Wojskowa Akademia Techniczna - Centralny System Uwierzytelniania
Strona główna

Spectroscopy and Optical Imaging in Material Research

Informacje ogólne

Kod przedmiotu: IOEVXCSM-SOIE-23L
Kod Erasmus / ISCED: (brak danych) / (0530) Nauki fizyczne nieokreślone dalej Kod ISCED - Międzynarodowa Standardowa Klasyfikacja Kształcenia (International Standard Classification of Education) została opracowana przez UNESCO.
Nazwa przedmiotu: Spectroscopy and Optical Imaging in Material Research
Jednostka: Instytut Optoelektroniki
Grupy:
Punkty ECTS i inne: (brak) Podstawowe informacje o zasadach przyporządkowania punktów ECTS:
  • roczny wymiar godzinowy nakładu pracy studenta konieczny do osiągnięcia zakładanych efektów uczenia się dla danego etapu studiów wynosi 1500-1800 h, co odpowiada 60 ECTS;
  • tygodniowy wymiar godzinowy nakładu pracy studenta wynosi 45 h;
  • 1 punkt ECTS odpowiada 25-30 godzinom pracy studenta potrzebnej do osiągnięcia zakładanych efektów uczenia się;
  • tygodniowy nakład pracy studenta konieczny do osiągnięcia zakładanych efektów uczenia się pozwala uzyskać 1,5 ECTS;
  • nakład pracy potrzebny do zaliczenia przedmiotu, któremu przypisano 3 ECTS, stanowi 10% semestralnego obciążenia studenta.

zobacz reguły punktacji
Język prowadzenia: angielski
Forma studiów:

stacjonarne

Rodzaj studiów:

II stopnia

Rodzaj przedmiotu:

wybieralny

Forma zajęć liczba godzin/rygor:

(tylko po angielsku) Lect. 14, pract. 8+, lab. 8, sem. 10. In summa: 40, ECTS: 3

Przedmioty wprowadzające:

(tylko po angielsku) Physics, Electronics measurements

Programy:

(tylko po angielsku) Optoelectronics

Autor:

(tylko po angielsku) prof.dr hab.in.Mirosław Kwaśny

Bilans ECTS:

(tylko po angielsku) 3

Skrócony opis: (tylko po angielsku)

The essence, scope, division of spectroscopy and its application in material research, including optical and optoelectronic research. Review of spectroscopic measurement methods and techniques in the field of UV-VIS-IR. Theoretical foundations of molecular and atomic spectroscopy. Quantitative characteristics of the phenomena of absorption, emission and scattering. Construction of spectroscopic equipment. Atomic absorption spectroscopy (ASA) and emission spectroscopy (ICP). Basics and applications of fluorescence. Spectroscopy Frame. FTIR spectroscopy. UV-VIS spectroscopy. Imaging equipment, applications of imaging techniques in materials research.

Pełny opis: (tylko po angielsku)

Lectures:

1. Characteristics of measurement parameters. Basics of spectroscopy (structure of atom and molecule, atomic models, atomic and molecular terms, divisions of spectroscopy, interaction of EMF with matter, essence of optical spectroscopy and X-ray spectroscopy - 2 hours.

2. Construction of spectroscopic equipment (spectrometers and spectro-photometers, frequency and time domain techniques. Construction of photometer elements - optics, detectors, light sources) – 2 hours.

3. Basics and applications of fluorescence (the essence of the phenomenon, Jabłoński's diagram, efficiency of emission processes, methods of measuring fluorescence lifetime) - 2 hours.

4. Raman spectroscopy (light scattering phenomena, basics of the method, applications, construction of equipment. Raman imaging) – 2 hours

5. FTIR spectroscopy (basics of the method, applications, equipment, FTIR imaging) – 2 hours.

6. UV-VIS spectroscopy (basics, applications, equipment construction) - 2 hours.

7. Atomic absorption spectroscopy (ASA) and emission spectroscopy (ICP)(basic methods, applications, equipment -2 hours.

Exercises:

1. Basics of spectroscopy (PEM, atomic structure, interaction of PEM with matter, differences between optical and X-ray spectroscopy) – 2 hours

2. Fluorescence techniques, laser-induced fluorescence-fluorescence – 2 hours

3. Raman and FTIR spectroscopy – 2 hours

4. Atomic spectroscopy –two hours

Laboratories:

1. Fluorescence methods. Determination of fluorescence quantum yield. Emission and excitation matrices – 4 hours

2. Application of Raman spectroscopy and FTIR imaging in material analysis. Examples of markings of selected optical materials and polymers – 4 hours.

Seminars

1. Getting to know the spectral laboratories at IOE and CIBio, presentations of measurement equipment and techniques - 2 hours

2. Methods and techniques of gas analysis – 2 hours

3. Methods of analysis of hazardous substances - chemical and biological warfare agents, aerosols - 2 hours.

4. Imaging techniques – OCT, MRI, PET – 2 hours.

5. Optical methods - (polarimetry, interferometry, refractometry, turbidimetry) in material testing - 2 hours.

Literatura: (tylko po angielsku)

Primary reading list:

1. Sune Svanberg, Atomic and Molecular Spectroscopy, Springer, 2022.

2.Wiliam W.Parson, Modern Optical Spectroscopy, Springer 2023.

Supplementary reading list:

1. Wolfgang Demtroder, Atoms, Molecules and Photona, Springer 2018

2. Prabal Kumar Mallick, Fundamentals of Molecular Spectroscopy, Springer 2023

Efekty uczenia się: (tylko po angielsku)

W1/has extended and improved his/her knowledge in the field

of physics, including the elements of quantum physics and

solid-state physics, the elements of laser physics, including

the knowledge required for understanding the physical

phenomena having a great impact on the properties of new

materials and the functioning of electronic and

optoelectronic elements and is familiar with the methods

and forms of description of optical material media and the

influence of electromagnetic radiation on material media /W06

W2/ has knowledge as to the use of computers in

measurements. Is familiar with the organization and

application of selected interfaces of measurement systems,

knows how to proceed with research including the use of

computers /W09

W3/ has an extended knowledge in the field of physics and

astrophysics, is familiar with and understands physical

phenomena and processes occurring in the natural

environment, especially in the field of mechanics,

electromagnetism, special theory of relativity, elements of

quantum mechanics, basic solid-state physics, elements of

nuclear physics and plasma physics /W15

W4/has an extended knowledge of optics and optoelectronic

materials science and can use it to analyze and to design

optical systems in optoelectronic equipment /W24

U1/may plan and proceed with experiments, including

measurements and computer simulations and interpret the

obtained results and draw conclusions /U06

U2/ may use analytical, simulation and experimental methods to

formulate and solving of engineering tasks and simple

research problems /U07

U3/ may evaluate the utility and the possibility of use of new

achievements (techniques and technology) in the field of

optoelectronics /U10

K1/ recognizes the need of continuous building of knowledge

and competences, knows how to inspire the process of

education of other persons, is ready to consult experts in

case of difficulties in independent solving of problems /K01

K2/understands the need and knows the possibilities of

continuous self-education (studies of third level,

postgraduate studies, courses) – increase of professional

competences, both personal and social ones /K02

K3/ is aware of the importance of professional conduct, respect

of rules of professional ethics and respect for diversity of

opinions and cultures /K03

Metody i kryteria oceniania: (tylko po angielsku)

Credit for the course is awarded on the basis of: examination, subject assessment.

Practicals are assessed on the basis of: individual written examination or oral tests.

Laboratories are assessed on the basis of: individual written examination or oral tests and completed protocols.

Assessment of the subject is conducted in written and oral form; The exam/credit assessment is conducted in the form of: written examination or oral tests.

The condition for admission to the exam/pass is: passing the exercises and laboratories.

The achievement of the effect W1, U1, U2 - is verified during exercises and laboratory exercises; Achieving the effect W1 - is tested the exam/pass

Very good grade is awarded to the student who has achieved the expected learning outcomes at the level of 91-100%.

Good plus grade is awarded to the student who has achieved the expected learning outcomes at the level of 81-90%.

Good grade is awarded to the student who has achieved the expected learning outcomes at the level of 71-80%.

Sufficient plus grade is awarded to the student who has achieved the expected learning outcomes at the level of 61-70%.

Sufficient grade is awarded to the student who has achieved the expected learning outcomes at the level of 51-60%.

Insufficient grade is awarded to the student who has achieved the expected learning outcomes at the level equal or lower than 50%.

General credited grade is awarded to the student who has achieved the expected learning outcomes at the level higher than 50%.

General non-credited grade is awarded to the student who has achieved the expected learning outcomes at the level equal or lower than 50%.

Przedmiot nie jest oferowany w żadnym z aktualnych cykli dydaktycznych.
Opisy przedmiotów w USOS i USOSweb są chronione prawem autorskim.
Właścicielem praw autorskich jest Wojskowa Akademia Techniczna.
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