9360-0160/01 – Spectroscopy of Nanostructures (SN)

Gurantor departmentCNT - Nanotechnology CentreCredits3
Subject guarantordoc. Dr. Mgr. Kamil PostavaSubject version guarantordoc. Dr. Mgr. Kamil Postava
Study levelundergraduate or graduateRequirementChoice-compulsory type A
Year1Semesterwinter
Study languageCzech
Year of introduction2018/2019Year of cancellation
Intended for the facultiesUSP, FEI, FMTIntended for study typesFollow-up Master
Instruction secured by
LoginNameTuitorTeacher giving lectures
POS40 doc. Dr. Mgr. Kamil Postava
Extent of instruction for forms of study
Form of studyWay of compl.Extent
Full-time Credit and Examination 3+0

Subject aims expressed by acquired skills and competences

The main target of this subject is to understand fundamental principles of optical spectroscopy to characterize materials, thin films, nanostructured and periodic systems. Attention is devoted to methods and techniques of measurement, optical properties of materials, modeling of spectroscopic response and fitting of experimental spectroscopic data to a model. Applications of the spectroscopic methods in chemical analysis, characterization in material structure and properties are summarized.

Teaching methods

Lectures

Summary

The main target of this subject is to understand fundamental principles of optical spectroscopy to characterize materials, thin films, nanostructured and periodic systems. Attention is devoted to methods and techniques of measurement, optical properties of materials, modeling of spectroscopic response and fitting of experimental spectroscopic data to a model. Applications of the spectroscopic methods in chemical analysis, characterization in material structure and properties are summarized.

Compulsory literature:

HOLLAS, J. M., Modern Spectroscopy (4th ed.), John Willey & Sons, 2009. FOX, M., Optical properties of solids, Oxford Univ. Press, 2003. STENZEL, O., The physics of thin film optical spectra, Springer, Berlin, 2005. PALIK, E. D., Handbook of optical constants of solids, Academic Press, New York, 1998.

Recommended literature:

OHLÍDAL, I., FRANTA, D.: Ellipsometry of thin film systems, In: Progress in Optics, Vol. 41, Ed. E. Wolf, 2000. ZVEZDIN, A. K., KOTOV, V. A.: Modern magnetooptics and magnetooptical materials, IOP, Bristol 1977. HRING, M., The material science of thin films, Academic Press, 1992. MACLEOD, H. A.: Thin-film optical filters, 2nd ed. Bristol, 1986. YEH, P.: Optical waves in layered media, Willey, New York 1988. LUTH, H., Solid surfaces, interfaces and thin films, Springer, Berlin 2001. AZZAM, R. M. A., BASHARA, N. M.: Ellipsometry and polarized light, North-Holland, Amsterdam, 1977. SVANBERG, S.: Atomic and molecular spectroscopy: basic aspects and practical applications, Springer-Verlag, Berlin 1991.

Way of continuous check of knowledge in the course of semester

Written and oral.

E-learning

Další požadavky na studenta

For this subject other requirements for student are not determined.

Prerequisities

Subject has no prerequisities.

Co-requisities

Subject has no co-requisities.

Subject syllabus:

The subject deals with methods, physical description and appliications of optical spectroscopy. The lectures consists of: 1. Physical principles of optical spectroscopy, origin of spectral dependence of optical parameters, Kramers-Kronigovy relations and its application in spectroscopy. 2. Modeling of light propagation, reflection, transmission, and absorption spectra of materials, thin films, and nanostructures. 3. Dispersion elements, gratings, doispersion prism, interference methods in infrared spectroscopy, time-domain spectroscopy. Sources, detectors and materials used in spectrometers. 4. Spectroscopy in visible, near ultraviolet and near infrared spectral range (components of spectrometers, dual beam spectrometer, resolution). 5. Spectroscopic ellipsometry, ellipsometric angles, generalized and Mueller matrix ellipsometry, methods of data processing. 6. Spectroscopy in mid infrared spectral range (physical origin of infrared absorptions, vibration spectra, symmetry, Fourier transform infrared spectroscopy, apodization, ATR, IRRAS), Raman spektroscopy. 7. Magneto-optical spectroscopy (origin of magneto-optical effects, Kerr, Faraday, and Voight magneto=optic effects). 8. Origin of optical spectra from free charges, drude term, relation with electrical properties of materials. Debye model, absorption of polar liquids. 9. Model of damped harmonic oscillator, application for description of interband transitions and for vibration spectra in infrared spectroscopy. 10. Semiclasical theory of optical spectra of crystals, band structure, polycrystalline and amorphous materials, excitons. 11. Origin of infrared vibration and rotation spectra. 12. Models of nanostructured and nanokomposite materials. Application of effective medium theory, Maxwell-Garnet a Bruggeman formula. Description of periodic and aperiodic systems, plasmonics.

Conditions for subject completion

Full-time form (validity from: 2018/2019 Winter semester)
Task nameType of taskMax. number of points
(act. for subtasks)
Min. number of points
Credit and Examination Credit and Examination 100  51
        Credit Credit  
        Examination Examination  
Mandatory attendence parzicipation:

Show history

Occurrence in study plans

Academic yearProgrammeField of studySpec.FormStudy language Tut. centreYearWSType of duty
2019/2020 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2019/2020 (N0719A270002) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2019/2020 (N0533A110006) Applied Physics P Czech Ostrava 1 Choice-compulsory type A study plan
2019/2020 (N1701) Physics (1702T001) Applied Physics P Czech Ostrava 1 Choice-compulsory study plan
2018/2019 (N3942) Nanotechnology (3942T001) Nanotechnology P Czech Ostrava 1 Compulsory study plan
2018/2019 (N1701) Physics (1702T001) Applied Physics P Czech Ostrava 1 Choice-compulsory study plan

Occurrence in special blocks

Block nameAcademic yearForm of studyStudy language YearWSType of blockBlock owner