Study programme competencies |
Code
|
Study programme competences / results
|
A1 |
Recoñecer distintos niveis de organización nos sistemas vivos. |
A2 |
Identificar organismos. |
A3 |
Recoñecer, obter, analizar e interpretar evidencias paleontológicas. |
A4 |
Obter, manexar, conservar e observar especímenes. |
A29 |
Impartir coñecementos de Bioloxía. |
B1 |
Aprender a aprender. |
B2 |
Resolver problemas de forma efectiva. |
Learning aims |
Learning outcomes |
Study programme competences / results |
To understand the concept of deep (geologic) time |
A3 A29
|
B1
|
|
To understand the processes of fossilization and the biases of the fossil record as an indicator of ancient biospheres |
A2
|
B1
|
|
To understand how biological processes occurring at geological time scales, such as evolution or mass extinctions, cannot always be understood as simple extrapolations of processes taking place at shorter time scales |
A2
|
B1 B2
|
|
To expand our understanding of Evolutionary Theory from a multidisciplinary perspective |
A3
|
B1 B2
|
|
To know the fossil groups that make up the fossil record and their practical uses |
A1 A2 A3 A4
|
B1 B2
|
|
To identify the main bioevents in the history of the Earth, their causes and aftermath |
A2 A3
|
B1 B2
|
|
To synthesize knowledge from a long array of subjects such as Geology, Ecology, Microbiology, Biochemistry, Botany or Zoology in the framework of an ever changing Earth |
A2 A3 A29
|
B1 B2
|
|
Contents |
Topic |
Sub-topic |
SECTION-1. |
HISTORY AND CONCEPT OF PALEOBIOLOGY |
Lesson 1. An introduction to Paleobiology |
1.1 Introduction
1.2 Theoretical and methodological aspects
1.3 Divisions of Paleobiology |
SECTION-2. |
TAPHONOMY |
Lesson 2. The concept of fossil. Taphonomy |
2.1 Introduction
2.2 The concept and types of fossils
2.3 Biostratinomy
2.4 Diagenesis of fossils
2.5 Ichnofossils
2.6 Time-averaging
2.7 Fossil-lagerstätten
2.8 The quality of the fossil record
|
SECTION-3. |
MORPHOLOGICAL ANALYSIS |
Lesson 3. Size and Shape in Fossils |
9.1 Introduction
9.2 The analysis of morphometrical variability
9.3 Types of growth
9.4 Population variability
9.5 Ecophenotypic variability
9.6 Sexual dimorphism
9.7 Taphonomical variability |
Lesson 4. Ontogeny and Heterochrony |
10.1 Introduction
10.2 Biogenetic and von Baer's Law
10.3 Heterochrony and its types
10.4 Heterochrony and allometry
10.5 Heterochronoclines
10.6 Dissociated heterochrony
10.7 Evolutionary consequences of heterochrony |
Lesson 5. Morphodynamics and the Evolution of Form |
11.1 Introduction
11.2 Constructional morphology. Phylogenetic factor. Functional factor. Fabricational factor. Other factors
11.3 Research methods in morphodynamics. Biomechanical analysis. Theoretical morphology |
SECTION-4. |
EVOLUTIONARY PALEONTOLOGY |
Lesson 6. Classification and Phylogeny |
12.1 Introduction
12.2 Methods of classification. Essentialism, evolutionary, phenetic, and cladistic classification
12.3 Fossils and Phylogeny. Stratocladistics. Phylogenetic trees |
Lesson 7. Speciation |
13.1 Introduction
13.2 Species concepts
13.3 Modes of speciation
13.4 The problem of species concept in Paleontology |
Lesson 8. Modes of evolution |
14.1 Introduction
14.2 Darwinism and the Synthetic Theory of Evolution
14.3 Modes of evolution and the fossil record. Phyletic gradualism and punctuated equilibria
14.5 Evolutionary trends
14.6 Species selection
14.7 Coordinated stasis |
Lesson 9. Paleobiogeography |
16.1 Introduction
16.2 Dispersal biogeography
16.3 Paleogeography and paleoclimatology
16.4 Vicariance biogeography
16.5 Biogeographic patterns and extinctions |
Lesson 10. Evolutionary Paleoecology |
17.1 Introduction
17.2 Phanerozoic trends in global diversity. Explanatory hypotheses
17.3 Law of constant extinction. Red Queen Hypothesis and alternative explanatory hypotheses
17.4 Clade interactions |
SECTION-5. |
BIOSTRATIGRAPHY |
Lesson 11. Time and Geology |
4.1 Dating methods
4.2 The geologic time scale |
SECTION-6. |
HISTORY OF LIFE |
Lesson 12. The origin and early evolution of Earth and Life |
5.1 Origins of the Solar System and Earth.
5.2 Origin and evolution of the Atmosphere.
5.3 Origin of the Hidrosphere.
5.4 Origin and evolution of the continents.
5.5 The first life forms. |
Lesson 13. The diversification of Life |
6.1 The Ediacaran Fauna and other life forms.
6.2 The Cambrian Explosion.
6.3 Evolution of life forms during the Paleozoic.
6.4 Terrestrialization. |
Lesson 14. Mass extinction events |
7.1 Mass extinctions. Causes and their aftermath.
7.2 The end-Permian extinction.
7.3 The end-Cretaceous extinction.
|
Lesson 15. Climate and Life |
8.1 Climatic evolution of the planet Earth.
8.2 Global glaciations. Methods of study.
8.3 The Snowball Earth hypothesis.
8.4 The influence of climatic change on the Quaternary faunas and floras. |
Planning |
Methodologies / tests |
Competencies / Results |
Teaching hours (in-person & virtual) |
Student’s personal work hours |
Total hours |
Guest lecture / keynote speech |
A29 A3 B1 B2 |
21 |
66 |
87 |
Workshop |
A1 A2 A3 A4 A29 B1 B2 |
7 |
12 |
19 |
Laboratory practice |
A1 A2 A3 A4 A29 B1 B2 |
14 |
18 |
32 |
Objective test |
A1 A2 A3 A4 A29 B1 B2 |
2 |
8 |
10 |
|
Personalized attention |
|
2 |
0 |
2 |
|
(*)The information in the planning table is for guidance only and does not take into account the heterogeneity of the students. |
Methodologies |
Methodologies |
Description |
Guest lecture / keynote speech |
Lectures will be devoted to topics related to principles and problems in paleontology, as well as to the history of life on Earth. Students are expected to take their own notes. Reading assignments from specific topics delivered during the lectures are also expected to be completed. |
Workshop |
The workshops are intended to introduce to the students the basic concepts of taphonomy and systematics by means of the direct observation of fossils. The students will prepare their own handouts and solve specific quizzes. Attendance to the workshops is mandatory to pass the subject. |
Laboratory practice |
Laboratory sessions will be devoted to the recognition of the basic morphological features of the main groups of fossils, as well as on the identification of important taxa from the Iberian Peninsula. Students will be required to take their own notes and answer the lab quizzes. Attendance to the lab sessions is compulsory to pass the course. |
Objective test |
Grading is primarily based on the idea of continuous assessment and so, the final exam IS NOT REQUIRED for those students being successful during this continuous assessment. Students failing specific parts or the whole subject are required to make the final exam for the parts they failed |
Personalized attention |
Methodologies
|
Workshop |
Laboratory practice |
Guest lecture / keynote speech |
Objective test |
|
Description |
Attendance to tutorials is expected, especially for those aspects showing greater difficulty, such as quizzes solving, tests, or workshop/laboratory observations.
Part-time students not capable of attending to the workshops and/or lab sessions are eligible to get an exemption of these compulsory tasks in the scheduled programme. They will however be required to perform the tasks associated to the workshops and labs in a different schedule adapted to their job obligations.
|
|
Assessment |
Methodologies
|
Competencies / Results |
Description
|
Qualification
|
Workshop |
A1 A2 A3 A4 A29 B1 B2 |
Continuous assessment using quizzes involving multiple choice, matching, true-false questions, fill in the blank questions or short answer and essay questions. These quizzes make up 10% of the final grade |
10 |
Laboratory practice |
A1 A2 A3 A4 A29 B1 B2 |
Continuous assessment using quizzes involving multiple choice, matching, true-false questions, fill in the blank questions, short answer, essay questions and/or fossil identifications with real specimens |
25 |
Guest lecture / keynote speech |
A29 A3 B1 B2 |
Continuous assessment will take place using in-class quizzes and participation during classes. All quizzes can involve multiple choice, matching, true-false questions, fill in the blank questions or short answer and essay questions. Quizzes make up 65% of the final grade. |
65 |
Objective test |
A1 A2 A3 A4 A29 B1 B2 |
As stated in Step 5, grading is primarily based on the idea of continuous assessment and so, the FINAL EXAM IS NOT REQUIRED for those students being successful during this continuous assessment. For the rest of students a final exam will be carried out for the specific parts of the subject (i. e., lectures 65%, workshops + lab sessions 35%) that they failed |
0 |
|
Assessment comments |
Students
are required to obtain a final grade of at least 5.0 out of 10 to pass this
subject. However, all the activities making up the assessment (lectures,
workshops and lab sessions) can be compensated among them getting a grade of at
least 4.0. Students passing any of the parts (lectures and workshops + lab
sessions) are given the opportunity to keep this mark for the two grading
opportunities (January and July), being only examined of those parts which they
failed. However, all the teaching-learning process of this subject is based on
the idea of being developed in the current term. This means that for successive
terms the student is suppossed to fullfill all the assignments scheduled for
those specific terms. Under
exceptional justified reasons, such as part-time learning, or students with
special educational needs, specific assessments could be undertaken. The
grade “no show” will be given only to those students who have not participated
in more than 20% of the assessed activities during the term. The
before mentioned instructions also apply for part-time students. Students
from former terms, if attending the December’s advance call, will be examined
under the rules of the 2020-21 academic year (please check the corresponding
syllabus).
If academic fraud is detected in any of the activities included in the continuous assessment of the course, the student/s
involved will be qualified with "Fail (0)" in the corresponding opportunity (January or July) of the terms's call
|
Sources of information |
Basic
|
PROTHERO, D. R. (2013). Bringing Fossils to Life. An Introduction to Paleobiology. Columbia University Press, New York
BENTON, M.J. (2020). Cowen’s History of Life. Wiley
STANLEY, S. M. (2009). Earth System History. Freeman and Company, New York
MARTIN, R. (2012). Earth's Evolving Systems: The History of Planet Earth. Jones & Bartlett Learning, Sudbury
FREEMAN, S. & HERRON, J.C. (2013). Evolutionary Analysis. Preason Prentice Hall
REGUANT, S. (2005). Historia de la Tierra y de la Vida. Editorial Ariel, Barcelona
WICANDER, R. & MONROE, J. S. (2015). Historical Geology. Evolution of Earth and Life through Time. Thompson Learning, Belmont
COWEN, R. (2013). History of Life. Blackwell Science, Oxford.
BENTON, M. J. & HARPER, D. A. T. (2020). Introduction to Paleobiology and the Fossil Record. Wiiey-Blackwell
BRIGGS, D. E. G. & CROWTHER, P. R. (2003). Palaeobiology II. Blackwell Science
FOOTE, M. & MILLER, A.I. (2007). Principles of Paleontology. W. H. Freeman, New York
LEVIN, H. L. (2010). The Earth through Time. John Wiley & Sons, Hoboken, New Jersey |
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Complementary
|
ANGUITA, F. (2002). Biografía de la Tierra. Editorial Aguilar, Madrid
GOULD, S. J. (1993). El Libro de la Vida. Editorial Crítica, Barcelona
FUTUYMA, D. J. & KIRKPATRICK, M. (2017). Evolution. Oxford University Prees
SKELTON, P. (1993). Evolution. A Biological and Palaeontological Approach. Addison Wesley Longman
- (-). Fósil. Revista de Paleontología. http://www.fosil.cl
MILSOM, C. & RIGBY, S. (2010). Fossils at a Glance. Wiley-Blackwell
JAIN, S. (2016). Fundamentals of Invertebrate Palaeontology: Macrofossils. Springer
JAIN, S. (2019). Fundamentals of Invertebrate Palaeontology: Microfossils. Springer
LEVINTON, J. S. (2001). Genetics, Paleontology, and Macroevolution. Cambridge University Press
DOMÈNECH, R. & MARTINELL, J. (1996). Introducción a los Fósiles. Masson
CLARKSON, E. N. K. (2001). Invertebrate Palaeontology and Evolution. Blackwell Science, Oxford
GOULD, S. J. (1992). La Flecha del tiempo : mitos y metáforas en el descubrimiento del tiempo geológico. Alianza Editorial, Madrid
BRENCHLEY, P. J. & HARPER, D. A. T. (1998). Palaeoecology: Ecosystems, Environments and Evolution. Chapman & Hall, London
BOTTJER, D. J. (2016). Paleoecology: Past, Present and Future. Wiley |
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Recommendations |
Subjects that it is recommended to have taken before |
Geology/610G02004 | Physical Geography/610G02006 | Genetics/610G02019 | Population Genetics and Evolution/610G02021 | Plant Systematics: Cryptogamia/610G02024 | Plant Systematics: Phanerogamia/610G02025 | Zoology I/610G02031 | Zoology II/610G02032 | Ecology I: Individuals and Ecosystems/610G02039 | Ecology II: Populations and Communities/610G02040 |
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Subjects that are recommended to be taken simultaneously |
Animal Biodiversity and the Environment/610G02033 |
|
Subjects that continue the syllabus |
Developmental Biology/610G02010 | Functional Adaptations of Animals in the Environment/610G02037 |
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Other comments |
Students having specific questions or wanting to discuss class materials are always welcome during the lecturer's office hours. It is highly recommended that they communicate any kind of problem affecting their class performance, ability to take tests or class attendances, especially in the case of foreign students. This
subject follows the Green Campus Faculty of Sciences program on sustainability
(https://ciencias.udc.es/images/Facultade/Green_Campus/Declaraci%C3%B3n_Ambiental_FCiencias.pdf) |
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