Studienhandbuch | VL Lecture on Green and Sustainable Chemistry

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[ 863ADCHGSCV24 ] VL ^(*)Lecture on Green and Sustainable Chemistry

Versionsauswahl

^(*) Leider ist diese Information in Deutsch nicht verfügbar.

Workload	Ausbildungslevel	Studienfachbereich	VerantwortlicheR	Semesterstunden	Anbietende Uni
3 ECTS	M1 - Master 1. Jahr	Biologische Chemie	Wolfgang Schöfberger	2 SSt	Johannes Kepler Universität Linz

Detailinformationen
Quellcurriculum	Masterstudium Biological Chemistry 2024W
Ziele	^(*)1. To appreciate the history of chemical accidents and how Green Chemistry can be used to design safer products and industrial systems without harming the environment and subsequent human health. 2. To understand the historical and current role of chemicals in our society and economy. 3. To qualitatively and quantitatively examine the impacts on human health and the environment of chemical products and processes. 4. To recognize the tools available to scientists and engineers in the design and synthesis of new chemical products and processes including energy efficiency. 5. To have a basic knowledge of toxicity and the molecular basis of hazard. 6. To analyze the efficiency of various approaches to chemical design. 7. To understand the transformational role of Green Chemistry in the global economy and the associated material and energy benefits.
Lehrinhalte	^(*)Why Green Chemistry? - Current Problems • Ecosystems • Lithosphere (Waste, resource depletion) • Atmosphere (CO2, Ozon, three-way catalysis in automobile…) • Hydrosphere (microplastics, salt, desalination, heavy metals) • Biosphere (toxicity) • Energy (renewable) What is Green Chemistry? • The Twelve Principles of Green Chemistry • Green Metrics Solvents • Synthesis in water and benign solvents • Ionic liquids • Supercritical solvents • No solvent at all - mechanochemistry Alternative Synthesis Concepts • Mechanochemistry • Photochemistry (TiO2, water splitting, photooxidation in water treatment) • Microwave • Ultrasound • Flow reactor • Continuous manufacturing • Metal-free syntheses • Biological syntheses Catalysis (homogeneous and heterogeneous, zeolites) Resources • Alternative feedstock • Upcycling of waste and use of waste products • Using natural resources: problems and prospects • Biomass (biomass-derived reactants, biofuels, bioreforming) • Waste reduction • Synthesis using green reagents • Metals (Li, raw earthes) • Chemical degradation and reuse Products • Design of safer chemicals (drugs, toxicity, pesticides, reducing carcinogenity, etc. reducing ecotoxicity,(book 9) • Sustainable materials (polymers, inorganic materials, footprint) • New technologies (solar, supercap, energy storage) Evaluate the Synthesis • Tools for green chemistry (estimate fate, exposure, effect of chemicals) • Concept of life cycle assessment • How to Plan a Green Synthesis (DOE)
Beurteilungskriterien	^(*)Written exam at the end of the semester. The exams will be closed-book and closed-note unless otherwise indicated.
Lehrmethoden	^(*)Classical lecture with computer projections and extended blackboard sessions. Homework: Paper reading and presentation. (Each student once a semester).
Abhaltungssprache	Englisch
Literatur	^(*)References are given in the lecture and slides of the lecture will be distributed online. Book “Green Chemistry: Theory and Practice”, Anastas and Warner, Oxford University Press, 1998.
Lehrinhalte wechselnd?	Nein

Präsenzlehrveranstaltung
Teilungsziffer	-
Zuteilungsverfahren	Direktzuteilung