Base Knowledge
Knowledge of Biology content is recommended.
Teaching Methodologies
In order to achieve the objectives of the curricular unit and the competences foreseen for the students, the process of teaching learning is based on:
1. Exposition of the theoretical foundations necessary for content development;
2. Individual or group work for the resolution of questions presented by the teacher or formulated by the students;
3. Execution of practical laboratory work related to the subject;
4. Oral presentation and discussion of the final research product..
Learning Results
1. Understand the water-plant-atmosphere relation ships;
2. Understand the carbon balance and plant productivity;
3. Understand the dynamics and kinetics of growth and development in plant productivity.
Program
Competence 1:
1 Water flow in the soil-plant-atmosphere continuum;
2 Water relations in plant cells and tissues;
3 Transpiration;
4 Water deficit and plant growth;
5 Water saving in the plant
Competence 2:
1 Photochemistry and assimilation of CO2;
2 Structure of the photosynthetic system;
3 Photorespiration;
4 Intrinsic and extrinsic factors that affect the photosynthetic process;
5 Interaction between carbon and nitrogen metabolism and the impact on plant productivity;
6 Synthesis, regulation, accumulation and translocation of assimilates;
7 Respiratory metabolism;
8 Respiration and the plant energetics;
9 Day course of the physiological processes in function of the environmental variations.
Competence 3:
1 Mechanisms and levels of control ;
2 Plant hormones and growth regulators;
3 Physiology of germination and dormancy of seeds;
4 Differentiation, reproduction and yield;
5 Growth of plants in modified environments;
6 Quantitative
Curricular Unit Teachers
Grading Methods
- - Desempenho nas aulas e qualidade dos relatórios apresentados - 15.0%
- - Teste escrito - 60.0%
- - Elaboração de um trabalho escrito sobre um tema previamente acordado com o docente, apresentação e discussão - 25.0%
- - Exame - 100.0%
Internship(s)
NAO
Bibliography
Anderson, J. W.; Beardall, J. – Molecular Activities of Plant Cells: An Introduction to Plant Biochemistry, Blackwell. 1991.
Arrabaça, M. C. – Metabolismo Fotossintético do Carbono, em Bioquímica, M. J. Halpern ed., Lidel. 1997.
Azcon-Bieto, J.; Talon, M. 1993 – Fisiologia y Bioquimica Vegetal. Interamericana, McGraw Hill. Nova lorque.
Bibliografia complementar
Blankenship, R. 2002 – Molecular mechanisms of photosynthesis. London: Blackwell Science, 336 pp.
Contreiras, J. – Fisiologia e Bioquímica da Respiração das Plantas Superiores. Fundação Calouste Gulbenkian. Lisboa. 1992.
Fageria, N.; Baligar V.; Clark, R. 2006 – Physiology of crop production. Haworth Press, New York, 364pp.
Hay, R.; Porter, J. 2006. The physiology of crop yield, 2nd edition. Blackwell, Oxford, 328pp.
Heldt, H.; Piechulla, B. 2010. Plant biochemistry. 4.ed. San Diego: Academic Press, 656 pp.
Kirkham, M. 2005. Principles of soil and water relations. Elsevier Academic Press, Burlington.
Lambers, H.; Chapin, F.; Pon, T. 2009. Plant physiological ecology, 2nd edition. Springer, Berlin, 640 pp.
Nicholls, D.; Ferguson, S. – Bioenergetics 3, Academic. 2002.
Nobel, P. 2005. Physicochemical and environmental plant physiology, 3rd edition. Elsevier Academic Press, Burlington.
Overman, A.; Scholtz, R. 2002. Mathematical models of crop growth and yield. New York. Marcel Dekker, 344 pp.
Pessarakli, M. 2005. Handbook of photosynthesis. CRC – Taylor & Francis, Boca Raton, 952 pp.
Roger, M. 2010. Handbook of plant ecophysiology techniques. Dordrecht: Kluwer Academic Press, 472 pp.
Taiz, L.; Zeiger, E. 2015. Plant physiology, 5th edition. Sinauer Associates, Suderlands, 782pp.
Yeo, A.; Flowers, T. 2007. Plant solute transport. Blackwell, Oxford.