Nanomaterials and Nanotechnology 1 (Nano1)6 ECTS
(englische Bezeichnung: Nanomaterials and Nanotechnology 1)
(Prüfungsordnungsmodul: Schwerpunktfach Nanomaterials and Nanotechnology 1)

Lehrveranstaltungen:

• • Advanced High Temperature Alloys
    (Vorlesung, 1 SWS, Uwe Glatzel, Einzeltermine am 29.6.2017, 6.7.2017, 10:00 - 15:00, 0.02-142; Block seminars in Erlangen, plus day trip to Bayreuth, dates and place will be announced by MAP office)
  • Nanotechnology of Disperse Systems
    (Vorlesung, 2 SWS, Robin N. Klupp Taylor et al., Mi, 14:15 - 15:45, H14)
  • Selbstorganisation an Oberflächen
    (Vorlesung, 2 SWS, Marcus Halik, Di, 12:15 - 13:45, 1.84)

Inhalt:

Nanotechnology of Disperse Systems: This module begins with a revision of basic topics in the theory of nucleation, growth and electrostatic stabilization of particulate materials. Following this the challenges and solutions to the problem of metal, oxide, semiconductor and polymer particle synthesis will be discussed. The second half of the course will concern the characterisation, properties and application of disperse systems. In addition to understanding the measurement of particle and agglomerate size and shape, the factors affecting the electronic, magnetic, optical and catalytic properties will be covered. Particles are often applied as part of a hierarchical system e.g. in a device, functional coating, drug delivery system. The use of self-assembly and printing/patterning techniques to achieve these goals will be presented with reference to work carried out within the Erlangen Cluster of Excellence "Engineering of Advanced Materials – Hierarchical Structure Formation for Functional Devices”. For the associated "Exercises” participants of the course will be required to explore the literature and give a 10 minute presentation regarding recent developments in a specific aspect of disperse systems or nanoparticle research.
Processing and Functionality of Organic Electronic Devices: • The lecture provides basics in materials properties of -conjugated systems (C-allotropes, polymers, small molecules) with emphasis on electrical and optical properties on different scales (molecular, thin film, bulk). • General approaches in device processing – in particular thin films – will be discussed (solution based and gas phase deposition). Solution based processes focus on different printing techniques and self-assembly methods, during gas phase processes highlight complex evaporation techniques. Additionally, patterning methods are discussed. • In the largest part, the main devices based on organic materials are introduced (field effect transistors, OLED, OPV, memory) with focus on device functionality, materials, processing and integration to complex functionality. Market potential and limitations of the organic electronics will be discussed on examples.
High Temperature Alloys: 1. Introduction, Basics 2. Stability of Microstructure 3. Mechanical Properties a) Static b) Cyclic (Fatigue) 4. High Temperature Corrosion 5. High Temperature Alloys 6. Lost Wax Investment Casting 7. Depending on Time: Lectures on a) SX Ni-Base Superalloys b) LEK 94 c) Pt-Base Superalloys

Lernziele und Kompetenzen:

Nanotechnology and Disperse Systems: The lecture enables the students to gain an overview of key themes of nanoparticle research and application as well as the underlying fundamentals.
Processing and Functionality of Organic Electronic Devices: The lecture enables the students to detailed understanding of structure-property-relations of functional p-systems on different scales (nano to m2). Knowledge of hierarchical structure formation as key concept in device fabrication is provided. The students learn the basic components in organic electronics – their potential and limits, and how to fabricate such devices.
High Temperature Alloys: The lecture enables the students to achieve knowledge on high temperature deformation mechanisms (diffusion, dislocation glide and climb) and deterioration mechanisms (HT corroision). Information on mechanical testing techniques (creep deformation).

Literatur:

• “Organic Electronics – Materials, Manufacturing and Applications” edited by Hagen Klauk, Wiley-VCH (2006) ISBN: 3-527-31264-1

• “Organic Electronics II - More Materials and Applications” edited by Hagen Klauk, Wiley-VCH (2012) ISBN: 3-527-32647-2
  

Superalloys, R.C. Reed

• Superalloys, A Technical Guide, M.J. Donachie + S.J. Donachie

• Handbuch Hochtemperaturwerkstofftechnik, R. Bürgel

Verwendbarkeit des Moduls / Einpassung in den Musterstudienplan:

1. Advanced Materials and Processes (Master of Science with Honours)
   (Po-Vers. 2014w | TechFak | Advanced Materials and Processes (Master of Science with Honours) | Masterprüfung | Schwerpunktfächer | Schwerpunktfach Nanomaterials and Nanotechnology 1)

Studien-/Prüfungsleistungen:

Nanotechnology of Disperse Systems (Prüfungsnummer: 1906)

Untertitel: Review

Prüfungsleistung, Hausarbeit, benotet, 3.5 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Robin N. Klupp Taylor

Termin: 28.07.2017, Ort: Prof. Klupp Taylor Office (2nd floor, Haberstr. 9a)

Advanced High Temperature Alloys (Prüfungsnummer: 1908)

Untertitel: Oral exam

Prüfungsleistung, mündliche Prüfung, Dauer (in Minuten): 10, benotet, 1 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Mathias Göken

Nanotechnology of Disperse Systems (Prüfungsnummer: 1906)

Untertitel: Oral exam

Prüfungsleistung, mündliche Prüfung, Dauer (in Minuten): 20, benotet, 3.5 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Robin N. Klupp Taylor

Termin: 28.07.2017, Ort: Prof. Klupp Taylor Office (2nd floor, Haberstr. 9a)

Advanced High Temperature Alloys (Prüfungsnummer: 1908)

(englischer Titel: Advanced High Temperature Alloys)

Prüfungsleistung, Hausarbeit, benotet, 1 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

weitere Erläuterungen:
Anteil an der Berechnung der Modulnote: 25%

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Mathias Göken

Self Assembly on Surfaces (Prüfungsnummer: 1909)

(englischer Titel: Self Assembly on Surfaces)

Prüfungsleistung, mündliche Prüfung, Dauer (in Minuten): 10, benotet, 1.5 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Marcus Halik

Self Assembly on Surfaces (Prüfungsnummer: 1909)

(englischer Titel: Self Assembly on Surfaces)

Prüfungsleistung, Hausarbeit, benotet, 1.5 ECTS

Anteil an der Berechnung der Modulnote: 0.0 %

Prüfungssprache: Englisch

Erstablegung: SS 2017, 1. Wdh.: WS 2017/2018

1. Prüfer:

Marcus Halik