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Teaching and Training – Universität Innsbruck

University Courses

Univ.-Prof. Dr. Christopher A. Mayhew

Type/Hours: ECTS-AP:  2,5

Link to University Course

Mode of repetition: semestral

Language of instruction: English

Learning Outcome:

To introduce the fundamental science of ion-molecule chemistry that underpins chemical ionisation mass spectrometry

To provide the framework needed for gaining a knowledge and an in-depth understanding of ion-molecule reactions for later development and use in a second course dealing with ion-molecule chemistry and gas-phase analytical chemistry: Applications of Chemical Ionisation Mass Spectrometry (748003), a 5 ECTS course that includes lectures and major practical studies.  (Successful completion of 748002 is a prerequisite for undertaking 748003.)

To link the spectroscopic information received from interstellar space to the development of laboratory based chemical ionisation mass spectrometers for investigations to explain the interstellar chemistry observed spectroscopically

To provide hands-on-experience of spectroscopic measurements and an understanding of atomic and molecular transitions

Contents:

1. Lecture Material (15 lectures)

Ion-molecule reaction chemistry

  • types of ion-molecule reactions
  • reaction rate equation
  • experimentally determining the reaction rate coefficient
  • calculating reaction rate coefficients
  • biomolecular ion-molecule reactions
  • termolecular reactions
  • radiative association processes
  • calculating the collisional reaction rate coefficient

Ion-molecule processes and planetary atmospheres

  • spectroscopy
  • spectroscopic nomenclature (atoms)
  • atomic transitions
  • forbidden transitions
  • regions of the ionosphere
  • transmission and reflection of electromagnetic waves ion-molecule processes

Ion-molecule processes and interstellar chemistry

  • nebulae (HII regions)
  • interstellar clouds
  • Maxwell’s laws of electromagnetism
  • propagation of electromagnetic radiation through space
  • spectroscopic measurements
  • rotational spectra and the discovery of molecules in space
  • interstellar chemistry – spectroscopic discovery of molecules in space
  • Laboratory – creating an HII nebula and determining the ionisation energy of atomic hydrogen

Development of Chemical Ionisation Mass Spectrometric Instrumentation

  • Laboratory investigations to explain the spectroscopic discoveries of interstellar space and planetary atmospheres
  • Precursor instrumentation to state-of-the-art analytical instruments currently used to detect trace chemical compounds (from parts per trillion by volume)

              - Flowing Afterglow Mass Spectrometer
               - Selected Ion Flow Tube Mass Spectrometer
               - Proton Transfer Reaction-Mass Spectrometer

Fundamentals of Mass Spectrometry

  • mass spectra
  • definitions and nomenclature
  • resolving power
  • isotopes
  • ion sources
  • mass analysers
  • ion detectors

2. Practical Work (1 day) - Line spectra: the Balmer Series and its link to nebula

  • Learning how to calibrate a spectroscope (use of a helium lamp) coupled to a CCD camera
  • Determining the Rydberg constant RH from measurements of the visible spectrum of atomic hydrogen

Methods:

Lectures and Experimental Work (taught in English)

o provide a series of tutorial style lectures drawing together and developing concepts from various disciplines (e.g. chemistry, physics, and biosciences) and different subjects (e.g. quantum mechanics, plasma physics, statistical mechanics, and electromagnetism) to describe ion-molecule processes and their importance in many chemical environments, including planetary atmospheres and interstellar space.

Assessment: written

Literature:

G.A. Eiceman, Z. Karpas, H. H. Hill „Ion Mobility Spectrometry” - ISBN: 9781138199484 (CRC Press 2016), - 444 pages.

A. M. Ellis and C. A. Mayhew “Proton Transfer Reaction Mass Spectrometry: Principles and Applications - ISBN: 978-1-4051-7668-2 (Wiley 2014)” 350 pages.

Univ.-Prof. Dr. Christopher A. Mayhew

Type/Hours: ECTS-AP:  5

Link to University Course

Mode of repetition: semestral

Language of instruction: English

Learning Outcome:

To introduce state-of-the-art soft chemical ionisation mass spectrometric (SCIMS) techniques, namely; Proton Transfer Reaction – Time-of-Flight – Mass Spectrometry (PTR-ToF-MS), Selected Ion Flow Tube – Mass Spectrometry (SIFT-MS) and Ion Mobility Spectrometry (IMS)

Compare SCIMS to more standard mass spectrometric analytical techniques including the “gold-standard” of analytical chemistry; namely Gas Chromatography – Mass Spectrometry (GC-MS) – advantages and disadvantages

To provide a framework for gaining a knowledge and an understanding on the use of reagent ions as sensitive and selective analytical probes for use in many areas of analytical chemistry – interdisciplinary and intersectoral perspectives

Comparison of SCIMS to more standard mass spectrometric analytical techniques including the “gold-standard” of analytical chemistry; namely Gas Chromatography – Mass Spectrometry (GC-MS) – advantages and disadvantages

To provide a major practical hands-on research project within the Institute for Breath Research using state-of-the-art PTR-MS instruments – students will become proficient in using PTR-MS and in the analysis of the mass spectrometric data obtained:
- putting the context of the lectures into real-world applications
- gaining experience of working in a research environment (team and independent work)
- gaining skills in the use of using state-of-the-art soft chemical ionisation mass spectrometric and analysis techniques (An Ionicon Analytik GmbH PTR-TOF 6000 X2)
- developing experimental, critical thinking and analytical skills
- gaining experience in writing and presenting scientific reports

Contents:

1. Lecture Material
Analytical performance of a SCIMS instrument-Ions as Sensitive Analytical Probes to the Environment

Accuracy and precision, Sensitivity, Limits of detection, Mass accuracy, Selectivity, Use of ion-molecule reaction rate coefficients to determine compound concentration

Principles of Proton Transfer Reaction Mass Spectrometry

Non-dissociative and dissociative proton transfer, Operational principles, Soft ionisation versus electron impact ionisation, Determining concentrations, Selectivity

Proton Transfer Reaction Mass Spectrometry and the Reduced Electric Field

Residence times, Mean drift velocities, Collisional energies (Wannier equation) and effective temperatures, Sensitivity, Limits of detection

Proton Transfer Reaction Mass Spectrometry: Improving Selectivity and Response Time

Selectivity of PTR-MS – methods employed to improve selectivity, Response Time of Measurements with PTR-MS – changing reagent ions, Latest PTR-MS developments

Selected Ion Flow Tube Mass Spectrometry (SIFT-MS)

Operational principles, Determining absolute rate coefficients, Use in trace gas analysis – commercialisation of SIFT-MS, Advantages and disadvantages of SIFT-MS

Ion Mobility Spectrometry (IMS)–Principles and Methods

Operational principles, Mobility coefficient, Mean drift velocity, Reagent ion peak, IMS spectra, Ionisation sources, IMS-MS, Applications of IMS, Advantages and disadvantages of IMS

Ion Mobility Spectrometry (IMS)-Positive Ion Mode

Reagent ion formation, Applications (CWAs and Drugs)

Ion Mobility Spectrometry (IMS)-Negative Ion Mode

Reagent ion formation, Applications (Explosives), Electron attachment investigations – IMS and swarm measurements

IMS and Improved Selectivity

Dopants, GC-IMS, Collisional Induced Dissociation, High Kinetic Energy Ion Mobility Spectrometry

Soft Chemical Ionisation Mass Spectrometry and Atmospheric Chemistry

The biosphere, Plant studies and influences on the atmosphere, Chamber studies, Emission monitoring, Biomass burning, Airborne and shipborne measurements

Soft Chemical Ionisation Mass Spectrometry and Food Science

Mass spectral fingerprinting, Flavour release and perception, Food classification, Food freshness and ripening

Soft Chemical Ionisation Mass Spectrometry and Homeland Security

Thermal desorption PTR-MS, Explosive detection with PTR-MS

Soft Chemical Ionisation Mass Spectrometry and Health Sciences

Breath analysis, Urine analysis, Skin emanations, Endogenous verses exogenous volatile sources, PTR-MS and breath research, Volatiles and breath tests in clinical practice

Electronic Sensors–Future Directions

Chemical recognition by chemical gas sensors

2. Research Project (5 days)–Applications of PTR-MS to Breath Analysis
Extensive training on the operation of the state-of-the-art PTR-ToF-MS (an Ionicon Analytik GmbH PTR-TOF 6000 X2) and analyses of data.

Measure the breath concentrations (VMRs) of key volatiles in breath, Calculate the breath concentrations and compare to measured values, Investigate temporal changes of breath volatile concentrations (pharmacokinetics)

Methods:

Lectures and Experimental Work (taught in English)

To provide a series of tutorial style lectures drawing together and developing concepts from various disciplines (e.g. chemistry, physics, and biosciences) and different subjects (e.g. quantum mechanics, plasma physics, statistical mechanics, and electromagnetism) to describe the applications of ion-molecule processes for use in gas-phase analytical chemistry. 

Assessment: written

Literature:

  • G.A. Eiceman, Z. Karpas, H. H. Hill „Ion Mobility Spectrometry” - ISBN: 9781138199484 (CRC Press 2016), - 444 pages.
  • A. M. Ellis and C. A. Mayhew “Proton Transfer Reaction Mass Spectrometry: Principles and Applications - ISBN: 978-1-4051-7668-2 (Wiley 2014)” 350 pages.

Requirements:
VO Fundamentals of Chemical Ionisation Mass Spectrometry

Link to University Course

Priv.-Doz. Dr. Rania Bakry
Univ.-Prof. Dr. Christopher A. Mayhew
LV 740239
Type/Hours: ECTS-AP: 1,5         

Period: Block

Mode of repetition: annually

Language of instruction: German

Mode of repetition: semestral

Learning Outcome:

Basic understanding of the principles and applications of “Forensic Toxicology” with a special emphasis on techniques and workflows used for the extraction and confirmation of illegal drugs in casework samples.

Contents:

Introduction to “Forensic Toxicology”. Discussion of the principles of state-of-the-art analytical techniques (GC-MS, LC-MS). Analysis of casework samples (seized drugs, human samples). Interpretation of analytical results.

Methods:

Introduction to “Forensic Toxicology” including a detailed discussion of important analytical techniques. Presentation of applications. Practical exercise of drug analysis workflows. Discussion and interpretation of analytical results.

Assessment:

Cooperation, interest and activity during the course, report on practical work and presentation of experimental results.

Literature:

Will be discussed in the first lesion.

Remarks:

Subject to alteration.

Language: German/English

Start: 5.10.2023

Time, location: Practical course: Monday 08.01.2024 / Friday 02.02.2024, tbd

Link to University Course

Assistant Prof. Dr. Veronika Ruzsanyi,
Sven Arne Philipp Schiller, BSc, MSc, PhD.,
Valentina Stock, MSc.                                                                                                               
Typ/Stunden: PR 5
ECTS-AP: 5

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

The students achieve a profound knowledge about current analytical techniques. They are able to establish analytical methods for selected problems on their own and to interpret analytical data correctly.

Contents:

literature research in order to find a suitable procedure for a given analytical problem, samples selected from the fields of environmental, bio-, food , polymer and industrial analysis, different sample preparations and application of chromatography, spectroscopy, electrochemistry, and hyphenated techniques,data evaluation and comparison of different analytical methods

Methods:

practical lab course in small groups

Assessment:

successful accomplishment of the experimental tasks; final lab journal

Literature:

Harris, Lehrbuch der Quantitativen Analyse, Springer 2002; Skoog, West, Holler, Fundamentals of Analytical Chemistry, Saunders 1992Skoog, Leary, Principles of Instrumental Analysis, Saunders 1992Kellner (HSG) Analytical Chemistry, Wiley 2004Camman, Instrumentelle Analytische Chemie, Spektrum 2001

Remarks:

Registration via LFU:online is obligatory! Comment: conditions for admission according to curriculum apply!

Link to University Course

Assistant Prof. Dr. Veronika Ruzsanyi
Typ/Stunden: VO1
ECTS-AP: 1

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

Students achieve a profound knowledge about different measurement principles in sensor technology

Contents:

Basic measurement principles and applications of different types of sensors (electrochemical sensors, different types of gas sensors, biosensors, optical sensors, modern developments such as field effect transistors, sensor arrays, miniaturisation)

Methods: blackboard, transparencies, pc-presentation

Assessment: oral

Literature:

  • Brian R. Eggins, Chemical Sensors and Biosensors, Wiley 2002.
  • K. Camman (Edt.) Instrumentelle Analytische Chemie, Spektrum 2001
  • Harris, Lehrbuch der Quantitativen Analyse, Springer 2002

Remarks:

Start: 2. Half of Semester, Separate Announcement

Registration for the Course obligatory in order to obtain course documents

Link zur Lehrveranstaltung

Assistenz-Prof. Dr. Veronika Ruzsanyi,
Franziska Maria Lochmann, MSc,

Typ/Stunden: PR4
ECTS-AP: 5

Wiederholungsturnus: jährlich

Unterrichtssprache: Deutsch

Lernergebnis:

Die Studierenden erwerben grundlegende Kenntnisse der Probenvorbereitung und der Instrumentalanalytik. Die Studierenden sind in der Lage, Messdaten richtig auszuwerten und zu interpretieren. Die Studierenden erwerben fachübergreifende Schlüsselkompetenzen in Teamfähigkeit sowie mündlicher und schriftlicher Kommunikationsfähigkeit.

Inhalt:

Vermittlung von Grundkenntnissen in der Probenvorbereitung und der instrumentellen Analytik, Anwendung der HPLC, GC, Voltammetrie, Extraktionsverfahren, UV/VIS-Spektroskopie, Atomspektroskopie (AAS und FES) zur Analyse von Realproben.

Methoden:

praktischer Kurs im Labor in kleinen Gruppen

Anmerkungen:

verpflichtende Anmeldung über LFU:online!! Anm.: die Zulassungsvoraussetzungen lt. Studienplan müssen erfüllt sein!

Link to University Course

Assistant Prof. Dr. Veronika Ruzsanyi,
Anesu Andrew Chawaguta, MSc,
Franziska Maria Lochmann, MSc,
Typ/Stunden: PR4
ECTS-AP: 5

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

The students are taught basic skills in sample preparation, gravimetric analysis and titration. They are able to interpret analytical data correctly. The Students achieve key skills in communication and working together in teams.

Contents:

Fundamental operations and handling of chemicals in analytical chemistry measurement of volume and mass, precipitation, filtration, digestion, ignition) gravimetric and volumetric analysis (neutralization, complex-formation, redox titrations) potentiometric and photometric endpoint detection, conductivity titration) pH- measurement of buffers, statistical evaluation of analytical data

Methods:

practical course in the laboratory

Assessment:

practical, written (or oral) intermediate and final examinations

Literature:

  • Jander, Jahr, Maßanalyse, Gruyter 2002
  • Mortimer, Basiswissen der Chemie, Thieme Harris, Lehrbuch der Quantitativen Analyse, Springer 2002
  • Skoog, West, Holler, Fundamentals of Analytical Chemistry, Saunders 1992
  • Vogel's Textbook of Quantitative, Inorganic Analysis, Longman
  • Kunze, Schwedt, Grundlagen der qualitative und quantitativen Analyse (Thieme 1996)
  • Müller, Quantitativ-Anorganisches Praktikum, Deutsch-Thun Verlag 1992

Remarks:

Registration via LFU:online is obligatory! Comment: conditions for admission according to curriculum apply!

Link to University Course

Assistant Prof. Dr. Veronika Ruzsanyi
Typ/Stunden: VO2
ECTS-AP: 2,5

Period: Block

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

To assess and describe the limit values and health hazards of air pollutants.

To carry out sampling techniques and sample preparation for gas analysis, including sample enrichment.

To understand and describe various analysis and detection methods such as gas chromatography, mass spectrometry, ion-molecule reaction in the gas phase, and ion mobility spectrometry, including the use of gas sensors for flue gas analysis, breath gas analysis, food industry, workplace monitoring, toxic gases, explosives, and metabolomics.

Contents:

Air pollutants (origin, limit values, health hazards), sampling techniques, sample preparation, sample enrichment in classical gas analytics, gas chromatography, detection methods, on-line/off-line analytics, mass spectrometry, ion-molecule reaction in the gas phase, ion mobility spectrometry, gas sensors, applications (flue gas analysis, breath gas analysis, food industry, workplace monitoring, toxic gases, explosives, metabolomics).

Methods:

Class with practical examples

Assessment:

written exam

Link to University Course

Sven Arne Philipp Schiller, BSc, MSc, PhD.
Typ/Stunden: SE2
ECTS-AP: 2,5

Mode of repetition: every 2nd year

Language of instruction: English

Learning Outcome:

Students are able to find, read and understand scientific literature in a time-efficient manner. Based on this and their own investigations, students are able to independently author scientific texts and thus communicate the ideas behind their research.

Contents:

The seminar is focused on the various components involved in the process of drafting a scientific manuscript, such as the search for relevant literature as well as the reading, understanding and evaluation of scientific publications. The acquired knowledge and skills will be reinforced and practiced by students during the seminar in short exercises. As a conclusion to the seminar, students will draft a short seminar paper demonstrating what they have learned.

Methods:

PowerPoint presentation, discussion, exercises, short presentations (students), seminar paper

Assessment:

Participation in the seminar, seminar paper

Literature: to be announced

Prerequisites: none

Remarks: none

Link to University Course

Emma Erharter
Andreas Mair, BSc
Sven Arne Philipp Schiller, BSc, MSc, PhD.
Dipl.-Ing. Dr. Peter Thoman, Bakk.
Mirte Van der Eyden, MSc


Typ/Stunden: VU3
ECTS-AP: 3

Course number: 702010

Period: Block

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

The bridge course mathematics is recommended to first year students in the Bachelor's programmes Technical Mathematics and School Teacher Training Mathematics. The bridge course offers support for first year students to ease the transition from school to university.

Contents:

In the bridge course mathematics, basic mathematical concept are presented in forms of lectures and exercises.

Privacy notice: course will be recorded

Start: see dates

Link to University Course

Anesu Andrew Chawaguta, MSc,
assoz. Prof. Mag. Dr. Markus Ganzera,
David Glänzer, MSc
Mag. Thomas Hasenöhrl
Alessandro Marotto, MSc
Mag. Dr. Lisa Schwaiger
Mag. David Seher, BSc
Ferenc Török, MSc
Mag. Lorenz Waltl                                                                                                                                                                                                                                           

Typ/Stunden: UE 4
ECTS-AP: 4

Period: Block

Mode of repetition: annually

Language of instruction: German

Learning Outcome:

The students have knowledge on important compendial monographs related to Pharmacognosy, also considering sampling and sample preparation, and they are able to conduct respective protocols using relevant analytical and separation techniques.

Contents:

Practical application of the regulations and general methods discussed in the lecture, with a focus on procedures relevant to pharmacognosy (determination of ash, key figures of fatty oils, etc.)

Methods: Laboratory course

Assessment: Oral examination during course as well as evaluation of rendered results

Literature:

  • Europäisches Arzneibuch
  • Österreichisches Arzneibuch
  • Pharmakognosie-Phytopharmazie (Hänsel, Sticher; Springer Verlag, Heidelberg)
  • Analytik biogener Arzneistoffe (Adam, Becker; Wissenschaftliche Verlagsgesellschaft, Stuttgart)
  • Instrumentelle pharmazeutische Analytik (Rücker, Neugebauer, Willems; Wissenschaftliche Verlagsgesellschaft, Stuttgart)

Remarks: Subject to alteration.

Start: 02.10.2023

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