230030 Terrestrial Environmental Chemistry

Ansvarligt institutInstitut for Grundvidenskab og Miljø

English TitleTerrestrial Environmental Chemistry
Tidligst mulig placeringKandidat 1.år til Kandidat 2. år
VarighedEn blok
Pointværdi7.5 (ECTS)

skriftlig prøve

Skriftlig auditorieeksamen

Alle hjælpemidler tilladt

Beskrivelse af eksamen: Report from project work 4 hours written exam.

Vægtning: Case study report: 33 % Written exam: 67 %

7-trinsskala, intern censur
Forudsætninger for indstilling til eksamenCompletion of project work (report + oral presentation)
Rammer for UndervisningThe course comprise lectures, theoretical exercises, computer modelling exercises, laboratory exercises, project work and two excursions. The course has teaching elementes together with the course in Aquatic Environmental Chemistry (FARMA-KU) - see below
BlokplaceringBlock 3
Ugestruktur: C
Exercises and lectures usually occur together

Anbefalede forudsætninger250021 
Course in "Soil, water and plants" or equivalent "Environmental Chemistry of Biological Systems" or equivalent. Basic knowledge in chemistry, physics, mathematics and microbiology. Introduction to physical chemistry will be helpful
Begrænset deltagerantalNone
Brief review of soils, including chemical composition and properties of soil minerals and humic matter and emphasizing the characteristics of soil particle surfaces. Natural soil forming processes affecting soil pollutants such as acidification, clay migration, redox processes and leaching including interactions between abiotic and soil biochemical processes. Characterization of microbial degrader populations in soil and groundwater. Sampling, fractionation and analysis of soil and soil solutes emphasizing the importance of spatial variation of pollutant degradation and sorption in soils.

Review of pollutants in soil environments with emphasis on biogeochemical properties, monitoring data and mass balances for pollutants including heavy metals, radionuclides, acids, pesticides, endocrine disruptors, detergents, PAH's, halogenated compounds, veterinary drugs/biomedicine, natural toxins, anthropogenic nanoparticles and microbial contaminants. Activity and mode of action of soil enzymes and soil microorganisms. Metal solubility, complexation and speciation in soil solution. Sorption (pollutant binding) processes including ion exchange, surface complexation (specific sorption) and partitioning into organic matter. The effect of ageing and sesquestration with respect to bioavailability and degradation. Reactions at particle surfaces including engineered nanoparticles. Redox processes, zonations and sequences. Degradation pathways, formation of metabolites, and models to quantify biodegradation and -mineralization kinetics. Macropores and colloidal transport. Software for computing speciation and for QSAR estimation of pollutant properties. Modelling of water and solute transport using state-of-the art software (DAISY) integrating degradation kinetics, sorption, climate, land use and transport properties. Integration of soil chemical, physical and microbiological properties into soil quality assessment with focus on soils as filters.

Cleaning and remediation of polluted soils with emphasis on bioremediation technologies such as enhanced microbial degradation of organic pollutants, bioaugmentation (use of introduced microorganisms for degradation), phytoremediation (use of plants to degrade or absorb pollutants) and use of biodetergents and bioligands for pollutant leaching.

Some topics will be taught together with the course in Aquatic Environmental Chemistry (FARMA-KU) running in the same block (module A). This mainly comprise lectures and theoretical exercises on soil and water pollution, biodegradation kinetics/pathways, metal speciation, equilibrium computation and redox processes.
Lectures, theoretical exercises, laboratory exercises, computer computations and project work. Two half-day excursions comprising examples of soil pollution, soil remediation, land use and groundwater monitoring. Lectures are based on the textbook(s) used. The topics of the theoretical exercises run in parallel with the topics presented in the lectures. The laboratory exercises is coordinated with DAISY modelling and project work. Computer computations comprise QSAR computation of pollutant properties, equilibrium speciation and transport modelling (DAISY). Transport properties of soils are mainly taught through "hands-on" computer exercises. Groups of students work together to discuss and solve the selected theoretical, laboratory and computer exercises. The project work focus on describing contemporary examples of water and soil pollution and the technologies used to clean soil and waters. The projects draw on the general insight in chemical, biological and physical processes presented in this course. Each project is solved by groups of students and it is presented as a report and an oral presentation.
The objectives of the course are to comprehend and to study i) how soils respond to man-made disturbances, ii) soils as "filters", i.e. the efficiency of soils to degrade, neutralise and sorb environmental pollutants, iii) fate of pollutants in a terrestrial systems, iv) quantification of soil processes for assessment, modelling and forecasting the fate of pollutans in soil and groundwater, and v) new technologies for cleaning soils and groundwater.

After completion the course the student should be able to:
- Classify and show overview of main inorganic and organic pollutants in terrestrial ecosystems, and to present knowledge on the relationships between land use and soil/groundwater quality
- Describe key properties and processes of pollutants critical for sorption, degradation, bioavailability and transport of pollutants in terrestrial systems
- Classify and summarize the molecular mechanisms controlling pollutant degradation/transformation and bonding in soils and water
- Describe analytical procedures and monitoring strategies for pollutants in terrestrial systems
- Identify and reflect about the main strategies for soil and groundwater remediation

- Apply and demonstrate the use of general principles from chemistry, physics and microbiology in environmental chemistry
- Compute chemical and physical properties of pollutants and pollutant fate in terrestrial ecosystems
- Quantify pollutant sorption, degradation and transport using different types of models and calculus
- Apply and evaluate procedures for soil and groundwater cleaning (remediation)
- Retrieve and critical examine environmental chemical data
- Make reports on pollutant fate and remediation in terrestrial environments

- Combine data and information from different sources in calculus, prediction and evaluation of pollutant mass balances, distribution, fate and effects in terrestrial systems
- Diagnose the processes critical for the fate of any pollutant, and critical selection of tools for analysis and evaluation
- Propose, analyse and assess the use of different remediation technologies and strategies for clean-up of simple and complex pollutant scenarios
- Discuss and assess the complexity of how modern agrotechnology, land use and management affect soil and groundwater quality
Hansen, H.C.B. (ed)(2010) Soil Pollutions: Biogeochemistry and Modelling - including exercises.
Schwarzenbach, R.P. et al. (2005) Environmental Organic Chemistry, 2nd. Ed., Wiley, chapt. 14
Laboratory manual
Handout notes and journal papers.

Software for speciation analysis.
Software for QSAR estimation of pollutant properties
Software for transport modelling (DAISY)

Excursion material
Hans Chr. Bruun Hansen, haha@life.ku.dk, Institut for Grundvidenskab og Miljø, Tlf: 353-32418
Søren Hansen, sha@life.ku.dk, Institut for Grundvidenskab og Miljø/Agrohydrologi, Tlf: 353-33386
Peter Engelund Holm, peho@life.ku.dk, Institut for Grundvidenskab og Miljø, Tlf: 353-32414
Carsten Suhr Jacobsen, csj@geus.dk, Institut for Grundvidenskab og Miljø/Jordbunds- og miljøkemi, Tlf: 38142313
A small fee for participation in the excursion may be requested.
Studienævn NSN
teoretiske øvelser51