ECTS credits ECTS credits: 6
ECTS Hours Rules/Memories Student's work ECTS: 99 Hours of tutorials: 3 Expository Class: 24 Interactive Classroom: 24 Total: 150
Use languages Spanish, Galician
Type: Ordinary Degree Subject RD 1393/2007 - 822/2021
Departments: Inorganic Chemistry
Areas: Inorganic Chemistry
Center Faculty of Pharmacy
Call: First Semester
Teaching: With teaching
Enrolment: Enrollable | 1st year (Yes)
Acquisition and consolidation, by the students, of the basic knowledge of Chemistry related to the nucleus, atomic structure, bonding and with the acid-base and oxidation-reduction processes, which are necessary for them to understand and rationalize the teachings of others chronologically subsequent subjects of the degree in Pharmacy.
Theoretical program
LESSON 1
Bases of the modern theory of the atom. Elementary application of wave mechanics. Quantum numbers. Structure of polyelectronic atoms. Periodicity of atomic electronic structures. Ionization energy. Electronic affinity. Periodic table of elements.
LESSON 2
Bond general approach. Bond in discrete atomic groupings: molecules. Introduction to molecular geometry: some significant examples. Predictive approach: T.R.P.E.C.V. Diatomic molecules: T.O.M. CLOA approach. Electronic structures of some homonuclear molecules. Bond polarity and electronegativity.
LESSON 3
Introduction to the treatment of polyatomic molecules. Justification of the structural aspects of polyatomic molecules. Hybridization. Polarity and dipole moment in polyatomic systems.
LESSON 4
The bond in condensed phases. Ionic bond: structural aspects. Energy considerations: lattice energy.
LESSON 5
Weak bonding forces: different types. Hydrogen bond.
LESSON 6
Chemical equilibrium in solution. Acids and bases: definitions. Acid-base force. Acidity and basicity constants. Equilibrium of self-dissociation of water. Specific examples of strong and weak acids and bases.
LESSON 7
Behavior of salts in aqueous solution: hydrolysis. Buffer solutions.
LESSON 8
Oxidation - reduction reactions. Qualitative aspects and revision of fundamental concepts. Quantitative aspects. Red-ox potentials. Effects of concentration. Specific examples of oxidants and reducers.
LESSON 9:
The nucleus. Nuclear reactions. Radioactivity. Nuclear stability Radioactive series. Nuclear fission and fusion. Units of radioactivity.
Experimental program
Practice 1: Obtaining sodium peroxoborate. Determination of its purity.
Practice 2: Separation of a mixture.
Practice 3: Reactions of species in solution.
Practice 4: Obtaining sodium bicarbonate.
Basic.
• Petrucci R.H., Harwood W.S. y Herring F.G., Química General, 12ª ed.; Pearson, 2017.
Other reading.
• Brown T.L., LeMay H.E. Jr. y Bursten B.E.; Química. La Ciencia Central, 12ª ed., Pearson, 2013.
• Atkins, P. y Jones, L.: Principios de Química, 3ª ed.; Ed. Médica Panamericana, 2006.
• Goldsbsby, K. y Chang, R: Química, 12ª ed.; McGraw-Hill, 2016.
• Masterton, W.L. y Hurley, C.N.: Química. Principios y reacciones, 4ª ed.; Paraninfo Cengage Learning, 2003.
• Kotz, J.C. y Treichel, P.M.: Química y reactividad química, 5ª ed.; Thomson, 2003
Basic and general skills:
CB1 - That students have demonstrated to possess and understand knowledge in an area of study that starts from the base of general secondary education, and is usually found at a level that, although supported by advanced textbooks, also includes some aspects They involve knowledge coming from the cutting edge of your field of study.
CG1 - That the graduates possess and understand the most important concepts, methods and results of the different branches of Chemistry, with a historical perspective of their development.
CG2 - That they are able to gather and interpret relevant data, information and results, obtain conclusions and issue reasoned reports on scientific, technological or other issues that require the use of knowledge of Chemistry.
CG3 - That they can apply both the theoretical-practical knowledge acquired as well as the capacity for analysis and abstraction in the definition and approach of problems and in the search for their solutions both in academic and professional contexts.
CG4 - That they have the ability to apply the basic principles of the different branches of Chemistry to any chemical transformation process and to the resolution of qualitative and quantitative problems.
CG5 - That they are able to study and learn autonomously, with the organization of time and resources, new knowledge and techniques in any scientific or technological discipline.
Transversal skills:
CT01 - Possess the ability to analyze information and synthesize concepts.
CT02 - Be able to adapt to new situations and make decisions.
CT04 - Be able to solve problems.
CT06 - Acquire teamwork habits.
CT10- Acquire critical reasoning.
CT12 - Demonstrate autonomy and ability to manage time and information.
Specific skills:
CE01 - Correctly use chemical terminology: nomenclature, conventions and units.
CE02 - Interpret the variation of the characteristic properties of chemical elements according to the Periodic Table.
CE03 - Apply concepts of link theories, structure and periodic properties to the study of chemical elements and compounds.
CE04 - Know the main types of chemical reaction and their main associated characteristics.
CE13 - Be able to demonstrate knowledge and understanding of the essential facts, concepts, principles and theories related to the areas of Chemistry.
CE14 - Be able to solve qualitative and quantitative problems according to previously developed models.
CE17 - Be able to safely handle chemical materials.
CE21 - Assess the risks in the use of chemical substances and laboratory procedures.
CE22 - Balance between theory and experimentation.
CE24 - Understanding of the qualitative and quantitative aspects of chemical problems.
1.Large groups lectures. (EC)
Classes given by the professor on the most relevant aspects of the subject. The teacher can count on the support of computer and audiovisual media. The USC virtual platform will serve as support and complement to the theoretical teaching.
2. Interactive classes in small groups. Seminars, (S)
Theoretical / practical classes dedicated to solving the bulletins of questions and problems that, previously, will be delivered to the students, and that will allow them to determine the degree of use of the personal work carried out. The student must actively participate in these classes. Evaluative tests can be included.
3. Practical laboratory classes. Practices (L)
In these classes the student acquires the skills of a laboratory and consolidates the knowledge acquired in the theory classes. For these practices, the student will have a manual of laboratory practices, which will include general considerations about the work in the laboratory, as well as a script for each of the practices to be carried out, which will consist of a brief presentation of the fundamentals, the methodology to be followed and an indication of the calculations to be carried out and results to be presented. Students must attend each practice session having carefully read the content of this manual and previously carrying out the necessary calculations to be able to carry out the experimental work. At the beginning of each practical session, the student must demonstrate that he understands the work to be carried out in the laboratory. Subsequently, the experimental part will be carried out in the laboratory, collecting in the laboratory diary the development of the practice and the calculations and results that proceed. The results of the practices, as well as the answers to the questions raised in the scripts, will be evaluated.
Attendance at these classes is compulsory. The absences must be justified by documentation. Practices not carried out will be made up, if possible, in agreement with the teacher and within the scheduled time for the subject.
The student will not be evaluated if he does not complete and pass the practices of the subject.
The laboratory practices will be carried out in groups of 20 students.
4. Blackboard tutorials (T)
These tutorials are aimed at solving doubts about theory or practices, but they can also pose problems or exercises to be solved individually or in small work groups. They will be taught in person.
The student will not be evaluated if he does not complete and pass the laboratory practices.
The course is divided into two parts, theoretical and practical, which will be assessed separately.
The theoretical part of the subject will be evaluated with a final test, which will account for 80% of the final grade, will consist of short questions and problems aimed at the student to reason about the subject studied, in addition to questions related to laboratory practices. Assessment controls may be carried out throughout the course in order to help the student in following the subject. (Competences in the exam: C102, C103, C105, C108; CS03, CS04).
The evaluation of the theoretical test will be complemented with the assessment obtained from the student in the aspects related to the completion of the exercises and / or problems suggested by the teacher. The evaluation control tests that are carried out and the participation in the seminars and tutorials, as well as the performance of individual or group work, will be valued. In the final evaluation these aspects will account for 20% of the final grade. In order to access the qualification corresponding to the continuous assessment, attendance to the interactive classes is an essential requirement. Exceptionally, students who repeat the course will not have to attend interactive seminar classes, if they so request in writing to the teacher. In this case, the grade corresponding to the interactive classes of the previous course (s) will be maintained. (Competences in interactive classes: C101, C103, C105, C109; C110, CP01, CP02).
In the practices, the opinion obtained about the student in the work sessions in the laboratory and their notebook of practices will be taken into account. On the one hand, issues related to laboratory work will be taken into account and, on the other, those related to the preparation of the laboratory diary. The qualification of the practices will be "suitable" or "not suitable". Students not suitable in practices will have failed the subject. The student who does not complete all the practices will be classified as "Failure". Students who repeat the subject and who have the grade of PASS in practice, will not have to do it again, if they do not want to. Repeating students will keep the qualification of the practical part for a period of five years. (Competences in practices: Q02, Q03, Q04, Q06, Q07, CP01, CP02, CP103, CS01, CS03, CS04, CS08, CS12)
The student must obtain five points out of ten and the qualification of apt in the practices to pass the subject.
In the second call of the academic year, only the theoretical test will be carried out, keeping the grade corresponding to the continuous assessment obtained during the course. The maximum mark on which the exam will be graded will be the same as in the first call. The requirements of having carried out and approved the practices will also be maintained.
CLASSROOM TEACHING
-Expositive classes in large group: 30 h
-Interactive groups: 10 h
-Tutorials in very small group: 2 h
-Laboratory practices: 17 h
-Other activities: 1 h
-Total hours classroom teaching or in the laboratory: 60 h
PERSONAL WORK OF THE STUDENT:
-Individual or group study: 52,5 h
-Resolution of exercises, or other works: 14 h
-Guidance and resolution of doubts: 8,5 h
-Preparation of the laboratory work and elaboration of the laboratory notebook: 8,5 h
-Realization and review of the exam: 14 h
-Total hours personal work of the student: 90 h
• It is advisable to attend the lectures.
• It is important to keep the study of the subject “up to date”.
• Once you have finished reading a topic in the reference manual, it is helpful to summarize the important points, identifying the basic equations to remember and making sure you know both their meaning and the conditions under which they can be applied.
• Problem solving is essential for learning this subject. It may be helpful to follow these steps: (1) Make a list of all the relevant information that the statement provides. (2) Make a list with the quantities to be calculated. (3) Identify the equations to use in solving the problem and apply them correctly.
• It is essential to prepare the practices before entering the laboratory. First, the important theoretical concepts should be reviewed in each experiment and then it is necessary to read the practice script carefully, trying to understand the objectives and development of the proposed experiment. Any questions that may arise should be consulted with the teacher
Recommendations related to the assessment:
The student should review the theoretical concepts of each unit. The number of correct choices in the proposed exercises indicates the students’ preparation to confront the subject’s final examination. Those students that find important difficulties in the proposed activities should use the teacher’s tutorial time to analyze the problem and to help to resolve any difficulties.
Recommendations related to the extraordinary exam:
Together with the students, the teacher will analyze the evaluation process and if so, any difficulties in the learning of the subject contents.
In cases of fraudulent completion of exercises and tests, the provisions of the "Regulations for the validation of academic performance for students and for the review of qualifications" shall apply
Maria Elena Labisbal Viqueira
Coordinador/a- Department
- Inorganic Chemistry
- Area
- Inorganic Chemistry
- Phone
- 881815089
- Category
- Professor: Temporary PhD professor
Maria Luz Duran Carril
- Department
- Inorganic Chemistry
- Area
- Inorganic Chemistry
- Phone
- 881814952
- marialuz.duran [at] usc.es
- Category
- Professor: University Lecturer
Antonio Sousa Pedrares
- Department
- Inorganic Chemistry
- Area
- Inorganic Chemistry
- Phone
- 881814240
- antonio.sousa.pedrares [at] usc.es
- Category
- Professor: Temporary PhD professor
Maria Isabel Garcia Santos
- Department
- Inorganic Chemistry
- Area
- Inorganic Chemistry
- Phone
- 881814956
- isabel.garcia [at] usc.es
- Category
- Professor: University Lecturer
Esperanza Padin Gonzalez
- Department
- Inorganic Chemistry
- Area
- Inorganic Chemistry
- esperanza.padin [at] usc.es
- Category
- Researcher: Marie Curie Programme
Monday | |||
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11:00-12:00 | Grupo B /CLE_02 | Spanish | 5035 Edaphology Classroom. Faculty of Pharmacy |
11:00-12:00 | Grupo A /CLE_01 | Spanish | 5035 Plant Physiology Classroom |
17:00-18:00 | Grupo C /CLE_03 | Spanish | 5035 Soil Science Seminar Room |
Tuesday | |||
11:00-12:00 | Grupo B /CLE_02 | Spanish | 5035 Edaphology Classroom. Faculty of Pharmacy |
11:00-12:00 | Grupo A /CLE_01 | Spanish | 5035 Plant Physiology Classroom |
17:00-18:00 | Grupo C /CLE_03 | Spanish | 5035 Soil Science Seminar Room |
Wednesday | |||
11:00-12:00 | Grupo B /CLE_02 | Spanish | 5035 Edaphology Classroom. Faculty of Pharmacy |
11:00-12:00 | Grupo A /CLE_01 | Spanish | 5035 Plant Physiology Classroom |
17:00-18:00 | Grupo C /CLE_03 | Spanish | 5035 Soil Science Seminar Room |
Thursday | |||
11:00-12:00 | Grupo B /CLE_02 | Spanish | 5035 Edaphology Classroom. Faculty of Pharmacy |
11:00-12:00 | Grupo A /CLE_01 | Spanish | 5035 Plant Physiology Classroom |
17:00-18:00 | Grupo C /CLE_03 | Spanish | 5035 Soil Science Seminar Room |
Friday | |||
11:00-12:00 | Grupo B /CLE_02 | Spanish | 5035 Edaphology Classroom. Faculty of Pharmacy |
11:00-12:00 | Grupo A /CLE_01 | Spanish | 5035 Plant Physiology Classroom |
17:00-18:00 | Grupo C /CLE_03 | Spanish | 5035 Soil Science Seminar Room |