Profile of the Program

The aim of the Energy Systems Operation and Technologies Master's Program is to educate students as highly motivated, socially responsible energy systems engineers who have the ability to deal with energy-related engineering problems creatively at theoretical and practical levels using the critical thinking and scientific analysis methods in both the national and the world-wide context.

Qualification Awarded

The students who successfully complete the program are awarded the degree of Bachelor of Science

Level of Qualification

This is a program.

Specific Admission Requirements

Anyone who graduates from a related engineering department of any university is eligible to apply for this program. While evaluating the applicants, the following criteria will be taken into account: the applicant's ALES grade, English language grade (from an exam recognized by our university) and Bachelor's level graduation CGPA.

Qualification Requirements and Regulations

The students studying in this undergraduate program are required to have a Cumulative Grade Points Average (Cum.GPA) of not less than 3.00/4.00 and have completed all the courses with at least a letter grade of C/S in the program in order to graduate. The minimum number of ECTS credits required for graduation is 240.

Recognition of Prior Learning

At Bahcesehir University , full-time students can be exempted from some courses within the framework of the related by laws. If the content of the course previously taken in another institution is equivalent to the course offered at BAU, then the student can be exempted from this course with the approval of the related faculty/graduate school after the evaluation of the course content.

Occupational Profiles of Graduates

Graduates of this program can work on a variety of fields such as energy production, transmission, distribution as well as energy planning and investment analysis, energy economics and management, or energy conservation and efficiency. No students have graduated from our program yet.

Access to Further Studies

The students graduating from this program may apply to third cycle (doctorate degree) programmes.

Program Outcomes

1 Have sufficient theoretical background in mathematics, basic sciences and other related engineering areas and to be able to use this background in the field of energy systems engineering.
2 Be able to identify, formulate and solve energy systems engineering-related problems by using state-of-the-art methods, techniques and equipment.
3 Be able to design and do simulation and/or experiment, collect and analyze data and interpret the results.
4 Be able to access information, to do research and use databases and other information sources.
5 Have an aptitude, capability and inclination for life-long learning.
6 Be able to take responsibility for him/herself and for colleagues and employees to solve unpredicted complex problems encountered in practice individually or as a group member.
7 Develop an understanding of professional and ethical responsibility.
8 Develop an ability to apply the fundamentals of engineering mathematics and sciences into the field of energy conversion.
9 Develop an understanding of the obligations for implementing sustainable engineering solutions.
10 Develop an ability to design a system, component, or process to meet desired needs within realistic constraints such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability
11 Realize all steps of a thesis or a project work, such as literature survey, method developing and implementation, classification and discussion of the results, etc.

Course & Program Outcomes Matrix

No Effect 1 Lowest 2 Low 3 Average 4 High 5 Highest
Program Outcomes 1 2 3 4 5 6 7 8 9 10 11
EEE5101 Research Methods and Ethics
ESE5301 Energy Production Technologies 3 4 2 3 3 3 1 5 2 2
ESE5401 Power Systems Analysis 5 5 5 3 3 3 2 4 3 4
ESE5501 Energy Management 2 2 2 3 3 3 4 1 3 4
ESE5887 Seminar
ESE5888-1 Master Thesis
ESE5888-2 Thesis
Departmental Elective
EEE5012 Numerical Methods in Engineering
ENM5112 Project Management
ENM5128 Financial Literacy for Executives
ENM5201 Advanced Engineering Management
ENM5211 Technology Management
ENM5227 Risk Management
ENM5231 Strategic Management
ESE5303 Renewable Energy Sources in Fuel Production
ESE5502 Sustainable Energy Systems
ESE5504 Implementation of Oil and Gas Markets
INE5111 Mathematical Programming and Modelling
MAT5101 Engineering Mathematics
MCH5613 Introduction to Wind Energy Engineering

Course Structure Diagram with Credits

1. Semester
Course Code Course Name Prerequisites Theoretical Practical Credit ECTS
ESE5301 Energy Production Technologies 3 0 3 8
ESE5401 Power Systems Analysis 3 0 3 8
ESE5501 Energy Management 3 0 3 8
Departmental Elective 3 6
Total 30
2. Semester
Course Code Course Name Prerequisites Theoretical Practical Credit ECTS
EEE5101 Research Methods and Ethics 3 0 3 9
ESE5887 Seminar 0 0 0 10
Departmental Elective 3 8
Departmental Elective 3 8
Departmental Elective 3 8
Total 43
3. Semester
Course Code Course Name Prerequisites Theoretical Practical Credit ECTS
ESE5888-1 Master Thesis 0 0 0 20
Total 20
4. Semester
Course Code Course Name Prerequisites Theoretical Practical Credit ECTS
ESE5888-2 Thesis 0 0 0 30
Total 30

Program Director (or Equivalent)


Program Coordinator

Telephone: +90