Teacher(s)
Language
French
Prerequisites
General knowledge in soil science : texture, structure, composition, etc.
Main themes
- Characteristics of a porous medium
- Water retention and water potential in soils
- Flow of water in saturated and unsaturated media
- Techniques for characterizing water content, water potential and hydraulic conductivity
- Introduction to solute transfer
- Transfer of gas and heat in soils
- Soil Mechanics
- Water retention and water potential in soils
- Flow of water in saturated and unsaturated media
- Techniques for characterizing water content, water potential and hydraulic conductivity
- Introduction to solute transfer
- Transfer of gas and heat in soils
- Soil Mechanics
Learning outcomes
At the end of this learning unit, the student is able to : | |
1 | a. Contribution de l'activité au référentiel AA (AA du programme) M1.2 ; M1.4 ; M2.2 ; M2.3 ; M2.4 ; M6.5 ; M6.8 b. Formulation spécifique pour cette activité des AA du programme At the end of the course, the student will be able to: - Explain the factors that determine the physical properties of soil - Master the basic techniques of characterization of soil physical properties - Explain the impact of soil physical properties on the retention and flow of water, the transfer of gas, heat and dissolved substances, and mechanical properties of soils - Establish the profiles of total water potential from baseline data - Establish the basis for modeling the dynamics of soil water in space and time, and applying Darcy's equation to estimate steady water flow - Associated with a given type of soil, depending on texture and structure, the physical properties that correspond to it, and interpret soil physical data - Describe the principle of operation, advantages and disadvantages of conventional methods and instruments used for the characterization of soil physical properties - Extract soil samples in situ and characterize the basic hydraulic properties in the laboratory - Write a report according to scientific standards and critically and consistently analyze results - Contribute effectively to collegial data acquisition, analysis and writing of the results and conclusions. |
Content
Lectures :
- Reminder regarding the characteristics of a porous medium
- Retention of water in soil, capillarity, water retention, hysteresis
- Potential of water in soils: gravitational, matrix, hydrostatic, overburden, osmotic, barometric potential
- Techniques for characterizing water content and water potential
- Water flow in soils under steady saturated and unsaturated conditions : laws of Poiseuille, Darcy Equation and Richards equation
- Techniques for characterizing the hydraulic conductivity curve
- Equation of water transport in soil: Examples of analytical solutions
- Introduction to solute transport in soils
- Transfer of gas and heat in soil : processes
- Mechanical properties of soils , compaction, and characterization techniques
Practicals :
- Sampling of soil
- Measurement of bulk density
- Measurement of infiltration : constant head infiltrometer and permeameter
- Characterization of the water retention curve
- Calculation of water potentials
- Calculation of water balance
- Reminder regarding the characteristics of a porous medium
- Retention of water in soil, capillarity, water retention, hysteresis
- Potential of water in soils: gravitational, matrix, hydrostatic, overburden, osmotic, barometric potential
- Techniques for characterizing water content and water potential
- Water flow in soils under steady saturated and unsaturated conditions : laws of Poiseuille, Darcy Equation and Richards equation
- Techniques for characterizing the hydraulic conductivity curve
- Equation of water transport in soil: Examples of analytical solutions
- Introduction to solute transport in soils
- Transfer of gas and heat in soil : processes
- Mechanical properties of soils , compaction, and characterization techniques
Practicals :
- Sampling of soil
- Measurement of bulk density
- Measurement of infiltration : constant head infiltrometer and permeameter
- Characterization of the water retention curve
- Calculation of water potentials
- Calculation of water balance
Teaching methods
- Classes, largely illustrated by photos, schematics and exercices
- Inverted classrooms, based on Videos from the MOOC 'L'eau et le sol' (in French) (water retention and flow in soils)
- Practicals in the lab and in the field
- Exercise solving sessions
- Inverted classrooms, based on Videos from the MOOC 'L'eau et le sol' (in French) (water retention and flow in soils)
- Practicals in the lab and in the field
- Exercise solving sessions
Evaluation methods
Report of practicals (40%). A penalty will be applied in case of unjustified absence. The score will be weighted (33%) according to personal involvement based on a Dynamo evaluation.
Oral exam based on solving of exercises (written preparation, 2h, open-book - computer not allowed) (40%)
Oral exam based on 3 theoretical questions (no préparation, questions available before the exam via Moodle) (20%)
Oral exam based on 3 theoretical questions (no préparation, questions available before the exam via Moodle) (20%)
Online resources
Moodle
MOOC "L'eau et le sol"
MOOC "L'eau et le sol"
Bibliography
Ouvrage de référence :
- "Environmental Soil physics", D. Hillel
- Transparents des cours sur iCampus
- MOOC "L'eau et le sol" (EDX)
- "Environmental Soil physics", D. Hillel
- Transparents des cours sur iCampus
- MOOC "L'eau et le sol" (EDX)
Teaching materials
- Transparents sur Moodle
Faculty or entity
Programmes / formations proposant cette unité d'enseignement (UE)
Title of the programme
Sigle
Credits
Prerequisites
Learning outcomes
Master [120] in Civil Engineering
Master [120] in Forests and Natural Areas Engineering
Master [120] in Environmental Bioengineering
Master [120] in Chemistry and Bioindustries
Master [120] in Agriculture and Bio-industries
Master [120] in Agricultural Bioengineering