Study programme competencies |
Code
|
Study programme competences
|
A2 |
CE2 - Aplicar los conceptos, principios, teorías y hechos fundamentales relacionados con la Nanociencia y Nanotecnología a la resolución de problemas de naturaleza cuantitativa o cualitativa. |
A4 |
CE4 - Desarrollar trabajos de síntesis y preparación, caracterización y estudio de las propiedades de materiales en la nanoescala. |
A6 |
CE6 - Manipular instrumentación y material propios de laboratorios para ensayos físicos, químicos y biológicos en el estudio y análisis de fenómenos en la nanoescala. |
A7 |
CE7 - Interpretar los datos obtenidos mediante medidas experimentales y simulaciones, incluyendo el uso de herramientas informáticas, identificar su significado y relacionarlos con las teorías químicas, físicas o biológicas apropiadas. |
A8 |
CE8 - Aplicar las normas generales de seguridad y funcionamiento de un laboratorio y las normativas específicas para la manipulación de la instrumentación y de los productos y nanomateriales. |
B2 |
CB2 - Que los estudiantes sepan aplicar sus conocimientos a su trabajo o vocación de una forma profesional y posean las competencias que suelen demostrarse por medio de la elaboración y defensa de argumentos y la resolución de problemas dentro de su área de estudio |
B3 |
CB3 - Que los estudiantes tengan la capacidad de reunir e interpretar datos relevantes (normalmente dentro de su área de estudio) para emitir juicios que incluyan una reflexión sobre temas relevantes de índole social, científica o ética |
B4 |
CB4 - Que los estudiantes puedan transmitir información, ideas, problemas y soluciones a un público tanto especializado como no especializado |
B5 |
CB5 - Que los estudiantes hayan desarrollado aquellas habilidades de aprendizaje necesarias para emprender estudios posteriores con un alto grado de autonomía |
B7 |
CG2 - Resolver problemas de forma efectiva. |
B8 |
CG3 - Aplicar un pensamiento crítico, lógico y creativo. |
B9 |
CG4 - Trabajar de forma autónoma con iniciativa. |
B10 |
CG5 - Trabajar de forma colaborativa. |
B12 |
CG7 - Comunicarse de manera efectiva en un entorno de trabajo. |
C6 |
CT6 - Adquirir habilidades para la vida y hábitos, rutinas y estilos de vida saludables |
C7 |
CT7 - Desarrollar la capacidad de trabajar en equipos interdisciplinares o transdisciplinares, para ofrecer propuestas que contribuyan a un desarrollo sostenible ambiental, económico, político y social. |
C8 |
CT8 - Valorar la importancia que tiene la investigación, la innovación y el desarrollo tecnológico en el avance socioeconómico y cultural de la sociedad |
C9 |
CT9 - Tener la capacidad de gestionar tiempos y recursos: desarrollar planes, priorizar actividades, identificar las críticas, establecer plazos y cumplirlos |
Learning aims |
Learning outcomes |
Study programme competences |
Apply skills to use, under safe conditions, experimental techniques in physical, chemical and biological laboratories, at the same time it is a training to develop other more complex skills. |
A4 A6 A8
|
B2 B3 B7 B10 B12
|
C6 C7
|
Learning about interpretation and presentation of experimental data through a personal portfolio. |
A7
|
B2 B5 B7 B9 B12
|
C9
|
Demonstrate sufficient knowledge and experimental skills to correctly and safely use the most common products, material and instruments in physical, chemical and biological laboratories, being aware of their most important characteristics, including danger and possible risks. |
A2 A4 A8
|
B2 B4 B5 B8 B12
|
C6 C8
|
Contents |
Topic |
Sub-topic |
Module 1. Basic Technics in a Physics Science Laboratory. |
- Calculation of direct and indirect experimental uncertainties.
- Correct expression of experimental physical magnitudes.
- Analysis and graphical representation of the experimental results.
- Density measurement with the pycnometer method.
- Viscosity measurement with Ostwald viscometer.
- Measurement of surface tension with the drop method.
- Measurement of the gravitational constant with the physical pendulum.
- Verification of the ideal gas laws.
- Association of resistances and Kirchhoff's laws.
- Measurement of ionic conductivity in electrolytes as a function of concentration.
- Calibration of 4 different thermometers (resistance, thermocouples, column and thermistors).
- Determination of the electrical equivalent of heat by calorimetry.
- Measurement of the refractive index using the optical bench. |
Module 2. Basic Technics in a Chemistry Science Laboratory. |
- Safety in the Chemistry laboratory. Classification, packaging and labeling of chemical products. Security sheets. Reagent quality. Waste management in the laboratory. Use of protective equipment.
- General material in a chemical laboratory. Gravimetric and volumetric material.
- Registration and communication of laboratory work. The laboratory notebook.
- Preparation of solutions and review of concentration units.
- Acid-base titration
- Separation of liquids. Distillation.
- Separation of solids. Filtration.
- Calorimetry. Determination of heats of reaction in a calorimeter. |
Module 3. Basic Technics in a Biology Science Laboratory. |
- Basic rules of safe work in the biological laboratory.
- Correct use of biological laboratory material.
- Preparation of biological buffer solutions.
- Serial and standard straight dilutions.
- Preparation of culture media.
- Cultivation of microorganisms.
- Operation and basic management of binocular loupes and microscopes.
- Use of pH meter and spectrophotometer.
- Extraction of macromolecules.
- Search for bibliographic information, citations and references. Databases and computer resources of interest in biology. |
Planning |
Methodologies / tests |
Competencies |
Ordinary class hours |
Student’s personal work hours |
Total hours |
Introductory activities |
C6 C7 C8 |
1 |
0 |
1 |
Laboratory practice |
A4 A6 A8 B2 B4 B5 B8 |
60 |
48 |
108 |
Objective test |
A2 B3 B10 B12 C9 |
2 |
18 |
20 |
Student portfolio |
A7 B7 B9 |
0 |
18 |
18 |
|
Personalized attention |
|
3 |
0 |
3 |
|
(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. |
Methodologies |
Methodologies |
Description |
Introductory activities |
The different modules of the subject will be presented, including its objectives, the way in which it will be developed, as well as the calendar and other information of interest. |
Laboratory practice |
Practical sessions in the respective laboratory, where specific material will be handled for the different practices, which cover a wide range of basic Physical, Chemical and Biological techniques. The students will receive a script of the specific practice that they will carry out in that session through Moodle, where the objectives of the same, the available material and the pertinent health and safety recommendations will be indicated. |
Objective test |
It will consist of an exam of short questions or test type that will be carried out on the dates set in the exam calendar approved by the Faculty. |
Student portfolio |
It refers to what is known as laboratory notebook. The student must note in it the development of the practice and the data or observations requested. In addition, the analysis and representation of the data will be done if requested. This portfolio will be delivered to each teacher of each module of the subject for evaluation and qualification. |
Personalized attention |
Methodologies
|
Laboratory practice |
Student portfolio |
|
Description |
The professors' tutorials, which will preferably be virtual, will be an essential resource so that the students can consult all the doubts that arise, which will result in the better quality of their laboratory portfolios. That is why they are of paramount importance in the subject. |
|
Assessment |
Methodologies
|
Competencies |
Description
|
Qualification
|
Student portfolio |
A7 B7 B9 |
Avaliación dos resultados obtidos, tratamento dos datos, e expresión dos mesmos. |
70 |
Objective test |
A2 B3 B10 B12 C9 |
Exame tipo test ou de preguntas cortas relacionadas co traballo desenvolvido no laboratorio. |
30 |
|
Assessment comments |
A asistencia ás sesións de prácticas programadas é obrigatoria. Máis de unha falta sen xustificar implicará a non superación da materia. As faltas deberán xustificarse e poderán recuperarse se é posible. É preciso obter un mínimo de 5/10 na avaliación de cada módulo para poder superar a materia. A cualificación dos módulos aprobados manterase na 2ª oportunidade.
ALUMNOS MATRICULADOS CON DISPENSA
ACADÉMICA O MATRÍCULA A TIEMPO PARCIAL: As prácticas son de carácter obligatorio pudindo
realizarse dentro do calendario oficial en cualquera turno. No caso de falta
non xustificada, aplicaránse os mesmos criterios que se describiron con
anterioridade para os alumnos de matrícula ordinaria.
|
Sources of information |
Basic
|
Karp, G. (2011). Biología Celular y Molecular. Conceptos y experimentos. . McGraw-Hill Interamericana Eds.
Cerdán Villanueva, M. E., Freire Picos, M. A., González Siso, M. I. & Rodríguez Torres, A. M. (1997). Biología Molecular. Avances y Técnicas generales. . A Coruña. Universidade da Coruña
Tortora, A, G.J., Funke, B. R. & Case, C.L (2017). Introducción a la Microbiología . McGraw-Hill Interamericana Eds. 12 ed.
Insausti, M.J., Redondo, P., Charro E. (1999). Manual de Experimentación Básica en Química. Valladolid, Universidad de Valladolid
Torrecilla, M.I. (1994). Prácticas de Física General.. Zaragoza. Prensas Universitarias de Zaragoza.
Ortega Girón, M.R. (1980). Prácticas de laboratorio de física general.. Barcelona
Petrucci, R. H.; Harwood, W. S.; Herring, F. G (2003). Química General. . Madrid, 8ªEd, Pearson Educación |
|
Complementary
|
H. Kennet (2014). Cambridge IGCSE physics. Laboratory practical book.. Hodder Educational. Londres.
Singer (2001). Experiments in Applied Microbiology. . Academic Pres.
Ninfa, A. J. (2010). Fundamental laboratory approaches for biochemistry and biotechnology.. Hoboken: John Wiley and Sons
Varios (2007). Manual de Seguranza e Saúde no Laboratorio. . Universidade da Coruña
J.D. Wilson (2015). Physics laboratory experiments.. Boston, MA : Cengage Learning.
Loyola-Vargas, V.M. y Vázquez-Flota F. (2006). Plant cell culture protocols. . Humana Press. 2nd Edition.
A. Amengual Colom (2003). Prácticas virtuales de física básica.. Palma de Mallorca. Universitat de les Illes Balears. |
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Recommendations |
Subjects that it is recommended to have taken before |
|
Subjects that are recommended to be taken simultaneously |
Cell Biology/610G04003 | Chemistry: Structure and Bonding/610G04005 | Physics: Mechanics and Waves/610G04002 |
|
Subjects that continue the syllabus |
Techniques of Characterisation of Nanomaterials 1/610G04025 | Kinetic and Catalysis/610G04026 | Thermodynamics: Equilibrium and Phases/610G04018 | Structural Biochemistry/610G04019 | Molecular and Metabolic Biochemistry/610G04023 | Physics: Electricity and Magnetism/610G04007 | Chemistry of the Elements/610G04011 | Chemistry: Equilibrium and Change/610G04008 |
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Other comments |
Programa Green Campus Facultade de Ciencias Para axudar a conseguir unha contorna inmediata sustentable e cumprir co punto 6 da "Declaración Ambiental da Facultade de Ciencias (2020)", os traballos documentais que se realicen nesta materia: a. Solicitaranse maioritariamente en formato virtual e soporte informático. b. De realizarse en papel: - Non se empregarán plásticos. - Realizaranse impresións a dobre cara. - Empregarase papel reciclado. - Evitarase a realización de borradores. |
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