KE553: Heterocyclic chemistry

Comment

The course is co-read with: the corresponding master course KE835 ( former KE823).
If you plan to attend both Hterocyclic chemistry (KE553/KE835) and Advanced organic synthesis (KE518/KE814) in your complete study program, we recommend that you first attend KE553/KE835 or that you attend the two courses simultaneously.

Entry requirements

The course cannot be chosen if you have passed, registered, or have followed KE526, KE823 or KE835, or if KE526, KE823 or KE835 is a constituent part of your Curriculum.

Academic preconditions

Students who attend the course are expected to:

be familiar with physical and organic chemistry including the structure and reactions of organic molecules as well as the concept of pH and thermodynamics.
have experience with the use of reaction mechanisms

KE505: Organic chemistry (10 ECTS), KE521: Chemistry of the elements (5 ECTS) or KE528: Introductory Inorganic Chemistry (5 ECTS) and KE537: Microscopic and macroscopic physical chemistry are required to be known.
Similar courses in organic and physical chemistry, such as organic chemistry and physical chemistry on the engineer degree programme in chemistry and biotechnology, can also provide the academic prerequisites.

Course introduction

The aim of the course is to make the students familiar with heterocyclic compounds and their importance in modern organic chemistry - including the synthesis of the most common heterocycles and their chemical properties.

The course is based primarily on the skills acquired in the course KE505 or equivalent with a systematic examination of the organic chemistry. The course is based on the fact that the students are in the third year of studies for a degree in chemistry, pharmacy, or chemical engineering, so that they can relate the course to other disciplines in chemistry, for example medicinal chemistry, spectroscopy, chemical engineering, physical chemistry, or inorganic chemistry.

In relation to the education competence profiles, the course has a particular focus on expanding and improving the students’ basis for planning organic syntheses and to apply reaction mechanisms within modern organic chemistry.

Hereby the course contributes with concrete knowledge about

the basic knowledge formation of chemistry and experimental methods within organic chemistry,
current topics within modern chemistry research,
the ability to understand and reflect on theories, methods and practices within the field of chemistry,
the ability to acquire knowledge in an efficient and independent manner and the ability to apply this knowledge in a reflective way, as well as skills to apply methods for investigating specific chemical phenomena theoretically and / or experimentally, as well as competencies to identify one's own learning needs and structure one's own learning in different learning environments.

Expected learning outcome

The learning objectives of the course is that the student demonstrates the ability to:

provide names for simple aliphatic and aromatic heterocycles
use reaction mechanisms to predict the formation of selected heterocyclic compounds
explain and account for the reactivity of selected heterocyclic compounds
explain
examples of applications of selected heterocyclic compounds in for
example medicinal chemistry and supramolecular chemistry

Content

The following main topics are contained in the course:

General nomenclature of heterocyclic compounds.
Synthesis
and chemical properties of heterocyclic compounds including pyrroles,
furans, thiophenes, various five-membered heterocycles with several
heteroatoms, pyridines, diazines and annullated heterocycles.
Use of reactions mechanisms to account for the formation of heterocyclic compounds
Examples of applications of heterocycles in for example medicinal chemistry and supramolecular chemistry.

Literature

John A. Joule and Keith Mills: Heterocyclic Chemistry at a Glance, 2nd Edition
Other material will be communicated via itslearning.

Examination regulations

Exam element a)

Timing

June

Tests

Oral exam

EKA

N530051102

Assessment

Second examiner: External

Grading

7-point grading scale

Identification

Student Identification Card - Name

Language

Normally, the same as teaching language

Duration

30 minutes (+ 60 minutes preparation)

Examination aids

To be announced during the course

ECTS value

Indicative number of lessons

40 hours per semester

Teaching Method

At the faculty of science, teaching is organized after the three-phase model ie. intro, training and study phase. These teaching activities are reflected in an estimated allocation of the workload of an average student as follows:

Intro phase (lectures) 30 hours
Training phase: 12 hours

In the study phase, students are expected to work on their own with the textbook and examples herein. It also includes preparation of written exercises as a key element in the study phase. The students will independently search for and read research papers. The students are also expected to use part of the study phase to pick up on the content of training phase and to reserve a small amount of time for repetition for the oral exam.

Activities during the study phase:

Self-study of the textbook
Written hand-in exercises
Search in scientific literature
Repetition for the exam

Teacher responsible

Name	E-mail	Department
Poul Nielsen	pouln@sdu.dk	Det Naturvidenskabelige Fakultetssekretariat

Timetable

Odense

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Administrative Unit

Fysik, kemi og Farmaci

Team at Registration

NAT

Offered in

Odense

Recommended course of study

Profile	Education	Semester	Offer period
BSc Major in Chemistry - registration 1 September 2021	\| Odense	4	E24
BSc Major in Chemistry with specialization in Medicinal Chemistry - registration 1 September 2022, 2023 and 2024	\| Odense	4	E24

Transition rules

Transitional arrangements describe how a course replaces another course when changes are made to the course of study.

If a transitional arrangement has been made for a course, it will be stated in the list.

See transitional arrangements for all courses at the Faculty of Science.