de | en

Prof. Dr. Aliaksandr Bandarenka

Photo von Prof. Dr. Aliaksandr S. Bandarenka
Phone
+49 89 289-12531
Room
PH: 3093
E-Mail
bandarenka@ph.tum.de
Links
Homepage
Page in TUMonline
Group
Physics of Energy Conversion and Storage
Job Title
Professorship on Physics of Energy Conversion and Storage

Courses and Dates

Title and Module Assignment
ArtSWSLecturer(s)Dates
Energy Materials 2
eLearning course
Assigned to modules:
VO 2 Bandarenka, A. Fri, 14:00–16:00, PH 2271
Electrified Solid/Liquid Interfaces: from Theory to Applications
Assigned to modules:
HS 1 Bandarenka, A. Mon, 14:00–16:00, PH II 227
Energy Materials 2
This course is not assigned to a module.
HS 2 Bandarenka, A. Fri, 10:00–12:00, PH 3734
and singular or moved dates
Electrified Interfaces and Catalysis
Assigned to modules:
SE 2 Bandarenka, A. Wed, 13:00–15:00, PH 3076
and singular or moved dates
FOPRA Experiment 22: Laser-Induced Current Transient Technique
Assigned to modules:
PR 1 Bandarenka, A.
Assisstants: DIng, X.
Mentoring in the Bachelor's Program Physics (Professors A–J)
Assigned to modules:
KO 0.2 Auwärter, W. Back, C. Bandarenka, A. Barth, J. Bausch, A. … (insgesamt 22)
Responsible/Coordination: Höffer von Loewenfeld, P.
Revision Course to Energy Materials 2
This course is not assigned to a module.
RE 2
Responsible/Coordination: Bandarenka, A.

Offered Bachelor’s or Master’s Theses Topics

All Solid State Batteries
An ever increasing demand for high density energy storage has led to the evolution of All Solid State Batteries (ASSB). While the concept of a solid ion conductors has been around for decades, the field of ASSB is relatively new. With novel materials, the ionic conductivity matches that of liquid electrolytes. However, a major challenge remains to be understood and solved: the electrode/electrolyte interface. Involving two different solid materials, this interface is subject to mechanical stress, material decomposition and electrochemical processes. In this work, this interface will be investigated through electrochemical experiments. Not only will you perform measurements on state-of-the-art equipment on various material systems but the physical modelling of the underlying physics-chemical processes will give you an insight into the various time domains involved. After initial literature research, a thorough introduction into our methods and to the experimental setups involved, the electrochemical model will be refined in an iterative procedure. Supporting the electrochemical model by other experimental and theoretical means will also be a part of your work.
suitable as
  • Master’s Thesis Condensed Matter Physics
  • Master’s Thesis Applied and Engineering Physics
Supervisor: Aliaksandr Bandarenka
Aqueous Sodium Ion Batteries

Energy storage technologies are an indispensable element of the transition towards an eco-friendly society. Due to their low cost, scalability and non-flammability,  rechargeable aqueous sodium ion batteries are a promising candidate for stationary applications, ranging from photovoltaic-powered private households to large scale grid power buffers. This experimental bachelor thesis will aim at understanding, characterizing and optimizing intercalation-type battery electrodes. The student will contribute to the investigation of fabrication methods, electrode substrates, active material composition, self-discharge and lifetime. The project will involve literature research, experimental training in a chemical laboratory and hands-on working on battery electrodes and electrolytes and thereby learning standard battery fabrication and characterization methods.

suitable as
  • Master’s Thesis Condensed Matter Physics
  • Master’s Thesis Applied and Engineering Physics
Supervisor: Aliaksandr Bandarenka
Top of page