assistant.


Assessment (current control) at the end of the second semester, which consists of two components:

assessment of laboratory and seminars (which is the average of the protocols and homework) +

scores from 2 tests conducted in the middle of the semester and at the end of the semester, covering

material from lectures, seminars and laboratory works.

TEACHING LANGUAGE: Bulgarian (with possibility for English teaching).

BIBLIOGRAPHY:





Name of the course:

Electrometric in nanoelectronics


Type of teaching:

Lectures, seminars and laboratory

works

Lessons per week:

L – 1h; S-1 h;

LW – 1 hours


LECTURER:

Assoc. Prof. Ph.D. Dimitar Todorov, Department of Electronics, phone: 9653281,

еmail:[email protected]


Elective for the students’ specialty “Microtechnologies and nanoengineering” at the Faculty of

Electronic Technique and Technologies in TU-Sofia, for the educational degree “MSc”.

AIMS AND OBJECTIVES OF THE COURSE: The course electrometric measurements in nanoelectronics is to acquaint students with the

possibilities, techniques and technologies of electrometrically measuring instruments and systems

used in carrying out the measuring process on nanostructures .

DESCRIPTION OF THE COURSE: The main issues arising in the implementation of structures,

measuring methods and approaches used in their solution and the basic rules when constructing

highly sensitive measurement circuits. From the metrological point of view special attention is put on

calibration, self-calibration, as well as diagnostic procedures providing metrological performance

with guaranteed accuracy. Specific developments and applications of electrometric measurement

converters, devices and systems and their application in nanotechnology are discussed.

PREREQUISITES: Technologies for Micro and Nanosystems, Nanomaterials, Theoretical Electrical Engineering,

Electrical Measurements in electronics, signals and systems, Computer systems and data

transmission.

TEACHING METHODS: Lectures are conducted in the hall with multimedia projector. The

laboratory group performs a topic under the guidance of the assistant. Seminars are carried on the

theme. Further tasks for a topic to prepare a paper which is transmitted to the completion of the

course.

METHOD OF ASSESSMENT: Current assessment, which consists of two components:

assessment of laboratory exercises with a weight of 0.4 and evaluation of test with a weighting of

0.6.


BIBLIOGRAPHY:

1. Keithley, Low Level Measurements Handbook: Precision DC Current, Voltage, and Resistance

Measurements (7th edition: 2014)

2. Nianxiong Nick Tan, Zhihua Wang Dongmei Li “Ultra-Low Power Integrated Circuit Design”;

ISBN: 9781441999733; Springer 2013.



Name of the course:

Nano-and bioelectronics


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):




Elective for students in "Microtechnology and nanoengineering" for the academic degree "Master".


The course "Nano and bioelectronics" aims is to familiarize students with the basic phenomena,

processes, technologies and materials in nanoelectronics and bioelectronics. The knowledge and

skills will allow them to gain experience on the applications of bioelectronic devices.


Students study relevant aspects of physics, biology, chemistry, materials science, micro-and

nanotechnology related to modern devices based on molecular electronics and bioelectronics.

PREREQUISITES:

Basic knowledge in physics, biology, chemistry, microelectronics, materials.

TEACHING METHODS:

Lectures using visual aids. Seminars conducted on materials given by assistants, during which

students have the opportunity to get acquainted with the main characteristics of the studied

phenomena and devices.


Current assessment.

TEACHING LANGUAGE:

Bulgarian

BIBLIOGRAPHY:

А. Попов, Полупроводникови материали и структури за наноелектрониката, Университетско

издателство „Св. Климент Охридски“, София 2007 .

Г. Младенов, Нанотехнологии и наноелектроника, Академично издателство „проф. Марин

Дринов“, София 2010 .

Timp, G., Ed., Nanotechnology, Springer-Verlag, Berlin, Germany, 1999.

S. Lyshevski, Nano and Molecular Electronics Handbook, CRC Press, Boca Raton, 2007.

C. Nicolini, Molecular Bioelectronics, World Scientific, Singapore, 1996.


Name of the course:

Processes in micro and nanotechniques

Code: ММТН 10.6 Semester: 2

Type of teaching:

Lectures, seminar and laboratory works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h

Number of

credits: 5

LECTURERS:

Assoc. prof. PhD Valentine Videkov, phone 965 3101, e-mail: [email protected]; Technical University

of Sofia, Faculty of Electronics, Department "Microelectronics" and Assoc. prof. PhD Boriana Caneva,

phone 9653663, e-mail: [email protected], Technical University of Sofia, Faculty of Electronics,

Department of "Chemistry".

COURSE STATUS IN THE CURRICULUM: Optional for students in "Microtechnology and

nanoengineering" for the academic degree "Master".

AIMS AND OBJECTIVES OF THE COURSE: The aim of the course is to acquaint students with basic

technological processes in microelectronics and nanoelectronics technology infrastructure. The course

covers the basic requirements for cleanness of the technological environment, equipment for vacuum

processes, epitaxy, production of superpure materials, mounting methods and precise handling and others.

DESCRIPTION OF THE COURSE: During the course students will gain knowledge of technology ,

process , equipment, logistics; technological purity ; clean rooms ; e- beam technologies; processes ion

treatment; processes with laser processing ; mechanical lithographs .

PREREQUISITES: Basic knowledge in materials science, physics, chemistry, nanomaterials are

required.

TEACHING METHODS: Lectures in classical auditory. There is a possibility for presenting some of the

materials with multimedia resources. The course is conducted using site http://ecad.tu-sofia.bg/ procesi-

nano. Attending lectures is selfcontrolled by an electronic. Each visit of lecture brings additional points for

the final evaluation. There are additional questions for self preparing. For further questions or clarifications

students use the forum in the discipline’s web site.

METHOD OF ASSESSMENT: Assessment at the end of the second semester . The evaluation is done by

accumulating points from different types of occupations including self-study and the fulfillment of other

obligations (attending lectures, laboratory, seminar).

TEACHING LANGUAGE: Bulgarian with possibility for English teaching

BIBLIOGRAPHY:

1. Г. Младенов, Нанотехнологии и наноелектроника, Акад. издателство „Проф. Марин Дринов”,

София, 2010.

2. Henrik Bruus, Introduction to nanotechnology, Lyngby, 2004 http://web-

files.ait.dtu.dk/bruus/TMF/publications/books/nnote.pdf



Name of the course:

Microelectronic technologies for

alternative energy sources


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Krassimir Denishev, phone 965 31 85, e-mail: khd@ tu-sofia.bg; Technical





This is elective course in specialty "Microtechnology and nanoengineering" for Master of Scinse

degree.


Students gain knowledge of the latest approaches and technologies to generate "green energy" to

build such elements in a compact form suitable for mobile applications, the properties of the

materials used for their fabrication and their main characteristics. The topics in this course cover the

design, manufacture and testing of components used to generate electrical energy from lost energy

(dissipated scattered in the space as unuseful). Attention is paid to the practical work with these

elements.


Subjects such as generating energy from movement and vibration, solar energy, temperature

gradient and hydrogen cells will be studied.

PREREQUISITES: Knowledge in material science, nanomaterials, physics, nanochemistry

surface technology for micro-and nanosystems is necessary.

TEACHING METHODS: Lectures are held in the hall with multimedia. The laboratory group

conduct a topic under the guidance of assistant on specialized technology equipment and

instrumentation. Seminar groups are divided into subgroups, to each of which is assigned additional

homework regarding more advanced study of specific properties or applications of the

microelectronics application for energy harvesting.

METHOD OF ASSESSMENT:Assessment (current control) during the semester and ongoing

evaluation. Laboratory work’s mark is obtained as an average of the working protocols during the

semester. The student should prepare a paper on a chosen theme. Two tests are running.

TEACHING LANGUAGE: Bulgarian (with possibility for English teaching).

BIBLIOGRAPHY:

1 Shashank Priya, Daniel J. Inman: Energy Harvesting Technologies, Springer US, 2009.

2. Kong Bing, Tao Li, Waste Energy Harvesting: Mechanical and Thermal Energies, Springer, 2014.


Name of the course:

Nano-structured oxides


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Valentine Videkov, phone 965 3101, e-mail: [email protected]; Technical

University of Sofia, Faculty of Electronics, Department "Microelectronics" and Assoc. prof. PhD

Boriana Caneva, phone 9653663, e-mail: [email protected], Technical University of Sofia,

Faculty of Electronics, Department of "Chemistry".




The aim of the course is to familiarize students with a particular nanostructured materials, that are

widely used in electronics, microelectronics and nanoelectronics.


The course covers the basic theoretical and experimental conditions for the production of anode

aluminum oxide and its applications. It is considered as a material for classic applications and for

specific usage for the nanoelectronics.

PREREQUISITES:

Basic knowledge in materials science, physics, chemistry, microelectronics, nanomaterials are

necessary.

TEACHING METHODS:

Lectures in classical audience. There is a possibility for presenting some of the materials with

multimedia resources. The course is conducted using site http://ecad.tu-sofia.bg/ALnano. Attending

lectures is selfcontrolled by an electronic.


Current assessment. Evaluation is done by accumulating points from attendance of lectures,

laboratories and seminar works. Attend classes gives points and additional homeworks bring extra

points. Two tests are conducted.

TEACHING LANGUAGE:

Bulgarian with possibility for English teaching.

BIBLIOGRAPHY:

1 Сокол В.А. Электрохимическая технология гибридных интегральных микросхем Минск

Бестпринт 2004 г. ISBN 985-6767-04-0.

2. Sulka G.D., Chapter 1: Highly ordered anodic Porous alumina formation by self-organized

anodizing, in Nanostructured Materials in Electrochemistry, WILEY-VCH, 2008 , ISBN: 978-3-527-

31876-6



Name of the course:

Methods for analysis of nanoscale

objects


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):

Assoc. prof. PhD Valentine Videkov, phone 965 3101, e-mail: [email protected]; Technical

University of Sofia, Faculty of Electronics, Department "Microelectronics" and Assoc. prof. PhD

Boriana Caneva, phone 9653663, e-mail: [email protected], Technical University of Sofia,

Faculty of Electronics, Department of "Chemistry".




The aim of the course is to familiarize students with the various methods for the study of nanoscale

objects and corresponding hardware solutions.


The course presents the basic methods for monitoring and analysis of nanoscale objects, including

various types of physical methods and specific implementations such as electron microscopy,

microanalysis, spectral analysis, the application of atom force microscopy, etc.

PREREQUISITES:

Basic knowledge in materials science, physics, chemistry, nanomaterials are necessary.

TEACHING METHODS:

Lectures in classical audience. There is a possibility for presenting some of the materials with

multimedia resources. The course is conducted using site http://ecad.tu-sofia.bg/nanoanaliz.

Attending lectures is selfcontrolled by an electronic.


Current assessment. Evaluation is done by accumulating points from attendance of lectures,

laboratories and seminar works. Attend classes gives points and additional homeworks bring extra

points. Two tests are conducted.

TEACHING LANGUAGE:

Bulgarian with possibility for English teaching.

BIBLIOGRAPHY:

1 Hans-Eckhardt Schaefer, Nanoscience, Springer, 2010

2. Encyclopaedia of Materials Characterization – Surfaces, Interfaces, Thin Films. Edts. C. Richard

Brundle, C. A. Evans, Jr. Sh. Wilson, MANNING, 1992.



Name of the course:

Microelectronic technologies for

encoding, recording and reading

information


Type of teaching:


works

Lessons per week:

L-1 h, SW – 1 h, LW-2 h


LECTURER(S):




This is an optional course of specialty "Microtechnology and nanoengineering" for Master of Scinse

degree.


The aim of the course is to acquire knowledge to students for the application of micro-and nano-

technologies for the creation of biometric ID cards and protecting objects and data, data encryption

at the hardware level and to gain skills to apply the methods and means of HiTech protection

information.


At the end of the course students will be able to: Set stochastic single and group protection;

implement stochastic protected by LBR; recorded and read codes from the materials; processed

images and logos hidden encrypted data; perform three-dimensional stochastic read/write encrypted

data on solids.

PREREQUISITES:



TEACHING METHODS:


guidance of the assistant. The seminars are executed on a given topic. Additional sets on a topic to

prepare a referate to be submitted until the end of the course.

METHOD OF ASSESSMENT: Current estimation

TEACHING LANGUAGE:

Bulgarian

BIBLIOGRAPHY:

Nanotechnologies for secure communications, ObservatoryNANO Breifing, 2011

(http://bwcv.es/assets/2011/8/29/Briefing_No.19_Nanotechnologies_for_Secure_Communications.pdf)

Z. Abid, Member, A. Alma’aitah, M. Barua, W. Wang, Efficient CMOL Gate Designs for

Cryptography Applications, IEEE transactions on nanotechnology, vol. 8, no. 3, May 2009.


Name of the course:

Devices and Technologies with Compound

Semiconductor and Metaloxide Materials


Type of teaching:

Lectures, Seminary and Laboratory works

Lessons per week

L-1 hour, SW-1 h, LW-2 hours

Number of credits

5

LECTURERS:

Assoc. Prof. PhD Krassimir Denishev, 9653185, еmail: [email protected],

Assist. Prof. Ph.D. Mariya Aleksandrova, phone: 9653085, email: [email protected],

Technical University of Sofia, Faculty of Electronic Engineering and Technologies (FETT),

Department of Microelectronics.

COURSE STATUS OF THE CURRICULUM:

Optional course for the students specialty "Microtechnologies and Nanoingeneering" MEng programme of

Faculty of Electronic Engineering and Technologies (FETT), Faculty of Industrial Technology (FIT) and

Faculty of Telecommunications (FTC) at Technical University of Sofia.


The purpose of the education on “Devices and Technologies with Compound Semiconductor and

Metaloxide Materials” is the students to get knowledge on the technological processes, used for creation

of structures, devices and blocks, using Compound Semiconductor and Metaloxide Materials, used in

Microelectronics and Micro Electro Mechanical Systems (MEMS). The main objects are the parameters

and the advantages of the mentioned materials, as well as the typical technological processes. The received

knowledge will allow the students to know the parameters of the most frequently used main Compound

Semiconductor and Metaloxide Materials and technological processes, used for such materials, as well as

to be able to define the necessary processes and procedures for designing and producing of

Microelectronics and Mechathronics devices.


In the course, the main parameters and the advantages of the most frequently used Compound

Semiconductor and Metaloxide Materials, as well as the necessary technological processes and

procedures, for creation of devices in Microelectronics and Micro Electro Mechanical Systems (MEMS),

using such materials, are reviewed.

PREREQUISITES:

Physics, Chemistry, Material Science, Nanomaterials, Micro- and Nanosystems Technologies.

TEACHING METHODS:

The lectures are conducted with the aim of visual samples. Laboratory works are carried out by instructions

and protocols.

METHOD OF ASSESSMENT: Two control works, during the second semester and final mark.

INSTRUCTION LANGUAGE: Bulgarian (English is possible).

BIBLIOGRAPHY:

1. “Introduction to Microsystem Technology : A Guide for Students” by Gerald Gerlach, Wolfram Dotzel, Dorte Muller, John Wiley & Sons Inc, ISBN 0470058617, New York, 2008. 2. “Mechatronics: An Introduction” by Robert H. Bishop, CRC Pr I Llc, ISBN 0849363586, New York,

2005.



Documents

DESCRIPTION OF THE COURSE NAME OF THE …oldweb.tu-sofia.bg/eng_new/ECTS/ectas/ectas12-13/feet/ME_EN/FETT...“Introduction to Microsystem ... 9652794, email: [email protected], Department