STUDENTS SKILLS

Characteristics of Graduate

Graduates of the Physics Bachelor program in KSU should be able to:

1.0 Knowledge

PLO1.1: Define the most fundamental concepts, principles and terminology of physics.

PLO1.2: Recognize appropriate tools and techniques that may be used to solve the problems they will face.

PLO 1.3: Describe and comment on different methodologies in physics.

2.0 Cognitive Skills

PLO 2.1: Apply their knowledge and understanding to solve qualitative and quantitative problems of a familiar and unfamiliar nature.

PLO 2.2: Execute and analyse critically the results of an experimental investigation and draw valid conclusions.

PLO 2.3: Construct their experimental work to investigate some aspect of a problem.

3.0 Interpersonal Skills & Responsibility

PLO 3.1: Learn independently.

PLO 3.2: Work as a team.

PLO 3.3: Acknowledge others' work.

PLO 3.4: Be self-discipline.

4.0: Communication, Information Technology, Numerical

PLO 4.1: Search in web sites.

PLO 4.2: Calculate and interpret the results using computer programs.

5.0: Psychomotor

PLO 5.1: Operates and uses equipment/tools/machinery appropriately.

PLO 5.2: Takes precise and accurate measurements.

Skills and Abilities of Graduate Physics Program:

Raise his skills and experience in dealing with scientific issues and problems and how to try to understand them through his experiences in dealing with physical problems.
Identify the importance and use of photovoltaic devices and their applications in multiple fields.
Understanding the daily applications of most physical phenomena in our daily lives and how to interpret them.
Understand and explain the basic concepts of semiconductors and electronics and develop skills in the scientific fields of electronics theoretically and practically.
Understanding recent developments in the fields of atomic physics, quantum mechanics and nuclear physics both theoretically and practically.
Physical properties of basic materials, laws and theories that govern the physics of solids and crystalline structures and their applications in materials science.
Linking the theoretical and practical aspects in the fields of materials science and physics of solids and how to deal with laboratory devices used in the study of materials physics.
Development of skills in the areas of monitoring, measurement, observation and recording of outputs accurately and analyze by extracting the most important results -Writing, presenting and explaining reports.
The connection between physical theories and their applications in practical aspects.
Increase research and laboratory skills and work in research teams.
The ability to define concepts, definitions, symbols, mathematical tools and the language of classical and dynamic Newtonian mechanics.
Building the relationship between the theories of physics and ideas with students' in everyday life applications.
Application of the basics of classical and modern physics and familiarity with physical phenomena and their interpretations based on physical concepts.
Understand the basic pillars of electromagnetic phenomena.
Interpretation of applications of daily life in the field of electromagnetic phenomena.
Analysis of electrical systems - current and frequency behavior.
Knowledge of dealing with Unix or Linux and some statistical programs.
Learn how to analyze, model and solve mathematical equations using computer programs.
Experience of basic principles in laser science.
Understanding basic principles in quantum theory.
Identification of the atomic spectra and their origin.
Study the properties of nuclei and isotopes in nature.
A thorough study of nuclear particles and their physical properties.
Knowledge of many nuclear reactions and the way they are written.
Know the types of sources of nuclear radiation and means of protection against radiation risk.
Understand the process of producing nuclear energy by fission and nuclear fusion.
Application of physical concepts to basic astronomical phenomena.

College of sience

Skills and Abilities of Graduate Physics Program:

Raise his skills and experience in dealing with scientific issues and problems and how to try to understand them through his experiences in dealing with physical problems.

Identify the importance and use of photovoltaic devices and their applications in multiple fields.

Understanding the daily applications of most physical phenomena in our daily lives and how to interpret them.

Understand and explain the basic concepts of semiconductors and electronics and develop skills in the scientific fields of electronics theoretically and practically.

Understanding recent developments in the fields of atomic physics, quantum mechanics and nuclear physics both theoretically and practically.

Physical properties of basic materials, laws and theories that govern the physics of solids and crystalline structures and their applications in materials science.

Linking the theoretical and practical aspects in the fields of materials science and physics of solids and how to deal with laboratory devices used in the study of materials physics.

Development of skills in the areas of monitoring, measurement, observation and recording of outputs accurately and analyze by extracting the most important results -Writing, presenting and explaining reports.

The connection between physical theories and their applications in practical aspects.

Increase research and laboratory skills and work in research teams.

The ability to define concepts, definitions, symbols, mathematical tools and the language of classical and dynamic Newtonian mechanics.

Building the relationship between the theories of physics and ideas with students' in everyday life applications.

Application of the basics of classical and modern physics and familiarity with physical phenomena and their interpretations based on physical concepts.

Understand the basic pillars of electromagnetic phenomena.

Interpretation of applications of daily life in the field of electromagnetic phenomena.

Analysis of electrical systems - current and frequency behavior.

Knowledge of dealing with Unix or Linux and some statistical programs.

Learn how to analyze, model and solve mathematical equations using computer programs.

Experience of basic principles in laser science.

Understanding basic principles in quantum theory.

Identification of the atomic spectra and their origin.

Study the properties of nuclei and isotopes in nature.

A thorough study of nuclear particles and their physical properties.

Knowledge of many nuclear reactions and the way they are written.

Know the types of sources of nuclear radiation and means of protection against radiation risk.

Understand the process of producing nuclear energy by fission and nuclear fusion.

Application of physical concepts to basic astronomical phenomena.

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