KJM1500 Physical Chemistry Course description

The students shall acquire knowledge of thermodynamics and kinetics. In addition, the course shall provide students with basic knowledge of radioactivity and coordination chemistry.

Passed laboratory course in KJPE1300 General Chemistry.

After completing the course, the student is expected to have achieved the following learning outcomes defined in terms of knowledge, skills and general competence:

Knowledge

The student:

• is capable of defining and carrying out calculations of energy, work and heat
• is capable of explaining and carrying out calculations of enthalpy (H), entropy (S), and Gibbs free energy (G), for different processes
• is capable of deriving and carrying out calculations of the connection between equilibrium constants, temperature and thermodynamic values
• is capable of explaining and calculating phase equilibria/ phase diagrams
• is capable of defining and carrying out calculations of colligative properties
• is capable of deriving connections between electrochemistry and thermodynamic values
• is capable of deciding a reaction order and performing kinetic calculations
• has basic knowledge of energy and energy transfer in different systems, knowledge of colligative properties and phase equilibria
• has basic knowledge of radioactivity
• has basic knowledge of transition metal and coordination compounds

Skills

The student:

• can collaborate in groups both with practical and written work
• have insight into the proper handling of chemicals on the basis of safety data sheets and from laboratory experience

General competence

The student:

• can perform thermodynamic measurements for different processes and phase transitions
• can derive some equations in thermodynamics, chemical equilibrium and phase equilibrium, electrochemistry and reaction kinetics
• can plot and outline phase diagrams
• can use Nernst equation and emf measurements in calculations
• can solve simple rate laws as differential equations and use the expressions further in calculations

The teaching is organised as lectures, exercises and demonstration of laboratory equipment

The following coursework is compulsory and must be approved before the student can sit the exam:

• 8 compulsory exercises (2-4 hours per exercise)
• 1 laboratory exercise with Lab report (2 -5 pages)

Individual written exam, 3 hours.

The exam result can be appealed.

In the event of a resit or rescheduled exam, oral examination may be used instead of written. If oral exams are used for resit and rescheduled exams, the exam result cannot be appealed.

On completion of the course, the students will have gained an understanding of the electrical properties of linear circuits and how basic circuits can be designed based on specifications. The course also gives a basic introduction to electromagnetics and confers 3 credits in physics.

No requirements over and above the admission requirements.

After completing the course, the student is expected to have achieved the following learning outcomes defined in terms of knowledge, skills and general competence:

Knowledge

The student is capable of:

• solving basic dc and ac circuits
• have a good knowledge of the physical laws that apply to electrical circuits
• can account for electric and magnetic fields
• have a good knowledge of methods for analyzing DC circuits
• analysing transient states in RL and RC circuits
• analysing inverting and non-inverting circuit solutions using operational amplifiers
• knowing the basic structure of electric motors and generators
• have knowledge of three-phase systems

Skills

The student is capable of:

• using instruments such as a voltmeter, ammeter and oscilloscope
• designing circuits based on diagrams and troubleshooting hardware if necessary
• explaining the function(s) of a circuit
• using manufacturer manuals and data sheets

General competence

The student is capable of:

• analysing a problem and specifying a solution method
• discussing and justifying own choices and priorities in relation to electric circuits
• explaining the historical development of the field of electricity

Theory lectures, laboratory work, company visits and a large-scale project carried out in project groups. The goal of the project is to give the students insight into what type of tools and methods engineers use to illustrate and show results.