Degree | Type | Year |
---|---|---|
2504235 Science, Technology and Humanities | OB | 2 |
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There are none.
The general objective of this subject is to offer students a basic knowledge to understand the structure of the matter and its relationship with its physical and chemical properties, and settle the knowledge that allow them understanding the fundamental role of Chemistry as basic science and the benefits that the advances in this discipline have provided to society. Specifically, students will study concepts related to atomic structure, periodical properties of elements, chemical bond theories, molecular structure and molecular interactions resulting in different forms of matter aggregation. Next, they will study the concept of chemical reactivity and the ability of substances to transform. Finally, those concepts will be contextualized concerning some key aspects of the 21st century Chemistry and the challenges it faces.
I – Atomic structure and properties
-Atomic models: from Dalton to Quantum Mechanics.
-Periodic table of elements and electronic structure.
-Nucleus structure and nuclear processes.
II – Molecules and molecular compounds
-Chemical bond, intermolecular forces and aggregation states.
-Physicochemical properties of the matter.
-Levels of organisation of matter and molecular complexity.
III – Structure of solids
-Structure of crystalline solids.
-Materials and their properties.
-Description and structural determination by conventional and advanced methods.
IV – Chemical reactions
-Introduction to chemical reactivity-types of reactions.
-Energy and velocity of chemical processes.
-Catalysis – Industrial, environmental and biological processes relevance.
V – Current challenges of Chemistry
-Current applications of advanced materials in nanotechnology.
-Climate change and sustainability. Environmental aspects of Chemistry.
-Chemical aspects of biotechnology and its applications.
Title | Hours | ECTS | Learning Outcomes |
---|---|---|---|
Type: Directed | |||
Learning exercises | 16 | 0.64 | 1 |
Lectures | 33 | 1.32 | 2, 3, 5, 6, 7 |
Type: Supervised | |||
Essay supervision | 4.25 | 0.17 | 1, 4 |
Type: Autonomous | |||
Personal study | 75 | 3 | 1, 2, 3, 5, 6, 7 |
Project preparation | 15.75 | 0.63 | 4 |
Lectures.
Practical exercises both in lecture room and in the laboratory.
Project preparation and oral presentation.
Annotation: Within the schedule set by the centre or degree programme, 15 minutes of one class will be reserved for students to evaluate their lecturers and their courses or modules through questionnaires.
Title | Weighting | Hours | ECTS | Learning Outcomes |
---|---|---|---|---|
Final exam | 30% | 2 | 0.08 | 2, 3, 5, 6, 7 |
Intermediate test | 30% | 2 | 0.08 | 2, 3, 5, 6, 7 |
Practices | 15% | 1 | 0.04 | 1, 3, 4, 6 |
Project | 25% | 1 | 0.04 | 1, 4 |
During the course, four practices will be carried out. Each student will deliver a report after each practice. 15% of the final grade in the subject will correspond to the work done during the practices and the reports delivered.
In the middle of the semester a written test will take place, intermediate exam, in which the knowledge of the part of the contents seen up to that moment will be evaluated - blocks I and II. 30% of the final grade in the subject will correspond to the evaluation of these contents.
At the end of the semester a second written test will be carried out by the students, final exam, in which the knowledge of the second part of the subject will be evaluated - blocks III and IV. 30% of the final grade in the subject will correspond to the evaluation of these contents.
Throughout the semester, the students will develop a project on a topical issue related to the subject, which will correspond mainly to block V. At the end of the semester, they will carry out a presentation followed by a debate with the whole group about their project. 25% of the final grade in the subject will correspond to the manuscript, presentation and discussion in the debate of the project.
In the recovery exam, the grade for the practicals and the project will be maintained. Students will have the opportunity to recover some of the parts assessed in written tests (mid-term exam and final exam) that they have failed (with a grade lower than 5/10) maintaining the percentage in the assessment.
In order for a student to pass the course, he/she must have satisfactorily participated in the continuous assessment tests: practicals and project.
If a student does not pass the written tests in any of the sessions, but has satisfactorily completed the continuous assessment tests, his/her grade in the practicals and the project will be saved for the following year and he/she will only have to sit the written tests to pass the subject. The percentage in each of the parts for the calculation of the final grade will be the same.
In the event of a student committing any irregularity that may leadto a significant variation in the grade awarded to an assessment activity, the student will be given a zero for this activity, regardless of any disciplinary process that may take place. In the event of several irregularities in assessment activities of the same subject, the student will be given a zero as the final grade for this subject.
Single assessment
This subject does not incorporate single assessment.
R. Chang, J. Overby. Química. 13ª edición en inglés, 8ª en español. México: McGraw-Hill, 2020.
R. H. Petrucci. Química general: principios y aplicaciones modernas. Madrid: Pearson Educación, 2017.
O. Mó Romero y M. Yáñez Montero. Enlace químico y estructura molecular. Palencia: Ediciones Cálamo, 2002.
H. Birch. 50 cosas que hay que saber sobre Química. Madrid: Planeta, 2016.
H. Baker. 50 cosas que hay que saber sobre Física Cuántica. Madrid: Planeta, 2016.J. L. Amoros. El Cristal. 4ª ed. Madrid: Atlas, 1990.
R. I. D. Tilley. Crystals and crystal structures. Oxford: Wiley-Blackwell, 2006.
J. F. Shackelford. Introducción a la ciencia de materiales para ingenieros. 6ª edición. Londres: Pearson. 2005.
C. Pico Marín, M. Luisa López García y M. L. Veiga Blanco. Cristaloquímica de materiales: de la estructura a las propiedades de los sólidos inorgánicos. Madrid: Síntesis, 2007.
A. R. West. Solid State Chemistry and Its Applications. 2nd. ed. Chichester: Wiley, 2014.
None required.
Information on the teaching languages can be checked on the CONTENTS section of the guide.