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Introduction to Wave Phenomena in Nature - enhanced
Cursusdoel
After completing this course students are able to:
- describe the different types of wave phenomena in mechanics, electromagnetism and in the (atomic) quantum world, as well as the properties of the medium that supports them;
- calculate the propagation of a wave and its reflection and transmission at the boundary between two media;
- solve simple problems involving wave phenomena such as dispersion, refraction, the Doppler effect and polarisation, and give examples of them from daily experiences;
- explain and calculate the patterns (visual or auditive) produced by the interference and diffraction of waves;
- a) describe practical applications of wave phenomena, such as, in instruments for precision measurements, visualisation of, otherwise, not-visible environments, i.e. the interior of human body and underground structures, as well as topography and astronomy;
b) Enhanced format: demonstrate analytical problem-solving skills and more fundamental understanding related to practical applications of wave phenomena as described in a) - explain the evidence and nature of the particle-wave duality of matter at microscopic atomic scales in quantum mechanics, and how it relates to Heisenberg uncertainty relations;
- solve the one dimension wave equation in quantum mechanics for simple systems including the finite potential well and the harmonic oscillator;
- explain the probabilistic interpretation of waves in quantum mechanics and illustrate how this applies to simple systems and infer the possibility of the ``ghostly’’ phenomenon of tunneling.
| Description of assignment | Assesses course aims: |
| Mid-term exam Assignments Exercises Portfolio Final exam |
1, 2, 3, 5 b) 1, 2, 3, 4, 6, 7, 8 5 b), 7, 8 4, 6, 7, 8 |
Vakinhoudelijk
The course is offered in two formats, standard with code UCSCIPHY13, and enhanced with code UCSCIPHY14. The enhanced course format is compulsory for Physics Double Degree students.
The main difference is in learning goal 5, which is either assessed through an essay (PHY13) or through a more extensive and in-depth excersises portfolio (PHY14).
In this course you are introduced to several types of wave phenomena in nature. Three main types of waves are studied: mechanical waves (as in air, fluids and solids), electromagnetic waves (as in light and radio waves), and quantum mechanical waves. Waves of several types are used in many scanning devises used in medicine and earth sciences for instance, and most of the technology in telecommunications common in our households uses electromagnetic waves.
Several properties and phenomena associated with waves (such as longitudinal and transverse wave modes, polarisation, dispersion, reflection, transmission and interference) are studied during the first two-thirds of this course and several applications are discussed. In the final third, you are introduced to the wave-duality nature of matter at the atomic and sub-atomic scales, and to the probabilistic interpretation of quantum mechanical waves, one of the cornerstones of modern physics .In this enhanced course format you work in more detail on the aspects of the physics behind these applications, by developing more analytical problem-solving skills and studying the physics more in-depth. You write a portfolio on the problems/applications you are assigned to work on.
Format
In this course you are introduced to several types of wave phenomena in nature. Three main types of waves are studied: mechanical waves (as in air, fluids and solids), electromagnetic waves (as in light and radio waves), and quantum mechanical waves. Waves of several types are used in many scanning devises used in medicine and earth sciences for instance, and most of the technology in telecommunications common in our households uses electromagnetic waves.
Several properties and phenomena associated with waves (such as longitudinal and transverse wave modes, polarisation, dispersion, reflection, transmission and interference) are studied during the first two-thirds of this course and several applications are discussed. In the final third, you are introduced to the wave-duality nature of matter at the atomic and sub-atomic scales, and to the probabilistic interpretation of quantum mechanical waves, one of the cornerstones of modern physics .In this enhanced course format you work in more detail on the aspects of the physics behind these applications, by developing more analytical problem-solving skills and studying the physics more in-depth. You write a portfolio on the problems/applications you are assigned to work on.
The course consists of four weekly contact hours, over 15 weeks, which are equally divided between interactive lectures and problem solving tutorial sessions.
For each lecture and tutorial you have to read and work through assigned material. This includes completing assignments from the teaching and learning platform MasteringPhysics, and explore the properties of waves by using virtual simulations of wave phenomena (https://phet.colorado.edu/en/simulations/category/physics). With this approach more time is used during class on discussing and understanding the subtleties of physical concepts necessary for concept-based problem solving, and less time is given to simple lecturer-to-students transfer of knowledge and ideas. When relevant the discussions are carried out in the context of real applications. Outside the four class hours a week, students are expected to study 10 hours a week on average on this course.
For each lecture and tutorial you have to read and work through assigned material. This includes completing assignments from the teaching and learning platform MasteringPhysics, and explore the properties of waves by using virtual simulations of wave phenomena (https://phet.colorado.edu/en/simulations/category/physics). With this approach more time is used during class on discussing and understanding the subtleties of physical concepts necessary for concept-based problem solving, and less time is given to simple lecturer-to-students transfer of knowledge and ideas. When relevant the discussions are carried out in the context of real applications. Outside the four class hours a week, students are expected to study 10 hours a week on average on this course.
Werkvormen
UCU SCI 1 course
Toetsing
assessment
Verplicht | Weging 20% | ECTS 1,5
assessment
Verplicht | Weging 15% | ECTS 1,13
*midterm FEEDBACK*
Niet verplicht
assessment
Verplicht | Weging 30% | ECTS 2,25
assessment
Verplicht | Weging 35% | ECTS 2,63
Ingangseisen en voorkennis
Ingangseisen
Er moet voldaan zijn aan de cursus:
- [SEE_BELOW]
Voorkennis
Students who do not satisfy the above requirement need to apply for course admittance. Secondary school knowledge of physics and mathematics is required. For physics this requires an IB Higher Level Physics, VWO “Natuurkunde”, or similar courses in physics from a foreign secondary school. For mathematics this requires an IB Higher Level Maths, Dutch VWO “Wiskunde B”, or similar “Calculus and Algebra” courses from a foreign secondary school.
Voertalen
- Engels
Competenties
-
Academisch schrijven
Cursusmomenten
Gerelateerde studies
Tentamens
Er is geen tentamenrooster beschikbaar voor deze cursus
Verplicht materiaal
| Materiaal | Omschrijving |
|---|---|
| BOEK | Hugh D. Young and Roger A. Freedman, University Physics with Modern Physics, with Mastering Physics, 15th Global Edition. ISNB: 9781292314952* *this ISBN contains the specific course materials selected by your instructor at a premium discount. |
| DIVERSE | The book includes an access code to MasteringPhysics |
| BOEK | Freely available online book: The Physics of Waves, by Howard Georgi originally published by Prentice Hall. |
Aanbevolen materiaal
Er is geen informatie over de aanbevolen literatuur bekend
Opmerkingen
Two formats are offered: UCSCIPHY13, and for DDLP students UCSCIPHY14. Pre-enrolment for both courses in UCSCIPHY13.
Coördinator
| dr. F.M. Freire | F.Freire@uu.nl |
Docenten
| dr. F.M. Freire | F.Freire@uu.nl |
| prof. dr. P. van der Straten | p.vanderstraten@uu.nl |
Inschrijving
Let op: deze cursus is niet toegankelijk voor studenten van andere faculteiten, bijvakkers mogen zich dus niet inschrijven.
Inschrijving niet via OSIRIS
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