Code: | MEMG0021 | Acronym: | RSA |
Keywords | |
---|---|
Classification | Keyword |
CNAEF | Environmental protection technology |
Active? | Yes |
Responsible unit: | Mining Engineering Department |
Course/CS Responsible: | Master in Mining and Geo-Environmental Engineering |
Acronym | No. of Students | Study Plan | Curricular Years | Credits UCN | Credits ECTS | Contact hours | Total Time |
---|---|---|---|---|---|---|---|
MEMG | 1 | Plano de estudos oficial a partir de 2008/09 | 2 | - | 6 | 56 | 162 |
MIEA | 39 | Syllabus since 2006/07 | 4 | - | 6 | 56 | 162 |
BACKGROUND: the knowledge of scientific principles and technologies involved in soil and groundwater remediation is a fundamental necessity for environmental engineers. In fact the large number of cases of environmental heritages concerning soil and groundwater contaminations cannot be ignored. On the other hand soil and groundwater legislations impose progressively stricter limits on the acceptable concentrations. SPECIFIC AIMS: Identify, recognize and characterize soil and groundwater contaminations; previous selection of the most convenient technologies to remediate a contaminated site; detailed evaluation of the alternatives; Main parameters for design; Control and monitoring of the remediation action plan. PREVIOUS KNOWLEDGE: EA0008 Environmental Geology EA0007 Environmental Chemistry I EA0012 Environmental Chemistry II EA0006 Mathematical Analysis I EA0011 Mathematical Analysis II EA0028 Heat and Mass Transfer PERCENTUAL DISTRIBUTION Scientific Component (establishes and develops scientific bases) – 30% Technological component (applies to design and process operation) – 30%. LEARNING OUTCOMES: At the end of this subject the students will be able to: - Chose the feasible alternatives for remediating a site with contaminated soil and/or groundwater; - Establish the methodology and procedures for designing a corrective action plan. - To design in-situ experiments in order to gather information for the full design; - Design a full scale process; - Design the monitoring system in order to verify the non-existence of perverse effects.
Ability to
- characterize the dispersion of a subsoil contamination;
- select the most appropriate rehabilitation technologies;
- to determine the most relevant project parameters;
- anticipate and project monitoring technology;
- develop a Corrective action plan.
Review of fundamental concepts of environmental chemistry; Transport and fate of contaminants in subsoil; Review of Basic Concepts of Environmental Chemistry – Multiphase Equilibrium; Transport and Fate of Contaminants in the subsoil; Introduction to Environmental Risk Analysis and Brief Notions of Toxicology; Impermeable and Permeable Reactive Barriers; Natural Atenuation as a type of Remediation; Biological Technologies: Landfarming; Biological Piles; bioventing, bio-sparging, enhanced in-situ bioremediation, Phyto-Remediation Physical Technologies: Soil-Vapour Extraction; Air Sparging; Dual Phase Extraction ; Electrokynetics ; soil washing and soil flushing ; Thermal Technologies : Low Temperature Thermal Dessorption ; Chemical Technologies: (ISDCO) In-Situ Chemical Oxidation and Extraction with Super-Critical Fluids; Groundwater Treatment: Pump and Treat; Air Stripping.
First the students review the main concepts related to multi-phase equilibrium of chemical systems and new concepts (partition coefficients) are introduced for environmental systems. As next step the students are learn the different transport and fate mechanisms in the subsoil. As all the remediation should be justified by a Risk Analysis in the next step the basic concepts of Toxicological Quantitative Risk Analysis are introduced. As next step the students are introduce to several remediation technologies chosen according to several criteria such as dissemination, in-situ, off-site, physical, thermal, chemical and biological alternatives that allow to remediate contaminations originated by different pollutants: mainly organics and heavy metals. In the application classes students solve problems related to the design of remediation systems.
Designation | Weight (%) |
---|---|
Exame | 95,00 |
Participação presencial | 5,00 |
Total: | 100,00 |
Designation | Time (hours) |
---|---|
Estudo autónomo | 56,00 |
Frequência das aulas | 56,00 |
Total: | 112,00 |
To be admitted to exams, students have to attend 75% of the theoretical-practical and practical classes.
0,95 * Classification of Final Exam + 0.05 Attendence (0ver the minimum of 75%)
Not applicable
2nd period of examinations.
This course unit is complemented by e-learning.