Main field(s) of study and in-depth level:
Renewable Energy Production A1N,
Energy Technology A1N,
Explanation of codes
The code indicates the education cycle and in-depth level of the course in relation to other courses within the same main field of study according to the requirements for general degrees:
G1N: has only upper-secondary level entry requirements
G1F: has less than 60 credits in first-cycle course/s as entry requirements
G1E: contains specially designed degree project for Higher Education Diploma
G2F: has at least 60 credits in first-cycle course/s as entry requirements
G2E: has at least 60 credits in first-cycle course/s as entry requirements, contains degree project for Bachelor of Arts/Bachelor of Science
GXX: in-depth level of the course cannot be classified.
A1N: has only first-cycle course/s as entry requirements
A1F: has second-cycle course/s as entry requirements
A1E: contains degree project for Master of Arts/Master of Science (60 credits)
A2E: contains degree project for Master of Arts/Master of Science (120 credits)
AXX: in-depth level of the course cannot be classified.
Fail (U), Pass (3), Pass with credit (4), Pass with distinction (5)
The Faculty Board of Science and Technology
120 credits within Science/Technology including Electromagnetism, Power Engineering, Energy System Physics/Modern Physics.
Department of Materials Science and Engineering
On completion of the course, the student should be able to:
explain the technical and physical principles of solar cells,
measure and evaluate different solar cell technologies and relate these to underlying theory,
calculate the required size of solar cell systems from a given power demand by using appropriate calculations and simulation software,
communicate technical and socioeconomic issues of solar energy in a concise and comprehensible way by using poster presentations, Power Point or similar, in English.
Solar radiation: Properties of sunlight. Absorption by the atmosphere. Calculation of solar irradiance at surfaces. Solar cells and modules: The function of solar cells from semiconductor physics. Different solar cell technologies and fabrication methods. Concepts for increasing efficiency based on loss analysis. Wavelength sensitivity. Series connection of solar cells to modules. Module function and characteristics. Shading of cells and modules. Solar cell systems: System components and their functions. Calculating output and dimensioning of solar cell systems. Analysis and computer simulation of a solar cell system. Concentrated sunlight and solar power (CSP): Properties of optical concentration systems. Solar cells in concentrated sunlight. Overview of the different components in a CSP system and their functions. Examples of CSP-systems globally. Active solar energy in systems: How large scale deployment of active solar cell energy is possible in Sweden and globally. Buying and selling electric energy. Grid aspects of large scale deployment of solar cells.
Lectures and seminars. The seminars can be in the form of lessons or discussion sessions. Study visit. Laboratory exercises and computer simulations.
Oral presentation of group task and written examination at the end of the course (4 credits). Lab exercises and computer simulation sessions (1 credt).
If there are special reasons for doing so, an examiner may make an exception from the method of assessment indicated and allow a student to be assessed by another method. An example of special reasons might be a certificate regarding special pedagogical support from the disability coordinator of the university.
The course may not be included in the same degree as 1TE028 Solar Energy - Technology and Systems, or 1TE206 Solar Energy - Technology and Systems.