University master's degrees
University Master's Degree in Applied Nanoscience: From Materials to Devices New

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Official Master's Degree in Applied Nanoscience: From Materials to Devices

Study guides

Degree obtained:

Applied Nanoscience: From Materials to Devices

Teaching timetable

Timetable

Study plan structure

 

  Compulsory Optional Final Project Work Placement
First Year 12 24 15 9
Totals 12 24 15 9

Compulsory training

First semester
  • 45721 - From Materials to Devices: Advanced Synthetic and Integration Methods
Second Semester
  • 45717 - Professional Skills in Nanoscience: From Lab to Society
  • 45748 - Work Placement
  • 45749 - Master's Degree Dissertation
  

Optional subjects

  • 45737 - Machine Learning and Artificial Intelligence: Application to Materials' Discovery ( 3 credits )
  • 45740 - First-Principles Computations: Applications for Physics and Chemistry ( 3 credits )
  • 45742 - (Bio) Sensing and Transducing at the Nanoscale
  • 45745 - Wearable and Molecular-Based Electronic Devices ( 3 credits )
  • 45744 - Nanoelectronic Devices ( 3 credits )
  • 45722 - Core Enabling Tools in Nanoscience
  • 45743 - Quantum Materials for Devices ( 3 credits )
  • 45741 - Sustainable Energy Materials
  • 45735 - Imaging and Spectroscopy at the Atomic Scale ( 3 credits )
  • 45738 - Multi-scale Modelling: Macroscopic Analysis with Finite Elements ( 3 credits )
  • 45736 - Advanced Nanofabrication ( 3 credits )
  • 45746 - Nature-Inspired Functional Nanomaterials ( 3 credits )
  • 45747 - Nanomaterials for Theranostics ( 3 credits )
  • 45739 - Soft Matter Simulation: Application to Bio-nanomaterials ( 3 credits )
  • 45734 - Advanced Diffraction and Spectroscopy Techniques ( 3 credits )

(1) Some students coming from degrees in Biochemistry or Biomedical Engineering may need to take and pass additional training courses. The Master’s Committee will evaluate each case individually during the assessment and tutoring process, determining whether or not these additional courses are required. For further details, please refer to Annex 1.1 on tutoring.
Two options are proposed that will allow students from the “Bio” field, who require it, to acquire a foundation in fundamental aspects of quantum mechanics, as well as surface physics and chemistry, within the framework of nanoscience, without imposing an excessive mathematical load.
The additional training courses for the master’s program for students coming from these degrees will, if necessary, amount to a maximum of 12 ECTS and will consist of the following compulsory subjects from the Nanoscience and Nanotechnology degree at UAB.

All subjects are worth 6 credits unless otherwise stated.
All optional subjects are not scheduled each year.