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Schwerpunktfach Advanced Processes (AP focal)15.0 ECTS (englische Bezeichnung: Focal subject Advanced Processes)
Modulverantwortliche/r: Tanja Franken Lehrende:
Hannsjörg Freund, Leonid Datsevich, Hans-Joachim Egelhaaf, Detlef Freitag, Matthias Thommes, Tanja Franken, Andreas Bück, Malte Kaspereit, Markus Kaiser
Startsemester: |
SS 2020 | Dauer: |
2 Semester | Turnus: |
halbjährlich (WS+SS) |
Präsenzzeit: |
150 Std. | Eigenstudium: |
300 Std. | Sprache: |
Englisch |
Lehrveranstaltungen:
In the third MAP semester (WS),the lecture "Catalysis" is obligatory. In addition, one of the following two lectures with the respective exercises has to be chosen:
Adsorption: Fundamentals and Application
or
Drying Technology
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Thin films: processing, characterization and functionalities. (SS 2020)
(Vorlesung, 1 SWS, Hans-Joachim Egelhaaf, Mo, 12:15 - 13:45, Raum n.V.; ab 27.4.2020; Vorbesprechung: 21.4.2020, 14:00 - 15:00 Uhr)
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Reactors (SS 2020)
(Vorlesung, 1 SWS, Leonid Datsevich, Mo, 10:15 - 11:45, 0.85; ab 18.5.2020)
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Process Technologies (SS 2020)
(Vorlesung, 2 SWS, Hannsjörg Freund et al., Di, 14:15 - 15:45, EE 0.135)
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Process Technologies Exercises (SS 2020)
(Übung, 1 SWS, Markus Kaiser et al., Fr, 10:15 - 11:45, KS II)
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Catalysis (WS 2020/2021)
(Vorlesung, 2 SWS, Tanja Franken, Do, 10:15 - 11:45, 0.85; Registration via StudOn required: https://www.studon.fau.de/crs3399990.html)
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Adsorption: Fundamentals and Applications (WS 2020/2021 - optional)
(Vorlesung, 2 SWS, Matthias Thommes, Mi, 16:15 - 17:45, 04.019)
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Trocknungstechnik/Drying Technology (WS 2020/2021 - optional)
(Vorlesung, Andreas Bück, Mi, 08:15 - 09:45, KS II; Seminar Raum LFG 0.332 - Cauerstraße 4, 91058 Erlangen)
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Empfohlene Voraussetzungen:
basics in physical chemistry
Inhalt:
Reactors:
divergence of a real reactor from an ideal one
safety aspects
multiphase catalysis: problems and solutions
examples of industrial development: three-phase reactors
Process Technologies:
The course “Process Technologies” gives an overview on important processes in the chemical process industries. The processes are treated in a holistic approach and the interaction of individual process steps and their feedback to the overall process are discussed in more detail. In particular, the relationship between the physical/chemical basics of the processes, process development and process design will be discussed. The presented processes are selected based on their importance in the fields of raw materials, intermediates and consumer products of the chemical process industries. In the sense of process engineering, apart from the reaction steps, the separation operations are also part of the considerations. The evaluation of the methods with regard to their cost-effectiveness and sustainability complete the description of the processes. In detail, the following aspects will be treated:
Raw materials (crude oil, fuels, natural gas, technical gases)
Organic base chemicals (syngas, alkanes, alkenes, aromatics)
Organic intermediates (C1-C4 alcohols, cyclic alcohols, ether, epoxides, organic acids)
Renewable raw materials
Organic end products (surfactants, pigments, polymers)
Inorganic base chemicals and intermediates (sulfuric acid, ammonia, sodium hydroxide)
Inorganic end products (fertilizers, ceramics, glass)
Process development (technologies, economic evaluation)
Thin films:
overview on passive materials in organic electronics (substrates, dielectrics, packaging and encapsulation materials)
dielectric properties, barrier properties, optical properties
major thin film fabrication processes (gas phase and solution based)
printing (gravure, ink-jet, doctor blading) techniques and conditions
composition of inks, thin film homogeneity and thickness control
deposition of patterned features
molecular self-assembly (molecular scale fabrication, applications).
The Catalysis lecture covers
Homogeneous catalysis
Fluid/fluid biphasic catalysis
Hatta number and enhancement
Advanced solvents for catalyst immobilization
Heterogeneous catalysis
Deriving reaction rate approaches for surface catalyzed reactions
Reactors to determine kinetics of reaction and mass transfer
Mass transfer coefficient correlations
Mass transfer influences on selectivity
Mass transfer in fluidized beds
Models to describe residence time distributions
Catalyst characterization
Chemical energy storage
Adsorption: Fundamentals and Applications
1. Introduction and terminology
2. Gas adsorptions basics and adsorbent materials
3. Physisorption mechanisms
4. Surface area determination
5. Porosity and pore structure analysis of nanoporous materials
5.1 Micropore analysis
5.2 Mesopore analysis
5.3 Macropore analysis : adsorption and liquid intrusion methods
5.4. Characterization of hierarchically structured porous materials
6. High pressure adsorption
7. Surface chemistry effects on adsorption
8. Adsorption and characterization in the liquid phase
8. Adsorption of mixtures
9. Adsorption applications in gas storage and separation
Lernziele und Kompetenzen:
Students who successfully participate in this module can define different types of chemical reaction and reactor
differentiate between steady-state and transient reactor operation
evaluate the differences between idea and real reactors
assess aspects of safety of chemical reactors
define challenges and solutions for multiphase reactors
describe the importance of thin film technologies to modern (opto)electronic devices
define principal gas and solution-based thin film fabrication technologies, especially printing techniques
evaluate the composition of printing inks and characteristics and quality of printed layers
explain how thin films can be patterned
understand the role of emerging thin film technologies such as molecular self-assembly Students who successfully participate in this module can
explain the material, technological and developmental aspects of chemical processes
understand the fundamentals of both homogeneous and heterogeneous catalysis
analyze and evaluate the general mechanisms in catalysis
describe and critically asses the interplay between mass transport and chemical reaction
apply immobilization techniques for homogeneous catalysts
transfer their knowledge about chemical reactors regarding influences on catalytic processes
Studien-/Prüfungsleistungen:
Advanced Processes 1: Process Technologies, Reactors and Thin Films (Prüfungsnummer: 1801)
(englischer Titel: Advanced Processes 1: Separation Processes, Reactors and Thin Films)
- Prüfungsleistung, schriftlich oder mündlich, benotet, 7.5 ECTS
- Anteil an der Berechnung der Modulnote: 50.0 %
- weitere Erläuterungen:
either oral exam 45 minutes or written exam 120 minutes
- Prüfungssprache: Englisch
- Erstablegung: SS 2020, 1. Wdh.: WS 2020/2021
1. Prüfer: | Robin N. Klupp Taylor |
- Termin: 15.10.2020
Termin: 01.04.2021, 08:00 Uhr
Advanced Processes 2a: Catalysis and Adsorption und Advanced Processes (Prüfungsnummer: 1802)
(englischer Titel: Advanced Processes 2: Process Technology and Catalysis)
- Prüfungsleistung, schriftlich oder mündlich, benotet, 7.5 ECTS
- Anteil an der Berechnung der Modulnote: 50.0 %
- weitere Erläuterungen:
either oral exam 45 minutes or written exam 120 minutes
- Prüfungssprache: Englisch
- Erstablegung: WS 2020/2021, 1. Wdh.: SS 2021
Advanced Processes 2b: Catalysis and Drying Technology (Prüfungsnummer: 1803)
(englischer Titel: Advanced Processes 1: Separation Processes, Reactors and Thin Films)
- Prüfungsleistung, schriftlich oder mündlich, benotet, 7.5 ECTS
- Anteil an der Berechnung der Modulnote: 50.0 %
- weitere Erläuterungen:
either oral exam 45 minutes or written exam 120 minutes
- Prüfungssprache: Englisch
- Erstablegung: WS 2020/2021, 1. Wdh.: SS 2021
- Termin: 22.07.2021
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