Type: 
University
Region: 
Wielkopolskie
Programme: 
Physics
Area: 
Science
Level: 
Master's Programme
Mode of studies: 
full-time programme
Duration: 
2 years
Tuition fee: 
Registration: 85 PLN Tuition fee per semester: 1,500 PLN
Degree awarded: 
MA
Scholarships available: 
Stipends for students from different regions are available through The Polish National Agency for Academic Exchange – NAWA programs (https://nawa.gov.pl/en/). Limited number of stipends will be available within the individual projects of supervisors.
Application deadline: 
Monday, 12 July, 2021
Language: 
EN
Day of semester start: 
Friday, 1 October, 2021
Credits (ECTS): 
120
Admission requirements: 


Preliminary requirements (candidate’s qualifications):
Undergraduate degree in science, natural sciences or technology. English language skills are required.
Ranking will be based on: 
The interview in the English language in the subject related to the field of study (in justified cases the conversation can be via an instant messenger).
 

Description: 

MASTER OF SCIENCE IN PHYSICS of ADVANCED MATERIALS for ENERGY PROCESSING - PAMEP

The subject matter of the program is closely tied to Physics of New Materials which currently have been applied or have its potential application in energy generation, conversion, storage and saving.

 

The goal of this program is to equip students with technical expertise necessary for an academic career (postgraduate degree studies) or a career in private sector corporations which strictly rely on detailed knowledge of scientific research (for instance, companies involved in research, producing or servicing advanced measuring tools and companies interacting with both science and the industry).

Classes offered are strictly connected to Physics (for instance, solid state physics, thermodynamics, magnetism) but also combined Physics and Chemistry (for instance: photovoltaics, solar energy, soft matter, crystallography), Physics and Biology (for instance: artificial photosynthesis, bionanostructures) and Physics and Nanomaterial Engineering (for instance: conducting nanostructures, one- and two-dimensional materials).

Students familiarize themselves not only with theories but also with experimental methods of materials research.

Additionally, they participate in specialized courses exploring the advanced modern material characterization techniques (for instance: electron and atomic force microscopy, optical spectroscopy, X-ray spectroscopy, Raman spectroscopy, NMR spectroscopy, time-resolved laser spectroscopy, neutron scattering), material fabrication (for instance, lithography, thin film deposition, chemical methods) and theoretical computation or computer simulation methods applied in materials physics.

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