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2020/2021

Physics II

Code: 105036 ECTS Credits: 6
Degree Type Year Semester
2502444 Chemistry FB 1 2
The proposed teaching and assessment methodology that appear in the guide may be subject to changes as a result of the restrictions to face-to-face class attendance imposed by the health authorities.

Contact

Name:
Antonio Perez-Calero Yzquierdo
Email:
Antonio.PerezCalero@uab.cat

Use of Languages

Principal working language:
spanish (spa)
Some groups entirely in English:
No
Some groups entirely in Catalan:
No
Some groups entirely in Spanish:
Yes

Teachers

Jorge Carretero Palacios

Prerequisites

There are no official pre-requisites. However, it is assumed that students have aquired the basic knowlegde in Physics and Mathematics taught during last years of High School. For those students who have not followed Physics during last years High School it is highly recommendeded to enroll the propedeutic course of Physics gave by the Physics department during the first two weeks of September. There is also the possibility of enrolling the propedeutic course of Mathematics also gave by the Physics department.

Objectives and Contextualisation

The aim of this course is that students know the basic principles of Nature, from the smallest (atomic nucleus and elementary particles) to the largest (planets and stars), and also that students will be able to apply them and describe physical phenomena in a quantitative and qualitative way. Students will learn the necessary tools to understand the material's structure, concepts, principles and research exploration in Chemistry. Also, students will aquire the critical thinking and to aquire new knowledge in an autonomous way.

Competences

  • Adapt to new situations.
  • Apply knowledge of chemistry to problem solving of a quantitative or qualitative nature in familiar and professional fields.
  • Communicate orally and in writing in one’s own language.
  • Have numerical calculation skills.
  • Learn autonomously.
  • Manage, analyse and synthesise information.
  • Obtain information, including by digital means.
  • Propose creative ideas and solutions.
  • Reason in a critical manner
  • Resolve problems and make decisions.
  • Show an understanding of the basic concepts, principles, theories and facts of the different areas of chemistry.
  • Work in a team and show concern for interpersonal relations at work.

Learning Outcomes

  1. Adapt to new situations.
  2. Apply knowledge of physics to solve chemistry problems.
  3. Communicate orally and in writing in one’s own language.
  4. Describe the concepts, principles and theories of physics to understand and interpret the structure of matter and the nature of chemical processes.
  5. Have numerical calculation skills.
  6. Learn autonomously.
  7. Manage, analyse and synthesise information.
  8. Obtain information, including by digital means.
  9. Propose creative ideas and solutions.
  10. Reason in a critical manner
  11. Resolve problems and make decisions.
  12. Work in a team and show concern for interpersonal relations at work.

Content

Waves (I). Waves in motion

1. Introduction
2. Wave pulses
3. Harmonic waves
4. Velocity of propagation
5. Energy of a wave
6. Doppler effect

Waves (II). Interferences

1. Interfetence of waves
2. Standing waves
3. Thin-film interference
4. Bragg difraction
5. Young experiment
6. Difraction grating
7. Difraction

Electrostatic field. Capacitors

1. Electric field
2. Gauss theorem. Applications
3. Electric dipole
4. Capacitors

Electric current

1. Current intensity
2. Ohm's law. Electric resistance
3. Batteries. Electromotive force
4. Resistance combinations
5. Direct Current Circuits
6. Charge and discharge of a capacitor

Magnetic field

1. Motion of a charged particles in a magnetic field
2. Magnetic force on a current-carrying conductor
3. Magnetic field sources
4. Ampère's circuital law
5. Magnetic induction. Faraday-Lenz law
6. Magnetism in matter

Alternating current circuits

1. Simple circuits
2. Current intensity in series AC circuits. Electrical impedance
3. Series RLC circuit as an oscillator. Resonance.

Electromagnetism

1. Maxwell's equations
2. Electromagnetic radiation
3. Optics: nature of light
4. Properties of light (reflexion, refraction and polization)

Methodology

The course consists of two types of guided activities, theoretical classes and problem classes, which are distributed throughout the course in an approximate ratio of 3 to 1.

Theory lectures

Professors will lecture on the contents of the course mainly in the blackboard and with support from multimedia material, which will be available for students in the Campus Virtual. In order to profit theory lectures to the maximum, students should prepare the sessions in advance making use of such material and the bibliography. Moreover, students will be encouraged to explore deeper aspects of the topics being studied by means of additional material (websites, videos, applets, etc) to be found also in the Campus Virtual. Professors will in some cases support the theory with some practical examples. Student participation in the lectures is highly encouraged.

Practice lectures

Professors will resolve practical exercises from the list that will be provided via the Campus Virtual. Students should work on the exercises prior to the practice session, in order to ensure participation and discussion on doubts or alternative solutions that students may have found.  

Activities

Title Hours ECTS Learning Outcomes
Type: Directed      
Practical cases lectures 13 0.52 2, 3, 4, 7, 8, 9, 10, 11, 5
Theory lectures 36 1.44 2, 6, 3, 4, 7, 10
Type: Autonomous      
Individual study and exercises 50 2 2, 6, 3, 4, 7, 8, 9, 10, 11, 5
Team work 26 1.04 2, 3, 4, 7, 8, 9, 10, 11, 5, 12

Assessment

Continuous assessment

The teaching and evaluation of this course will be based on the concept of continuous assessment. The emphasis is therefore placed on the continuous work by students, as well as on providing them with tools that allow the assessment of their level of acquisition of the skills and contents of the course. For this purpose, activities such as questionnaires on theoretical concepts, class activities, delivery of advanced problems, etc. will be carried out. These activities will also serve as evidence of the work done and for the student's grade.

The content of the subject will be taught in two blocks separated by the first evaluation period by Easter. Passing the course requires passing both blocks separately. For this, a sufficient degree of achievement and progress must be demonstrated by the student in each block.

Qualification

In each block there will be a partial exam that together with the continuous evaluation activities will determine your grade. The grade of each block will be calculated as follows: 80% exam grade + 20% continuous assessment activities.

  • The student's continued work activities will be evaluated according to their degree of compliance and quality. Failure to complete the activities or to deliver them in general with a very poor result will imply a zero in this category.
  • To pass a block, the exam grade must be equal to or greater than 4.

The final grade for the course is obtained as the average of the grades from both blocks passed separately.

Supplementary exam:

In the event that the student does not pass one or both blocks, they will have the option of taking a supplementary exam covering the content of the failed block or blocks. In order to participate in this second chance exam, the student must have participated in continuous assessment activities that equal two thirds of the total grade.

Improving grades:

Students may take the supplementary exam also in order to improve the course grade. The grade that the students have already achieved on the content on which they want to be reexamined will be in any case reetained.

 Not evaluable

The student who has not submitted to the second partial or to the recovery exam is considered Non-evaluable.

On exams:

To attend any of the exams it is essential to carry an identification document (ID or university card).

Using unauthorized methods during one of the exams of the subject (copying or communicating with a classmate, use of mobile phones, use of smart watches, etc.) will be penalized with a final failure grade in the subject for the current academic year.

Assessment Activities

Title Weighting Hours ECTS Learning Outcomes
Continuous assessment activities 20% 16 0.64 1, 2, 6, 3, 4, 7, 8, 9, 10, 11, 5, 12
Partial exams 80% 9 0.36 1, 2, 3, 4, 7, 9, 10, 11, 5

Bibliography

Theory:

P. A. Tipler y G. Mosca. Física. Reverté. Barcelona. (2010, 6ª ed.)
D. E. Roller, R. Blum. Mecánica, Ondas y Termodinámica (vol. 1).Reverté. Barcelona (1986)
F. W. Sears, M.W. Zemansky, H.D. Young. Física universitaria. Addison-Wesley (1986)

Exercises:

S. Burbano de Ercilla, E. Burbano García, G. Diaz de Villegas Blasco. Física general: problemas. Tébar 27ª ed. (1991).
F. A. González. La física en problemas. Madrid, Tebar-Flores (1997)
J. Aguilar Peris, J. Casanova Col. Problemas de Física General. 4ª ed. Madrid, editorial Alhambra (1981)
D. Jou, J.E. Llebot, C. Pérez-García. Física para las ciencias de la vida. McGraw-Hill (2009, 2ª ed.)

Additional Material: 

To be found in the subject's Campus Virtual.