Organic Chemistry 1 (CHE 111) Lecture Notes PDF

Summary

These lecture notes cover fundamental concepts in organic chemistry, including molecular structure, chemical bonding, and applications in biomedical engineering. The document outlines course objectives, contents, and evaluation procedures for a course titled "Organic Chemistry 1 (CHE 111)" at the Alexandria University. It includes key references for further study.

Full Transcript

 Lecturer: Alexndria University.
Taghreed Faculty of Engineering
M.M.Z., prof. Specialized Scientific Programs
Dr Biomedical Engineering BME

Organic chemistry 1 (CHE 111)
 1-P.Y.Bruice “Organic Chemistry” eighth
edition,2016,Pearson, USA

2-T.W. Graham Solomons “Organic
Course Chemistry” 11 th Ed., 2014, John Wiley, New
References: York., USA

3-Francis A. Carey “Organic Chemistry “
ninth edition, 2014, Mc Graw Hill, NY,USA

4-William H. Brown “Organic Chemistry” 8
th Ed., 2018, Cengage Learning, USA

5-Michael B. Smith, Biochemistry
An Organic Chemistry Approach,2020,
Taylor & Francis Group, LLC,NY,USA
Team code

0xh0kgc
Course objectives
Have an idea about basic concepts of molecular
Have structure, chemical bonding, molecular geometry,
resonance, isomerism and acid-base chemistry.
Know main functional groups of organic
Know compounds families and study their physical
and chemical properties

Major
Major chemical reactions and mechanisms
associated with each family

Know Know important applications of organic
chemistry in biomedical engineering

Acquire Acquire experimental experience in handling
and identifying organic compounds.
 Course contents

Carbon Representative Alkanes &
Compounds and Carbon Alkenes &
Chemical Bonds Compounds Alkynes

Aromatic
Alcohols phenols
compounds
 Evaluation procedures
First mid term 12.5

Second mid term 12.5

Lab 15

Lect. attendance& quizzes 10

Final 50
Chapter 1
Carbon
Compounds
and Chemical
Bonds
 -Define organic chemistry
and its importance.

-Types of chemical bonds
Learning
Objectives - How to represent
organic molecules.

-Resonance theory.
Definition:-
Organic chemistry is the study of hydrocarbons (compounds of
carbon and hydrogen) and their derivatives
Organic chemistry and life

We are central role in The food that pesticides, serious
composed medicine, we eat and the paints, environmental
mainly of bioengineerin clothes that adhesives, and problems.
organic g, we wear are plastics are all (organic
compounds. nanotechnolog comprised of made from refrigerants,
(e,g DNA, y, etc. organic organic synthetic,
protein compounds. compounds dyes)
enzymes,
vitamins)
 Biological Relevance
❑Bioorganic compounds are organic compounds
found in living systems such as carbohydrates,
fats, proteins, nucleic acids, enzymes, and
hormones—
❑Many of these compounds are larger than the
organic compounds
❑ They often have more than one functional group,
❑But the principles that govern their structure and
reactivity are essentially the same as those that
govern the structure and reactivity of the organic
compounds
Common examples of bioorganic
compounds
include the sugar sucrose
(C12H22O11), vitamin B2
(C117H120N4O6), cholesterol
(C27H46O.
)and DNA, which stores genetic
information, has molecular weights that
range 3 million to 2 billion.
Currently, there are about 16 million known
organic compounds.

Why are there so many carbon-containing
compounds? The answer lies in carbon’s
position in the periodic table.

Carbon is in the center of the second row of elements.
We will see that the atoms to the left of carbon have a
tendency to give up electrons, whereas the atoms to
the right have a tendency to accept electrons
 Because carbon is in the middle, it neither readily
gives up nor readily accepts electrons.
Carbon can share electrons with several kinds of
atoms as well as with other carbon atoms.
Organic compounds consist of atoms held together
by covalent bonds.
When an organic compound reacts, some of these
covalent bonds break and some new covalent bonds
form.
Let us review how the elements of C, H, O, halogens
and N combine by sharing electron pairs to form
bonds, and ultimately molecules.
Electronic
configurati
on of the
first ten
elements
❑ The major factor that determines the chemical
behavior of an element is the number of
valence electrons it has.
❑ Valence electrons are electrons in an atom’s
outermost shell. for example, carbon has four
valence electrons.
❑ Valence electrons participate in chemical
bonding
Study problem
How many valence electrons does each of the
following atoms have?
(a) Na (b) Cl (c) Si (d) B (e) Ne (f) N
Types of chemical bonds: "The OCTET Rule"
Atoms form bonds to produce the electron
configuration of a noble gas (because the electronic
configuration of noble gases is particularly stable).
For all the noble gases except helium, this means
achieving an octet of electrons in the valence shell.
Atoms close to helium achieve a valence shell
configuration of 2 electrons, such as H, Li, Be
We call the tendency for an atom to achieve a
configuration where its valence shell contains eight
electrons the octet rule
 An atom may lose or gain
enough electrons to
acquire a filled valence
Atoms form bonds to shell
produce the electron
configuration of a noble
gas An atom may share
electrons with one or
more other atoms to
acquire a filled valence
shell.
Covalent bond:
A covalent bond consists of the mutual sharing
of one or more pairs of electrons between two
atoms. These electrons are simultaneously
attracted by the two atomic nuclei

Shared electrons located in the
space between the two nuclei
are called bonding electrons.

The bonded pair is the “glue”
that holds the atoms together
in molecular units.
 Test yourself (1): What is the electron
configuration of C+ and C- Does either
one of these ions have a noble gas
(closed-shell) electron configuration?
The ionization energy of carbon is too
large and the electron affinity too small
for carbon to realistically form a C+ or C-
Nonpolar and polar covalent bonds

Covalent bonds Nonpolar EN