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School of Chemical and Environmental Engineering

Now offering two distinct diplomas: Chemical Engineering and Environmental Engineering

Aquatic Chemistry

1. COURSE INFORMATION:

School Environmental Engineering
Course Level Undergraduate
Course ID ENVE 345 Semester 5th
Course Category Required
Course Modules Instruction Hours per Week ECTS
Lectures and Tutorials 3
Th=2, E=1, L=0
4
Course Type Scientific Area
Prerequisites  
Instruction/Exam Language Greek
The course is offered to Erasmus students No
Course URL https//www.eclass.tuc.gr/courses/MHPER191/   (in Greek)

 

2. LEARNING OUTCOMES

Learning Outcomes

This course details the quantitative treatment of chemical processes in aquatic systems such as lakes, oceans, rivers, estuaries, groundwaters, and wastewaters. It includes a brief review of chemical thermodynamics that is followed by discussion of acid-base, precipitation-dissolution, coordination, and reduction-oxidation reactions. Emphasis is on equilibrium calculations as a tool for understanding the variables that govern the chemical composition of aquatic systems and the fate of inorganic pollutants.

Upon successful completion of this course the students will acquire new knowledge and specific skills on the following subjects:

  • To solve chemical thermodynamic equations and to determine the speciation of aqueous solutions of acids, bases, and minerals
  • To construct pH diagrams and titration curves, and solve the Proton Balance, Electroneutrality, and Mass Balance Equations for the speciation of solutions of acids, bases, and minerals
  • To determine the solubility of dissolved carbon dioxide, mineral salts, and metal oxides, hydroxides, and carbonates
  • Predict the behavior of environmentally important inorganic components under typical environmental conditions.
  • Apply knowledge of the behaviors of individual components in a system to explain real-world aquatic environmental systems.
  • Discuss how the presence of individual species, and their interactions, will affect the overall chemistry of a complex environmental system
General Competencies/Skills
  • Review, analyse and synthesise data and information, with the use of necessary technologies
  • Decision making

3. COURSE SYLLABUS

  • Global Biogeochemical Cycles
  • Determination of natural water pH
  • Carbon Equilibrium
  • Chemical species in solution
  • Regulating tension and neutralization ability
  • Creation of natural waters composition
  • Law of mass action-Determination of equilibrium constants
  • Chemical activity and ionic strength
  • Fate of metals in the environment
  • Hydrolysis and metals complexation
  • Inorganic compounds as substituents
  • Competitive binding of substituents
  • Interaction of aquatic solutions with sediments and soils
  • Solubility and Absorption
  • Effect of chemical species in the solubility
  • Surface complexes formation
  • Redox geochemistry
  • Heterogeneous reactions and cycles
  • Redox equilibrium
  • Capacity and redox volumetric measurements (pH scale)
  • Applications of environmental geochemistry.

4. INSTRUCTION and LEARNING METHODS - ASSESSMENT

Lecture Method Direct (face to face)

Use of Information and Communication Technology

  • Power point presentations
  • E-class support
Instruction Organisation Activity Workload per Semester
(hours)
- Lectures 26
- Tutorials 13
- Autonomous study 61
Course Total 100

Assessment Method

Ι) Written final examination (100%):
- Questions of theoretical knowledge.
- Theoretical problems to be resolved.

5. RECOMMENDED READING

  • Aquatic Chemistry: Chemical Equilibria and Rates in Natural Waters, Werner Stumm, James J. Morgan
  • Water Chemistry, Vernon L. Snoeyink, David Jenkins

6. INSTRUCTORS

Course Instructor: Professor E. Psillakis (Faculty - EnvEng)
Lectures: Professor E. Psillakis (Faculty - EnvEng)
Tutorial exercises: Professor E. Psillakis (Faculty - EnvEng)
Laboratory Exercises: