SYLLABUS
COURSE TITLE
FACULTY/INSTITUTE
SPECTROSCOPY LABORATORY
FACULTY OF MATHEMATICS AND NATURAL
SCIENCES
COURSE CODE
DEGREE PROGRAMME
FIELD OF STUDY
DEGREE LEVEL
FORMA
MODE
ENGINEERIG PHYSICS
BACHELOR
STATIONARY
COURSE FORMAT
YEAR AND SEMESTER
NAME OF THE TEACHER
STUDIÓW/STUDY
3RD YEAR, 6TH SEMESTER
DR IZABELA PIOTROWSKA
COURSE OBJECTIVES
 TO FAMILIARIZE STUDENTS WITH PRACTICAL AND THEORETICAL BASIS OF THE MOST
IMPORTANT SPECTROSCOPIC METHODS AND DEVICES
PREREQUISITES
 KNOWLEDGE AND SKILLS IN THE FIELD OF LASERS,
OPTICS AND MODERN PHYSICS
KNOWLEDGE:
LEARNING OUTCOMES
 HAS GENERAL KNOWLEDGE ESSENTIAL FOR
UNDERSTANDING
PHYSICAL
PHENOMENA
CONNECTED WITH LASER ACTION AND X-RAYS;
K_W01
 UNDERSTANDS AND CAN EXPLAIN PHYSICAL RULES,
PHENOMENA
AND
PROCESSES
USING
MATHEMATICAL LANGUAGE, IS ABLE TO RECALL
FUNDAMENTAL LAWS AND THEOREMS IN PHYSICS;
K_W03
 KNOWS BASIC ASPECTS OF STRUCTURE AND ACTION
OF APPARATUS IN PHYSICS; K_W05
 KNOWS PRINCIPLES OF WORK SAFETY REGULATIONS;
K_W06
SKILLS:
 CAN ANALYSE PROBLEMS AND SOLVE THEM USING
KNOWN THEOREMS AND METHODS; K_U01
 IS ABLE TO PLAN AND CARRY OUT SIMPLE
EXPERIMENTS OR OBSERVATIONS AND ANALYSE
THEIR RESULTS; K_U03
 CAN LEARN SINGLE-HANDEDLY; K_U07
 HAS AN ABILITY OF PREPARING ESSAYS AND
PRESENTATIONS IN POLISH AND IN ENGLISH USING
DIFFERENT SOURCES; K_U08, K_U09
FINAL COURSE OUTPUT - SOCIAL COMPETENCES
 UNDERSTANDS A LIFE-LONG LEARNING IDEA; NK_K01
 CAN COOPERATE IN GROUP, ACTING DIFFERENT
ROLES; K_K02
 CAN DETERMINE THE PRIORITIES TO FULFILL SPECIFIC
TASKS; K_K03
 UNDERSTANDS
THE
NEED
OF
IMPROVING
PROFFESSIONAL AND PERSONAL SKILLS; K_K05
COURSE ORGANISATION –LEARNING FORMAT AND NUMBER OF HOURS
LABS: 60 H
COURSE DESCRIPTION
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NON-RELATIVISTIC HYDROGEN ATOM
COMPLETE SET OF 'GOOD QUANTUM NUMBERS'
MANY-ELECTRON ATOM
PERTURBATIVE TREATMENT OF THE SPIN-ORBIT INTERACTION
EFFECTS OF APPLIED ELECTROMAGNETIC FIELDS, HYPERFINE STRUCTURE.
THE SEMICLASSICAL FORMALISM OF THE THEORY OF RADIATION BASED ON FIRST
ORDER TIME-DEPENDENT PERTURBATION THEORY
EINSTEIN'S A AND B COEFFICIENTS
COUPLING OF ANGULAR MOMENTA
SPECTROSCOPIC TERMS AND COMPLEX ATOMIC SPECTRA
BORN APPROXIMATION
RELATIVISTIC HYDROGEN ATOM
DIRAC EQUATION
CONSERVATION LAWS IN ATOMIC PHYSICS
MOLECULAR STRUCTURE
ELECTRONIC, ROTATIONAL, VIBRATIONAL AND RO-VIBRATIONAL SPECTRA OF
MOLECULES
FRAGMENTATION DYNAMICS OF MOLECULES
POTENTIAL ENERGY SURFACE
METHODS OF INSTRUCTION
REQUIREMENTS AND ASSESSMENTS
GRADING SYSTEM
TOTAL STUDENT WORKLOAD
NEEDED TO ACHIEVE EXPECTED
LEARNING OUTCOMES EXPRESSED
IN TIME AND ECTS CREDIT POINTS
LANGUAGE OF INSTRUCTION
INTERNSHIP
MATERIALS
WORKING IN GROUPS
STUDENTS ARE RESPONSIBLE FOR THEIR OWN
LEARNING. STUDENTS ARE REQUIRED TO READ A
CHAPTER IN THE TEXTBOOK BEFORE THE CLASS
WHERE IT WILL BE DISCUSSED.
CONTINUOUS ASSESSMENTS.
TUTORIAL WORK AND ATTENDANCE (5%)
LAB REPORTS (95%)
LABS: 60 H
LABS PREPARATION: 25 H
INDIVIDUAL TUTORIALS: 5 H
TOTAL: 90 H
ECTS: 3
ENGLISH
PRIMARY OR REQUIRED BOOKS/READINGS:
 HALLIDAY, RESNICK, WALKER
“FUNDAMENTALS OF PHYSICS”
 MANSFIELD, O’SULLIVAN “UNDERSTANDING
PHYSICS”
 DEMTRÖDER, „ATOMS, MOLECULES AND
PHOTONS: AN INTRODUCTION TO ATOMIC-,
MOLECULAR- AND QUANTUM-PHYSICS“
 SVANBERG „ ATOMIC AND MOLECULAR
SPECTROSCOPY“
 HOLLAS „MODERN SPECTROSCOPY“
SUPPLEMENTAL OR OPTIONAL BOOKS/READINGS: