Karta przedmiotu

Instrumential analysis

Some basic information about the module

Cycle of education:

2022/2023

The name of the faculty organization unit:

The faculty Chemistry

The name of the field of study:

Chemical Technology

The area of study:

technical sciences

The profile of studing:

The level of study:

first degree study

Type of study:

past time

discipline specialities :

Chemical analysis in industry and environment, Chemical and bioprocess engineering, Organic and polymer technology

The degree after graduating from university:

Bachelor of Science (BSc)

The name of the module department :

Department of Physical Chemistry

The code of the module:

5273

The module status:

mandatory for teaching programme Chemical analysis in industry and environment, Chemical and bioprocess engineering, Organic and polymer technology

The position in the studies teaching programme:

sem: 5 / W18 L27 / 6 ECTS / Z

The language of the lecture:

Polish

The name of the coordinator 1:

Julian Kozioł, PhD, Eng.

The name of the coordinator 2:

Prof. Andrzej Sobkowiak, DSc, PhD, Eng.

The aim of studying and bibliography

The main aim of study:
Acquisition of a theoretical knowledge and experience on practical applications of modern instrumental analysis techniques used for chemical analysis of organic and inorganic compounds.

The general information about the module:
The module is realised in the 5-th semester and include 30 hours of lectures and 45 hours of laboratory practice. Module ends with a graded assignment.

others:
Instrukcje do ćwiczeń laboratoryjnych

Bibliography required to complete the module

Bibliography used during lectures
1	K. Danzer i inn.	Analityka – przegląd systematyczny	WNT, Warszawa .	1993
2	A. Cygański	Metody spektroskopowe w chemii analitycznej	WNT, Warszawa.	1997
3	E. Hoffmann, J. Charette, V. Stroobant	Spektrometria mas	WNT, Warszawa.	1998
4	A. Cygański	Metody elektroanalityczne	WNT, Warszawa.	1995
5	Z. Witkiewicz	Podstawy chromatografii	WNT, Warszawa.	2005

Bibliography used during classes/laboratories/others
1	W. Szczepaniak	Metody instrumentalne w analizie chemicznej	PWN, Warszawa.	2004
2	R.M. Silverstein i inn.	Spektroskopowe metody identyfikacji związków organicznych	PWN, Warszawa.	2007

Bibliography to self-study
1	W. Szczepaniak	Metody instrumentalne w analizie chemicznej	PWN, Warszawa.	2004

Basic requirements in category knowledge/skills/social competences

Formal requirements:
Registration for V semester

Basic requirements in category knowledge:
Knowledge and understanding of the basic physics, general, analytical, organic and physical chemistry.

Basic requirements in category skills:
Skills in calculation of chemical concentration, solutions preparation, operation of basic laboratory equipment for chemical analysis, measurement as well as computer. A basic knowledge of mathematics

Basic requirements in category social competences:
Knowledge of principles of safe work in chemical laboratory, responsibility during experiments performed individually or in laboratory group.

Module outcomes

MEK	The student who completed the module	Types of classes / teaching methods leading to achieving a given outcome of teaching	Methods of verifying every mentioned outcome of teaching	Relationships with KEK	Relationships with PRK
MEK01	Has a theoretical and practical knowledge of construction and mechanizm of action of modern analytical equipment.	lecture, laboratory	written test, performance observation	K-W04++	P6S-WG
MEK02	Has a basic knowledge of the possibilities and application of particular instrumental methods for solving analytical problems.	lecture	written test	K-W04++	P6S-WG
MEK03	Knows basic concepts connected with the instrumental methods used for analysis of the materials and organic compounds.	lecture	written test	K-W04++	P6S-WG
MEK04	Is able to justify the choice of a particular instrumental method suitable to the analytical and economical conditions.	lecture, laboratory	written test	K-U11++ K-U21+	P6S-UO P6S-UW
MEK05	Is able to make use of analytical instruments to perform individual types of analysis.	laboratory	written test, observation of job performance	K-U21++	P6S-UW
MEK06	Can select the appropriate calibration method; carry out identification and elimination of measurement errors.	lecture, laboratory	written test	K-U11+	P6S-UO P6S-UW
MEK07	Is able to prepare a report on the results of the investigation, perform interpretation and evaluation of the analysis results and draw correct conclusions.	laboratory	written report	K-U21+	P6S-UW
MEK08	Is abble to work individually and in a team environment in laboratory of instrumental analysis.	laboratory	observation of job performance	K-U21+	P6S-UW
MEK09	Is able to identify a situation threatening to life or health and follow the principles of safe work in chemical laboratory.	laboratory	observation of job performance	K-U14+	P6S-UW
MEK10	Understand the need of widening their knowledge in the field of new solutions related to equipment and methods of instrumental analysis.	lecture, laboratory	observation of job performance	K-K01++	P6S-KK P6S-KO P6S-KR

The syllabus of the module

Sem.	TK	The content	realized in	MEK
5	TK01	Definition and aims of instrumental analysis. Classification of the physicochemical methods of analysis. Optical methods. Polarimetry definition and applications. Quantitative analysis of elements and compounds using spectroscopic methods - introduction to spectrophotometry, spectrophotometers. Atomic Emission Spectroscopy - theory, excitation sources, spectrometers and applications. Atomic Absorption Spectroscopy (AAS) principles and applications. Absorption spectroscopy in UV/VIS. IR absorption spectroscopy - principles, spectrometers, spectra, application in quantitative and qualitative analysis. Basic principles of magnetic nuclear resonance. Structural and quantitative analysis on the base of 1H-NMR spectra. Mass spectrometry of organic compounds. Interpretation and analytical application of mass spectra. Analytical separation methods. Chromatography definition and classification. Gas chromatography. The plate theory and the rate theory applied in practice. Liquid chromatography - column and planar. High performance liquid chromatography (HPLC). Apparatus and separation techniques: gradient elution and mobile phase programmed flow speed. Optymalisation of separation processes - theory and practice of stationary and mobile phase selection and separation parameters. HPLC applications. Electroanalytical methods. Potentiometry - principles and instrumentation. Construction, principles of operation and applications of chosen ion-selective electrodes (ISE). Voltammetric methods - the main techniques. Selected applications of voltammetric methods in laboratory and industrial analysis. Conductometry - definition, instrumentation and application. Complementarity of instrumental methods. Criteria of choice of analytical methods.	W30	MEK01 MEK02 MEK03 MEK04 MEK06 MEK10
5	TK02	Quantitative analysis of mixture components using Gas Chromatography. Determination of aromatic hydrocarbons and their derivatives using HPLC method. Identification of hydrocarbon mixture components with Kovats indices. IR measurement techniqu - spectrometer calibration, cell pathlength determination, qualitative and quantitative analysis. Determination of concentration by UV-Vis spectroscopy. Analysis of multicomponent mixtures with 1H-NMR spectroscopy method. Atomic Absorption Spectroscopy - determination of elements in solution. Polarimetric determination of the concentration of sucrose in water solution. Determination of the concentrations of chloride and of iodide in an unknown solution by potentiometric titration. Determination of phenol concentration by conductometric titration.	L45	MEK01 MEK04 MEK05 MEK07 MEK08 MEK09 MEK10

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 5)		contact hours: 18.00 hours/sem.	complementing/reading through notes: 10.00 hours/sem. Studying the recommended bibliography: 20.00 hours/sem.
Laboratory (sem. 5)	The preparation for a Laboratory: 10.00 hours/sem. The preparation for a test: 30.00 hours/sem.	contact hours: 27.00 hours/sem.	Finishing/Making the report: 25.00 hours/sem.
Advice (sem. 5)
Credit (sem. 5)	The preparation for a Credit: 15.00 hours/sem.	The written credit: 2.00 hours/sem.

The way of giving the component module grades and the final grade

The type of classes	The way of giving the final grade
Lecture	A written test including the content of lectures and laboratories. The test includes theoretical part and calculation problems. The mark (OW) depends on the score gained: 3.0 (50.0%-60.0%) MP ; 3.5 (60.1%-70.0%) MP; 4.0 (70.1%-80.0%) MP; 4,5 (80.1%-90.0%) MP; 5.0 (90.1%-100%) MP. MP denotes the full score.
Laboratory	The necessary condition for receiving a credit for the laboratory is obtaining at least a passing mark on each exercise included in the schedule. The mark obtained during each laboratory exercise is an arithmetic mean of the marks for a written/oral test, correct performance of an experiment and correct preparation of a report. The total mark in the laboratory work (OL) is calculated as arithmetic mean of the marks obtained for every exercise included in the schedule. A final mark for the laboratory is rounded according to WKZJK.
The final grade	The final mark in the module (K) is calculated according to the formula: K= w 0,5 OW + w 0,5 OL; where: OW, OL denote positive marks for lecture test and laboratory practice, respectively, w - coefficient for delay, w =1.0 when a passing mark is obtained in due time, w=0.9 for a first resit, w=0.8 for a second resit. The final mark is rounded according to WKZJK.

Sample problems

Required during the exam/when receiving the credit
(-)

Realized during classes/laboratories/projects
(-)

Others
(-)

Can a student use any teaching aids during the exam/when receiving the credit : no

The contents of the module are associated with the research profile yes

1	K. Rydel-Ciszek; A. Sobkowiak	The [(Bn-tpen)FeII]2+ Complex as a Catalyst for the Oxidation of Cyclohexene and Limonene with Dioxygen	2024
2	D. Naróg; A. Sobkowiak	Electrochemistry of Flavonoids	2023
3	P. Chmielarz; T. Pacześniak; K. Rydel-Ciszek; A. Sobkowiak	Bio-Inspired Iron Pentadentate Complexes as Dioxygen Activators in the Oxidation of Cyclohexene and Limonene	2023
4	Ł. Florczak; B. Kościelniak; A. Kramek; A. Sobkowiak	The Influence of Potassium Hexafluorophosphate on the Morphology and Anticorrosive Properties of Conversion Coatings Formed on the AM50 Magnesium Alloy by Plasma Electrolytic Oxidation	2023
5	D. Naróg; A. Sobkowiak	Electrochemical Investigation of some Flavonoids in Aprotic Media	2022
6	K. Darowicki; Ł. Florczak; G. Nawrat; K. Raga; J. Ryl; J. Sieniawski; A. Sobkowiak; M. Wierzbińska	The Effect of Sodium Tetrafluoroborate on the Properties of Conversion Coatings Formed on the AZ91D Magnesium Alloy by Plasma Electrolytic Oxidation	2022
7	A. Baran; M. Drajewicz; A. Dryzner; M. Dubiel; Ł. Florczak; M. Kocój-Toporowska; A. Krząkała; K. Kwolek; P. Kwolek; G. Lach; G. Nawrat; Ł. Nieużyła; K. Raga; J. Sieniawski; A. Sobkowiak; T. Wieczorek	Method of Forming Corrosion Resistant Coating and Related Apparatus	2021
8	P. Chmielarz; A. Miłaczewska; T. Pacześniak; K. Rydel-Ciszek; A. Sobkowiak	‘Oxygen-Consuming Complexes’–Catalytic Effects of Iron–Salen Complexes with Dioxygen	2021
9	P. Błoniarz; P. Chmielarz; T. Pacześniak; K. Rydel-Ciszek; A. Sobkowiak; K. Surmacz; I. Zaborniak	Iron-Based Catalytically Active Complexes in Preparation of Functional Materials	2020