The aim of studying and bibliography

The main aim of study: The students should obtain knowledge of instrumental methods of analysis of organic compounds.

The general information about the module: The module is implemented in the second semester. There are 9 hours of lectures and 9 hours laboratory. Module ends with a credit.

Bibliography required to complete the module

Bibliography used during lectures

1	Praca zbiorowa	Metody spektralne i ich zastosowanie do identyfikacji związków organicznych	WNT, Warszawa.	1995
2	Silverstein R. i inni	Spektroskopowe metody identyfikacji zwiazków organicznych	Wydawnictwo Naukowe PWN, Warszawa.	2007
3	Kazicyna L.A., Kupletska W.B.	Metody spektroskopowe wyznaczania struktury związków organicznych	PWN, Warszawa.	1974

Bibliography used during classes/laboratories/others

1	Praca zbiorowa	Metody spektralne i ich zastosowanie do identyfikacji związków organicznych	WNT, Warszawa.	1995
2	Silverstein R. i inni	Spektroskopowe metody identyfikacji zwiazków organicznych	Wydawnictwo Naukowe PWN, Warszawa.	2007
3	Kazicyna L.A., Kupletska W.B.	Metody spektroskopowe wyznaczania struktury związków organicznych	PWN, Warszawa.	1974

Bibliography to self-study

1	Praca zbiorowa	Metody spektralne i ich zastosowanie do identyfikacji związków organicznych	WNT, Warszawa.	1995
2	Silverstein R. i inni	Spektroskopowe metody identyfikacji zwiazków organicznych	Wydawnictwo Naukowe PWN, Warszawa.	2007
3	Kazicyna L.A., Kupletska W.B.	Metody spektroskopowe wyznaczania struktury związków organicznych	PWN, Warszawa.	1974

Basic requirements in category knowledge/skills/social competences

Formal requirements: Registration for semester II

Basic requirements in category knowledge: Knowledge of the nomenclature, structure, preparation methods, physical and chemical properties of the basic classes of organic compounds and basic knowlegde of the spectral techniques.

Basic requirements in category skills: Ability to name and to predict a chemical properties of organic compounds based on the structure and the effects of electron transfer, ability to work in a laboratory.

Basic requirements in category social competences: Ability to work in a team.

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
01	has knowledge of instrumental methods determining structure of organic compounds	lecture, laboratory	colloquium, written test, written report	K_W01++ K_W08++	P7S_WG
02	can propose a spectral method to identify organic compounds and identify simple organic compounds using spectral methods	lecture, laboratory	colloquium, written test, written report	K_U14++ K_U15++	P7S_UW
03	can individually expand their knowledge in the analysis of the organic compounds		performance monitoring	K_K01+	P7S_KK

Attention: Depending on the epidemic situation, verification of the achieved learning outcomes specified in the study program, in particular credits and examinations at the end of specific classes, can be implemented remotely (real-time meetings).

The syllabus of the module

Sem.	TK	The content	realized in	MEK
2	TK01	The types of methods of analysis of organic compounds. Elemental analysis, detection and determination of the elements in the organic compounds. Mass spectrometry. Spectral methods: UV-VIS, IR, NMR and EPR. Chirooptical methods. Study of the composition of mixtures of tautomers. Analysis of the steric structure of enantiomers and diastereomers. Analysis of mixtures of organic compounds.	W01 - W15, L01 - L10	MEK01 MEK02 MEK03

The student's effort

The type of classes	The work before classes	The participation in classes	The work after classes
Lecture (sem. 2)		contact hours: 9.00 hours/sem.	Studying the recommended bibliography: 4.00 hours/sem.
Laboratory (sem. 2)	The preparation for a Laboratory: 1.00 hours/sem. The preparation for a test: 10.00 hours/sem.	contact hours: 9.00 hours/sem.	Finishing/Making the report: 4.00 hours/sem.
Advice (sem. 2)
Credit (sem. 2)	The preparation for a Credit: 10.00 hours/sem.	The written credit: 3.00 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	The final grade depends on the basis of 2 written tests including the whole scope of material. The final test grade depends on the amount of points : 3.0 52.0%-62.0% ; 3.5 62.1%-72.0%; 4.0 72.1%-81.0%; 4.5 81.1%-90.5%; 5.0 90.6%-100%.
Laboratory	Each laboratory exercise must be positively included. The final grade of the exercise is an arithmetic average from written test and properly performed exercise. The final grade of the laboratory is an arithmetic average from all exercise included in the curriculum.
The final grade	Final grade (K): K = 0,4 w L + 0,6 w Z; where: L, Z - positive evaluation of the lab and lecture; w - factor related to the time of credit, w= 1.0 first term, w = 0.9 second term , w = 0.8 third term. The grade 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 : yes

Available materials : spectroscopic correlation tables

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

1	B. Dębska; J. Lubczak; A. Strzałka	Polyols and polyurethane foams based on chitosans of various molecular weights	2024
2	E. Chmiel-Bator; J. Lubczak; R. Lubczak; M. Szpiłyk	Sposób otrzymywania poliolu	2024
3	J. Lubczak; A. Strzałka	Sposób wytwarzania wielofunkcyjnych polioli z wykorzystaniem chitozanu	2024
4	J. Lubczak; A. Strzałka	Polyols and Polyurethane Foams Based on Water-Soluble Chitosan	2023
5	J. Lubczak; A. Strzałka	Polyurethane foams with hydroxylated chitosan units	2023
6	J. Lubczak; A. Strzałka	Sposób wytwarzania wielofunkcyjnych polioli	2023
7	J. Lubczak; A. Strzałka	Sposób wytwarzania wielofunkcyjnych polioli z wykorzystaniem chitozanu	2023
8	J. Lubczak; R. Lubczak	Oligoetherols and polyurethane foams based on cyclotriphosphazene of reduced fammability	2023
9	J. Lubczak; R. Lubczak; A. Strzałka	Chitosan Oligomer as a Raw Material for Obtaining Polyurethane Foams	2023
10	J. Lubczak; R. Lubczak; A. Strzałka	Polyols obtained from chitosan	2023
11	J. Lubczak; R. Lubczak; M. Szpiłyk	Sposób wytwarzania mieszaniny polioli	2023
12	J. Lubczak; R. Lubczak; M. Szpiłyk	Sposób wytwarzania wielofunkcyjnych polieteroli	2023
13	E. Chmiel-Bator; J. Lubczak; R. Lubczak; M. Szpiłyk	Polyols and Polyurethane Foams Obtained from Mixture of Metasilicic Acid and Cellulose	2022
14	J. Lubczak; M. Walczak	e-caprolactone and pentaerythritol derived oligomer for rigid polyurethane foams preparation	2022
15	J. Lubczak; R. Lubczak	Increased Thermal Stability and Reduced Flammability of Polyurethane Foams with an Application of Polyetherols	2022
16	D. Broda; B. Dębska; M. Kus-Liśkiewicz; J. Lubczak; R. Lubczak; D. Szczęch; R. Wojnarowska-Nowak	Polyetherols and polyurethane foams from starch	2021
17	E. Bobko; D. Broda; B. Dębska; M. Kus-Liśkiewicz; J. Lubczak; R. Lubczak; D. Szczęch; M. Szpiłyk	Flame retardant polyurethane foams with starch unit	2021
18	J. Lubczak; R. Lubczak; D. Szczęch	Sposób otrzymywania mieszaniny wielofunkcyjnych polieteroli	2021
19	J. Lubczak; R. Lubczak; M. Szpiłyk	Polyetherols and polyurethane foams with cellulose subunits	2021
20	J. Lubczak; R. Lubczak; M. Szpiłyk	Sposób wytwarzania wielofunkcyjnych polieteroli	2021
21	J. Lubczak; R. Lubczak; M. Szpiłyk	The biodegradable cellulose-derived polyol and polyurethane foam	2021
22	J. Lubczak; R. Lubczak; M. Szpiłyk; M. Walczak	Polyol and polyurethane foam from cellulose hydrolysate	2021
23	M. Borowicz; E. Chmiel; J. Lubczak; J. Paciorek-Sadowska	Use of a Mixture of Polyols Based on Metasilicic Acid and Recycled PLA for Synthesis of Rigid Polyurethane Foams Susceptible to Biodegradation	2021
24	E. Chmiel; J. Lubczak	Polyurethane foams with 1,3,5-triazine ring, boron and silicon	2020
25	J. Lubczak; M. Szpiłyk	Sposób wytwarzania oligoeterolu z pierścieniem azafosfacyklicznym	2020
26	J. Lubczak; R. Lubczak; D. Szczęch	From starch to oligoetherols and polyurethane foams	2020
27	B. Dębska; J. Duliban; K. Hęclik; J. Lubczak	Analysis of the Possibility and Conditions of Application of Methylene Blue to Determine the Activity of Radicals in Model System with Preaccelerated Cross-Linking of Polyester Resins	2019
28	E. Chmiel; J. Lubczak	Polyurethane foams with 1,3,5-triazine ring and silicon atoms	2019
29	E. Chmiel; J. Lubczak	Sposób otrzymywania termoodpornych i niepalnych pianek poliuretanowych	2019
30	E. Chmiel; J. Lubczak	Synthesis of oligoetherols from mixtures of melamine and boric acid and polyurethane foams formed from these oligoetherols	2019
31	E. Chmiel; J. Lubczak; R. Oliwa	Boron-containing non-flammable polyurethane foams	2019
32	J. Lubczak; R. Lubczak; D. Szczęch	Sposób otrzymywania mieszaniny wielofunkcyjnych polieteroli	2019
33	J. Lubczak; R. Lubczak; I. Zarzyka	Sposób otrzymywania polieteroli z pierścieniami azacyklicznymi	2019
34	M. Borowicz; B. Czupryński; J. Lubczak; J. Paciorek-Sadowska	Biodegradable, Flame-retardant, and Bio-Based rigid Polyurethane/Polyisocyanurate Foams for Thermal Insulation Application	2019