Week 3_Atoms and Elements CHEM1010 (1).pdf

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CHEM 1010
General Chemistry I

Week 3. Atoms and Elements
 Week 3: Atoms and Elements

Objectives:
1. Explain the structure of an atom
2. Give the symbol and name of the element mentioned in this course
3. Carry out calculations involving the determination of the number of
protons, electrons and neutrons in a given isotope
4. Identify the groups and period to which an element belongs
5. Identify regions of the periodic table (metals, metalloids, nonmetals,
alkali metals, alkaline earth metals, and transition metals)
6. Use isotopic masses and natural abundance to calculate the average
atomic masses

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 If You Cut a Piece of Graphite…

How far could you go?

Could you divide it forever?

Smaller pieces (far smaller than the eye could see) would
eventually yield individual carbon atoms

You cannot divide a carbon atom into smaller pieces and
still have carbon

Atoms are the key to connecting the macroscopic and
microscopic worlds

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 Atoms

An atom is the smallest identifiable unit of an element
About 91 different naturally occurring elements + over 20
synthetic

Salt
Copper
NOT an element
An ELEMENT
(made of sodium and chlorine)

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 2.3 Modern Atomic Theory and the
Laws That Led to It

The theory that all matter is composed of atoms grew out of
observations and laws

The three most important laws that led to the development and
acceptance of the atomic theory were

1. the law of conservation of mass
2. the law of definite proportions
3. the law of multiple proportions

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 The Law of Conservation of Mass
Antoine Lavoisier formulated the law of conservation of
mass
In a chemical reaction, matter is neither created nor
destroyed
The total mass of the substances involved in the reaction
does not change

The law is consistent with
the idea that matter is
composed of small,
indestructible particles.

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Concept Check

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 The Law of Definite Proportions

Joseph Proust formulated the law of definite proportions in
1797
All samples of a given compound always have the same
proportions of their constituent elements
Also called the law of constant composition

Illustration
The decomposition of 18.0 g of water results in 16.0 g
of oxygen and 2.0 g of hydrogen, or an oxygen-to-
hydrogen mass ratio of:
16.0 g O
Mass
= ratio = 8.0 or 8:1
2.0 g H

For ammonia (NH3), the mass ratio is 14.0 g:3.0 g
i.e. 4.7:1 8
 Concept Check

We just saw that the mass ratio of nitrogen to hydrogen in
ammonia is 4.7:1. If a sample of ammonia contains 10.0 grams
of H, how many grams of N does it contain?

a. 4.7 b. 9.4 c. 14 d. 47

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 The Law of Multiple Proportions

In 1804, John Dalton published his law of multiple proportions
When two elements A and B form two different compounds,
the masses of B that combine with a fixed mass of A can be
expressed in small whole number ratios
An atom of A combines with either one, two, three, or more
atoms of B (AB1, AB2, AB3, etc.).

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 The Law of Multiple Proportions

Carbon monoxide and carbon dioxide are two compounds
composed of the same two elements: carbon and oxygen.
The mass ratio of oxygen to
carbon in carbon dioxide is
2.67:1; therefore, 2.67 g of
oxygen reacts with 1 g of carbon

In carbon monoxide, however,
the mass ratio of oxygen to
carbon is 1.33:1, or 1.33 g of
oxygen to every 1 g of carbon
Mass oxygen to 1 g carbon in carbon dioxide 2.67
= = 2
Mass oxygen to 1 g carbon in carbon monoxide 1.33
Ratio of ratios! 11
Example 2.2 Law of Multiple Proportions
Nitrogen forms several compounds with oxygen, including nitrogen dioxide and dinitrogen monoxide. Nitrogen
dioxide contains 2.28 g oxygen to every 1.00 g nitrogen, while dinitrogen monoxide contains 0.570 g oxygen to every
1.00 g nitrogen. Show that these results are consistent with the law of multiple proportions.

Solution
Calculate the ratio of the mass of oxygen from one compound to the mass of oxygen in the other. Always divide the
larger of the two masses by the smaller one.

The ratio is a small whole number (4); these results are consistent with the law of multiple proportions.

For Practice 2.2
Hydrogen and oxygen form both water and hydrogen peroxide. The decomposition of a sample of water forms
0.125 g hydrogen to every 1.00 g oxygen. The decomposition of a sample of hydrogen peroxide forms 0.0625 g
hydrogen to every 1.00 g oxygen. Show that these results are consistent with the law of multiple proportions.

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 John Dalton and the Atomic Theory

Dalton’s atomic theory explained the laws as follows:

1. Each element is composed of tiny, indestructible particles
called atoms.
2. All atoms of a given element have the same mass and
other properties that distinguish them from the atoms of
other elements.
3. Atoms combine in simple, whole-number ratios to form
compounds.
4. Atoms of one element cannot change into atoms of
another element. In a chemical reaction, atoms only
change the way that they are bound together with other
atoms.

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The Structure of the Atom

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 Nucleus

NUCLEUS: the hard center of an atom
Contains protons and neutrons only
Electrons stay outside the nucleus
Even though it has 99% of the atom’s mass, it is very small

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 Electron

Outside the nucleus
Has a mass of almost 0
9.11x10-31 kg
Has a negative charge
The movement of electrons
is responsible for almost all
chemistry

Electrons

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 Protons vs Neutrons

Proton Neutron
Inside the nucleus Inside the nucleus
1000x more mass than an 1000x more mass than an
electron electron
POSITIVE charge NEUTRAL (no) charge

Neutrons
Protons (n0)
(p+)

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 2.6 Subatomic Particles

The charge of the proton and the electron are equal in
magnitude but opposite in sign
The neutron has no charge

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 Elements: Defined by Their Numbers of
Protons
The most important number to the identity of an atom is the
number of protons in its nucleus
The number of protons defines the element
The number of protons in an atom’s nucleus is its atomic
number and is given the symbol Z

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Periodic Table of the Elements

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Periodic Table of the Elements
 Periodic Table

 Each element has its own unique name and CHEMICAL
SYMBOL
1 or 2 letters
o First letter is always capital
o If there is a second letter, it is lower-case

C O Co CO
X
 Periodic Table

 CHEMICAL SYMBOLS may come from the
element’s English or original Latin/Greek name

C - Carbon Au - gold
H - Hydrogen Ag - silver
He - Helium Hg - mercury
Au: gold (from Latin “Aurum”)
Ag: silver (from Latin “Argentum”)
Hg: mercury (from Greek “Hydrargyrum”)

Note: You must remember the names and symbols of common
elements. The list of these elements are available on your D2L
account in the course resources module.
 Concept Check

Which element contains 50 protons in its nucleus?
a. tin
b. vanadium
c. manganese
d. fermium

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 Isotopes: When the Number of Neutrons
Vary
All atoms of a given element have the same number of protons

They do not necessarily have the same number of neutrons

For example: all neon atoms contain 10 protons, but they may
contain 10, 11, or 12 neutrons

All three types of neon atoms exist, and each has a slightly
different mass 20 21 22
10 Ne10Ne10 Ne
Atoms with the same number of protons but a different number
of neutrons are called isotopes

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 Isotopes: When the Number of Neutrons
Vary
The relative amount of each different isotope in a naturally
occurring sample of a given element is roughly constant

These percentages are called the natural abundance of the
isotopes

Advances in mass spectrometry have allowed accurate
isotopic mass measurements

20 21 22
10 Ne10Ne10 Ne

Ne-20 Ne-21 Ne-22
neon-20 neon-21 neon-22
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 Isotopes: Varied Number of Neutrons

Symbol Number of Number of A (Mass Natural
Protons Neutrons Number) Abundance (%)
10 10 20 90.48
N e 20, or super 20 sub 10 N e

Ne
10 11 21 0.27
N e 21, or super 21 sub 10 N e

Ne
10 12 22 9.25
N e 22, or super 22 sub 10 N e

Ne

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 Concept Check

An argon isotope has a mass number of 40 (A = 40). How
many neutrons does it contain?

a. 40
b. 18
c. 22
d. 20

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 Concept Check

Carbon has two naturally occurring isotopes: C-12 (natural
abundance is 98.93%) and C-13 (natural abundance is 1.07%). If
circles represent protons and squares represent neutrons, which
image best represents the C-13 isotope?

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 Ions: Losing and Gaining Electrons

The number of electrons in a neutral atom is equal to the
number of protons in its nucleus (Z)

Atoms can lose or gain electrons during chemical change and
become charged particles called ions

Positively charged ions, such as Na+, are called cations

Negatively charged ions, such as F−, are called anions.

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 Concept Check

How many electrons are present in the O2− anion?
a. 2
b. 6
c. 8
d. 10

In light of the nuclear model of the atom, which statement is
true?
a. For a given element, the size of an isotope with more
neutrons is larger than one with fewer neutrons.
b. For a given element, the size of an atom is the same for
all of the element’s isotopes.

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2.7 Finding Patterns: The Periodic Law
and the Periodic Table
The Periodic Law
In 1869, Mendeleev noticed that certain groups of elements
had similar properties
When elements are listed in order of increasing mass, these
similar properties recurred in a periodic pattern
To be periodic means to exhibit a repeating pattern
Mendeleev summarized these observations in the periodic law:
when the elements are arranged in order of increasing
mass, certain sets of properties recur periodically

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 The Periodic Table

Mendeleev organized the known elements
in a table
He arranged the rows so that elements with
similar properties fall in the same vertical
columns
The table contained some gaps, which
allowed him to predict the existence (and
even the properties) of yet undiscovered
elements
Mendeleev predicted the existence of an
element (eka-silicon)
In 1886, eka-silicon was discovered by
Clemens Winkler, who named it germanium

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 Modern Periodic Table Organization

Elements are listed in order of increasing atomic number rather
than increasing relative mass
Contains more elements than Mendeleev’s original table

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 Classification of Elements

Elements in the periodic table are classified as
Metals
Nonmetals
Metalloids

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 Metals
Metals, on the lower-left side and middle of the periodic table,
share some common properties.
Good conductors of heat and electricity
Can be pounded into flat sheets (malleability)
Can be drawn into wires (ductility)
Often shiny
Tend to lose electrons when they undergo chemical changes
Chromium, copper, strontium, and lead are typical metals

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 Non-Metals

Nonmetals lie on the upper-right side of the periodic table
There are a total of 17 nonmetals
Five are solids at room temperature (C, P, S, Se, and I)
One is a liquid at room temperature (Br)
Eleven are gases at room temperature (H, He, N, O, F, N e, C
l, Ar, Kr, Xe, and Rn)
Nonmetals as a whole tend to have these properties:
Poor conductors of heat and electricity
Not ductile and not malleable
Gain electrons when they undergo chemical changes
Oxygen, carbon, sulfur, bromine, and iodine are nonmetals

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 Metalloids

Metalloids are sometimes called semimetals

They are elements that lie along the zigzag diagonal line that
divides metals and nonmetals

They exhibit mixed properties

Several metalloids are also classified as semiconductors

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 Periodic Table
The periodic table can also be divided into:
Main-group elements, whose properties tend to be largely
predictable based on their position in the periodic table
Transition elements or transition metals, whose properties
tend to be less predictable based simply on their position in the
periodic table

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 Periodic Table

The periodic table is divided into vertical columns and
horizontal rows
Each vertical column is called a group (or family)
Each horizontal row is called a period
There are a total of 18 groups and 7 periods.
The groups are numbered 1–18 (or the A and B grouping)
Main-group elements are in columns labeled with a number
and the letter A (1A–8A or groups 1, 2, and 13–18).
Transition elements are in columns labelled with a number and
the letter B (or groups 3–12)

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 Noble Gases

The elements within a group usually have similar properties
The group 8A elements, called the noble gases, are mostly
unreactive
The most familiar noble gas is probably helium, used to fill
buoyant balloons
Helium is chemically stable—it does not combine with other
elements to form compounds—and is therefore safe to put into
balloons
Other noble gases are neon (often used in electronic signs),
argon (a small component of our atmosphere), krypton, and
xenon

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 Alkali Metals

The group 1A elements,
called the alkali metals,
are all reactive metals

A marble-sized piece of
sodium explodes violently
when dropped in water

Lithium, potassium, and
rubidium are also alkali
metals

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 Alkaline Earth Metals

The group 2A elements are called the alkaline earth metals

They are fairly reactive but not quite as reactive as the
alkali metals
Calcium, for example, reacts fairly vigorously with water

Other alkaline earth metals include magnesium strontium,
and barium

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 Halogens

The group 7A elements, the
halogens, are very reactive
nonmetals.
They are always found in nature as
a salt
Fluorine, a pale-yellow gas
Chlorine, a greenish-yellow gas
with a pungent odor
Bromine, a red-brown liquid that
easily evaporates into a gas
Iodine, a purple solid

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 Concept Check

Which terms best apply to lead (Pb)?
a. Transition element; metal
b. Main-group element; nonmetal
c. Halogen; nonmetal
d. Main-group element; metal

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 Ions and the Periodic Table

A main-group metal tends to lose electrons, forming a
cation with the same number of electrons (isoelectronic) as
the nearest noble gas
A main-group nonmetal tends to gain electrons, forming an
anion with the same number of electrons (isoelectronic) as
the nearest noble gas
In general, the alkali metals have a tendency to lose one
electron and form +1 ions
The alkaline earth metals (group 2A) tend to lose two
electrons and form +2 ions
The halogens (group 7A) tend to gain one electron and
form −1 ions
The oxygen family nonmetals (group 6A) tend to gain two
electrons and form −2 ions
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 Ions and the Periodic Table

For the main-group elements that form cations with a
predictable charge, the charge is equal to the group number
(e.g. Group 1A elements form +1 cations, 2A form +2 cations,
etc.)

For main-group elements that form anions with a predictable
charge, the charge is equal to the group number minus 8
(e.g. Group 7A elements form -1 anions, 6A form -2 anions)

Transition elements may form various different ions with
different charges
(e.g. Fe can form +2 and +3 cations, etc.)

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Ions and the Periodic Table

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2.8 Atomic Mass: The Average Mass
of an Element’s Atoms
Atomic mass is sometimes called atomic weight or standard
atomic weight

The atomic mass of each element is directly beneath the
element’s symbol in the periodic table

It represents the average mass of the isotopes that compose
that element, weighted according to the natural abundance of
each isotope

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 Example

Naturally occurring chlorine consists of 75.77% chlorine-35
atoms (mass 34.97 amu) and 24.23% chlorine-37 atoms
(mass 36.97 amu). Calculate its atomic mass

Solution:
Convert the percent abundance to decimal form and multiply
each with its isotopic mass and add them.

Cl-37 = 0.2423(36.97 amu) = 8.9578 amu
Cl-35 = 0.7577(34.97 amu) = 26.4968 amu

Atomic Mass Cl = 8.9578 + 26.4968 = 35.45 amu
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 Atomic Mass

In general, we calculate the atomic mass with the
following equation:

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 Concept Check

Carbon has two naturally occurring isotopes: C-12 (natural
abundance is 98.93%; mass is 12.0000 amu) and C-13
(natural abundance is 1.07%; mass is 13.0034 amu).
Without doing any calculations, determine which mass is
closest to the atomic mass of carbon.
a. 12.00 amu
b. 12.50 amu
c. 13.00 amu
d. 11.50 amu

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 Pearson Platform and eBook
Readings/Exercises:

Week 3: Atoms and Elements

Readings: Chapter 2.3, 2.4, 2.5, 2.6, 2.7, 2.8

Pearson Platform Tutorial 2 (Practice Questions)

Note: Tutorial questions will be available soon on the Pearson Platform

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