Chemistry Notes for CHE101 Chapter 2 PDF

Summary

This document is a set of chemistry notes covering the fundamentals of atoms, molecules, and ions. It includes classifications of matter, discussions on elements and compounds, and an introduction to mixtures. The notes outline various ways to differentiate between pure substances and mixtures.

Full Transcript

Chapter 2

Atoms, Molecules & Ions
 Two Schools of Thought
Democritus Zeno
All matter is made Matter is infinitely
of small particles divisible
called atoms
 Who was correct?
Matter is made of atoms
Atoms can be divided into subatomic
particles…
But after division they lose their characteristic
properties and become just a pile of electrons,
protons and neutrons
 Three Kinds of Matter

Elements

Compounds

Mixtures
 Pure Substances versus
Mixtures
Pure substance Mixture
Always has same ratio Can have different
of atom types ratios of atom types
It’s an element or It’s homogenous
compound (smooth/transparent)
or heterogeneous
(chunky/translucent)
Classification of Matter
Classification of Matter
Pure Substance?
Classification of Matter
Pure Substance?
Yes No
 Classification of Matter
Pure Substance?
Yes No

Number of atom types
 Classification of Matter
Pure Substance?
Yes No

Number of atom types

Only 1

Element
 Classification of Matter
Pure Substance?
Yes No

Number of atom types

Only 1 2 or more

Element Compound
 Classification of Matter
Pure Substance?
Yes No

Number of atom types Mixture

Only 1 2 or more

Element Compound
 Classification of Matter
Pure Substance?
Yes No

Number of atom types Mixture
Chunky?
Yes No
Only 1 2 or more

Element Compound
 Classification of Matter
Pure Substance?
Yes No

Number of atom types Mixture
Chunky?
Yes No
Only 1 2 or more

Element Compound
Heterogeneous
 Classification of Matter
Pure Substance?
Yes No

Number of atom types Mixture
Chunky?
Yes No
Only 1 2 or more

Element Compound
Heterogeneous
Homogeneous
Samples...
Native copper (Cu) a metallic element
Sulfur (S) a nonmetallic
……………………………element
Lithium (Li) a metallic
……………………………element
Galena a compound
– a.k.a. lead(II) sulfide
Belt Mountain ore a heterogeneous
mixture
 Elements
118 known at this time; 94 occur in nature
Most only discovered in last 200 years
The periodic table lists the atomic symbols for the
elements
Learn those on the handout for Monday’s quiz
(spelling counts!)
Here are all their names pronounced for you!
http://www.privatehand.com/flash/elements.html
Fun info about each element at
http://www.periodicvideos.com
 Element Forms
Monatomic elements
He, Ne, Ar, Kr, Xe, Rn
Diatomic molecules
H2, N2, O2, F2, Cl2, Br2, I2
Polyatomic molecules
P4, S8
 Element Forms
Network elements
C* (graphite, diamond)
Metals (e.g., Cu, Au, Fe)
There is no such entity as a
molecule for network elements
* C60, one type of buckyball, is a
molecule
Mixtures...
Can be separated by physical means
Common methods include
filtration (coffee)
evaporation (salt)
distillation (vinegar)
fractional crystallization (fresh water ice out
of sea water)
 What is Gatorade?
1. An element
2. A compound
3. A homogeneous
mixture
4. A heterogeneous
mixture
Element, Compound or Mixture?

Gatorade - it’s a HETEROGENEOUS
(murky) MIXTURE of sugar, water
flavoring, electrolyte salts, etc.

Baking soda, NaHCO3

Cl2 gas
 What is baking soda, NaHCO3?
1. An element
2. A compound
3. A homogeneous
mixture
4. A heterogeneous
mixture
Element, Compound or Mixture?

Gatorade - it’s a HETEROGENEOUS
(murky) MIXTURE of sugar, water
flavoring, electrolyte salts, etc.

Baking soda, NaHCO3 - it’s a
COMPOUND named sodium bicarbonate
or sodium hydrogen carbonate

Cl2 gas
 What is chlorine gas, Cl2?
1. An element
2. A compound
3. A homogeneous
mixture
4. A heterogeneous
mixture
Element, Compound or Mixture?

Gatorade - it’s a HETEROGENEOUS
(murky) MIXTURE of sugar, water
flavoring, electrolyte salts, etc.

Baking soda, NaHCO3 - it’s a
COMPOUND named sodium bicarbonate
or sodium hydrogen carbonate

Cl2 gas - it’s an ELEMENT since only one
kind of atom is present
Dalton’s Atomic Theory
John Dalton (English chemist) proposed
theory in 1808
Built on Lavoisier’s conservation of mass
Matter is neither created nor destroyed
Used Proust’s law of constant composition
Compounds always have same atom ratio
 Atoms are tiny
Size range
7.4 x 10-11 m for hydrogen (74 pm)
5.2 x 10-10 m for cesium (520 pm)
Mass range
1.67 x 10-24 g for hydrogen
3.95 x 10-22 g for uranium
Silicon atoms arranged on a face of a crystal. It is
impossible to "see" atoms this way using ordinary
light. The image was made by a Scanning Tunneling
Microscope, a device that "feels" the cloud of
electrons that form the outer surface of atoms.
http://www.aip.org/history/einstein/atoms.htm
Atoms are built from...
Protons
Electrons
Neutrons

But what holds them together?
 Fundamental forces

Strong nuclear force
Strong but short range (~10-15 m)
Electrostatic (electromagnetic) forces
Intermediate and midrange (~10-10 m)
Gravity
Weak but long range (light years!)
 Strong nuclear force
Used as “glue” between protons and
neutrons in the nucleus
Protons repel each other, but the strong
nuclear force overwhelms the electrostatic
repulsion
Beyond 83 protons (bismuth), all nuclei
become unstable
Electrostatic Forces...
⚫ Electrostatic forces are dominant once
particles are more than 10-15 m apart
⚫ Protons and electrons are more than 10-15 m
apart

ELECTROSTATIC INTERACTIONS ARE THE
DRIVING FORCE BEHIND CHEMISTRY!
Charge behaviors..
Like charges repel
+ repels + - repels -
Unlike charges attract
+ attracts -
Neutral charges are indifferent
0 ignores + and - and 0
The US Office of Naval Research just unveiled its new rail-gun
that uses charge repulsion to accelerate a sliding metal
conductor between two rails and launch a 28-pound HVP up to
5,600 mph!
 The Atomic Nucleus
Protons and neutrons are packed into a
HIGH density nucleus
 The Atomic Nucleus
Protons and neutrons are packed into a
HIGH density nucleus
 The Atomic Nucleus
Protons and neutrons are collectively called
nucleons
Strong nuclear force holds nucleus together
Neutrons can be viewed as “proton glue”
 Nuclear Density
Incredibly dense: 1.8 x 1014 g/cm3
A paper clip with this density would weigh
10,000,000 tons!
Neutrons stars have this density
As they rapidly spin they give off radio
waves and are known as pulsars
The electron cloud
Electrons move through the space
surrounding the nucleus in unknown
trajectories
The electron cloud
Electrons move through the space
surrounding the nucleus in unknown
trajectories

the electron
cloud
An inaccurate diagram of an
atom! http://sciencecabin.com/there-are-three-parts-of-the-atoms/
The electron cloud

Atoms are mostly empty space
Nuclear diameter: 10-15 m
Electron cloud diameter: 10-10 m
If the nucleus is pea-sized,
the electron cloud is as big as a domed
football stadium!
Subatomic Particles
 Table : Subatomic Particles

Particle Symbol amu’s grams Charge
 Table : Subatomic Particles

Particle Symbol amu’s grams Charge
Proton p+ 1.0073 1.673 x 10-24 +1
 Table : Subatomic Particles

Particle Symbol amu’s grams Charge
Proton p+ 1.0073 1.673 x 10-24 +1
Electron e- 0.0005486 9.110 x 10-28 -1
 Table : Subatomic Particles

Particle Symbol amu’s grams Charge
Proton p+ 1.0073 1.673 x 10-24 +1
Electron e- 0.0005486 9.110 x 10-28 -1
Neutron n 1.0087 1.675 x 10-24 0
Atomic Mass Units (amu)
Masses of atoms and subatomic particles
are so small that they are often expressed on
a relative scale
1 amu = 1/12 the mass of a carbon-12 atom
= 1.6605 x 10-24 g
= 1 dalton (biochemistry)
Atomic Number, Z
Atom type determined by number of
protons in nucleus
# of protons = atomic number
=Z
Atomic numbers are integers that
increase through the periodic table
Atomic Number, Z
Atom type determined by number of
protons in nucleus
# of protons = atomic number
=Z
Atomic numbers are integers that
increase through the periodic table
Neutral Atoms
When an atom is uncharged (electrically
neutral)…
# of protons = # of electrons
# of p+ = # of e-
Z = # of e-
 Consider a neutral copper
atom...
Number of protons: Z = ?
 Consider a neutral copper
atom...
Number of protons: Z = 29
 Consider a neutral copper
atom...
Number of protons: Z = 29

Number of electrons: ?
 Consider a neutral copper
atom...
Number of protons: Z = 29

Number of electrons: 29
 Mass Number, A
When weighing chemicals, need to account
for neutrons, too.
# of neutrons is not fixed for an atom type
The first evidence
of different masses
appeared at the
bottom right
corner of this J. J.
Thomson
photographic
plate. Two of the
patches are both
from neon: neon of
mass 20 and neon
of mass 22.
 Mass Number, A
When weighing chemicals, need to account
for neutrons, too.
# of neutrons is not fixed for an atom type
For a specific atom…
# of protons + # of neutrons = mass number
Z + # of n = A
Carbon-12
The most common type of carbon atom
6 protons
6 neutrons
6 p+ + 6 n = 12 (mass number)
Carbon-12
The most common type of carbon atom
6 protons
6 neutrons
6 p+ + 6 n = 12 (mass number)
Carbon-12
The most common type of carbon atom
6 protons
6 neutrons
6 p+ + 6 n = 12 (mass number)
NOTE: electrons ignored -- too light
Let's try another...
Let’s try another...
What’s in a neutral nickel-60 atom?
 How many protons in a neutral
Ni-60 atom?
1. 60
2. 0
3. 59
4. 28
 How many protons in a neutral
Ni-60 atom?
1. 60
2. 0
3. 59
4. 28
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = ?

# of protons = atomic number
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
 How many electrons in a neutral
Ni-60 atom?
1. 60
2. 0
3. 59
4. 28
 How many electrons in a neutral
Ni-60 atom?
1. 60
2. 0
3. 59
4. 28
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = ?
In a neutral atom
# of protons = # of electrons
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = 28
 How many neutrons in a neutral
Ni-60 atom?
1. 60
2. 32
3. 58
4. 28
 How many neutrons in a neutral
Ni-60 atom?
1. 60
2. 32
3. 58
4. 28
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = 28
Neutrons = ?
Mass number is...
# of protons + # of neutrons
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = 28
Neutrons = 60 - 28
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = 28
Neutrons = 60 - 28
= 32
 Lets try another...
What’s in a neutral nickel-60 atom?
Protons = 28
Electrons = 28
Neutrons = 60 - 28
= 32
Shorthand notation: 28 p+, 28 e-, 32 n
 Ions
Not all atoms are electrically neutral
A charged atom (or molecule) is called
an ion
Ion charge = # of p+’s - # of e-’s
 What’s the charge of an atom
that has 16 protons and 18
electrons?
1. -2
2. -1
3. 0
4. +2
 What’s the charge of an atom
that has 16 protons and 18
electrons?
1. -2
2. -1
3. 0
4. +2
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = # of p+’s - # of e-’s
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = # of p+’s - # of e-’s
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - # of e-’s
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - # of e-’s
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - # of e-’s
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - 18
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - 18
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - 18
= -2
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - 18
= -2
Aha! It’s a sulfide ion, S2-
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p +’s - # of e-’s
With 16 p+’s, it
What’s
can only the
be acharge of an atom that has
sulfur
16 atom and 18 electrons?
protons
Ion charge = 16 - 18
= -2
Aha! It’s a sulfide ion, S2-
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
The ion charge
Ion charge = # of p ’s - # of e-’s
+
is written as a
What’s the charge of an atom that has
superscript to
16 protons and 18 electrons?
the right, with
Ion charge = 16 the
- charge18 sign
listed last
= -2
Aha! It’s a sulfide ion, S2-
 Ions
Not all atoms are electrically neutral
A charged atom is called an ion
Ion charge = # of p+’s - # of e-’s
What’s the charge of an atom that has
16 protons and 18 electrons?
Ion charge = 16 - 18
= -2
Aha! It’s a sulfide ion, S2-
 Build atom and Ion

https://phet.colorado.edu/sims/html/build-an-
atom/latest/build-an-atom_en.html
Ions are charged species
 Ions are charged species

Cations are missing a
few electrons
 Ions are charged species

Cations are missing a
few electrons
This imparts a positive
charge
 Ions are charged species

Cations are missing a
few electrons
This imparts a positive
charge
e.g., Zn2+
30 protons
28 electrons
2 e-’s missing
 Ions are charged species

Cations are missing a Anions have a few
few electrons extra electrons
This imparts a positive
charge
e.g., Zn2+
30 protons
28 electrons
2 e-’s missing
 Ions are charged species

Cations are missing a Anions have a few
few electrons extra electrons
This imparts a positive This imparts a
charge negative charge
e.g., Zn2+
30 protons
28 electrons
2 e-’s missing
 Ions are charged species

Cations are missing a Anions have a few
few electrons extra electrons
This imparts a positive This imparts a
charge negative charge
e.g., Zn2+ e.g., Cl- ion
30 protons 17 protons
28 electrons 18 electrons
2 e-’s missing 1 excess e-
How to remember which is which
C a t ion
See a + ion

A n ion
A negative ion
Hydrogen isotopes
Most hydrogen atoms have a nucleus with
just 1 proton
hydrogen-1
protium
About 15 of every 100,000 hydrogen atoms
has a neutron as well
hydrogen-2
deuterium (D) or heavy hydrogen
Deuterium and Harold Urey
The neutron was theoretically predicted to exist by
Chadwick around 1930
Harold C. Urey ( UM chemistry alum/faculty!)
proved the existence of neutrons by isolating
deuterium
Awarded 1934 Nobel prize
He isolated deuterium through fractional
distillation of liquid hydrogen
Chemists use deuterium all the time in the form of
heavy water, D2O
Harold Clayton Urey was born in Walkerton, Indiana, on April 29, 1893, as the
son of the Rev. Samuel Clayton Urey and Cora Rebecca Reinsehl, and
grandson of pioneers who settled in Indiana. His early education in rural
schools led to his graduation from high school in 1911 after which he taught
for three years in country schools.

In 1914 he entered the University of Montana and received his Bachelor of
Science degree in Zoology in 1917. He spent two years as a research chemist
in industry before returning to Montana as an instructor in Chemistry. In 1921
he entered the University of California to work under Professor Lewis and he
was awarded the degree of Ph.D. in Chemistry in 1923. He spent the following
year in Copenhagen at Professor Niel Bohr’s Institute for Theoretical Physics
as American-Scandinavian Foundation Fellow to Denmark and on his return to
the United States he became an Associate in Chemistry at Johns Hopkins
University. In 1929 he was appointed Associate Professor in Chemistry at
Columbia University and he became Professor in 1934.

Professor's Urey's early researches concerned the entropy of diatomic gases
and problems of atomic structure, absorption spectra and the structure of
molecules. In 1931 he devised a method for the concentration of any possible
heavy hydrogen isotopes by the fractional distillation of liquid hydrogen: this
led to the discovery of deuterium.
 Hydrogen isotopes (Cont’d.)
Nuclear reactions create a third isotope with
two neutrons in the nucleus
hydrogen-3
tritium
This is a radioisotope in that it decays and
gives off harmful radiation
Isotope notation...
Isotope notation...
All four positions around a symbol
can hold information

H
Isotope notation...

Mass number, A

H
Isotope notation...

Mass number, A

H
Atomic number, Z
Isotope notation...

Mass number, A Ion charge

H
Atomic number, Z
Isotope notation...

Mass number, A Ion charge

H
Molecular
Atomic number, Z
formulas
Isotope notation...
Consider a +1 ion of a deuterium atom

H
Isotope notation...
Consider a +1 ion of a deuterium atom

H
A deuterium atom has 1 proton in its nucleus
Isotope notation...
Consider a +1 ion of a deuterium atom

1 H
A deuterium atom has 1 proton in its nucleus
Isotope notation...
Consider a +1 ion of a deuterium atom

1 H
Isotope notation...
Consider a +1 ion of a deuterium atom

1 H
A deuterium atom has a mass number of 2
Isotope notation...
Consider a +1 ion of a deuterium atom

2
1 H
A deuterium atom has a mass number of 2
Isotope notation...
Consider a +1 ion of a deuterium atom

2
1 H
Isotope notation...
Consider a +1 ion of a deuterium atom

2
1 H
A deuterium cation has a charge of +1
Isotope notation...
Consider a +1 ion of a deuterium atom

2 +
1 H
A deuterium cation has a charge of +1
Isotope notation...
Consider a +1 ion of a deuterium atom

2 +
1 H
Isotopes of Hydrogen
Atomic Weights
Atoms of the same type that differ in
neutron count are called isotopes
Most elements in nature occur as a mixture
of several isotopes
Isotopes DON’T make much difference in a
chemical sense
Isotopes DO make a difference in weighing
out samples
 Weighted Averages
Masses listed on periodic table are weighted
averages of natural isotopic abundances
Chlorine comes in two common forms
75.53% is chlorine-35
24.47% is chlorine-37
Exact masses are
Chlorine-35 34.97
Chlorine-37 36.96
 Weighted Averages
Masses listed on periodic table are weighted
averages of natural isotopic abundances
Chlorine comes in two common forms
75.53% is chlorine-35 The average MUST
be somewhere
24.47% is chlorine-37 between 35 and 37!
Exact masses are
Chlorine-35 34.97
Chlorine-37 36.96
Example calculation
 Example calculation
Contribution from Cl-35
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53
(34.97)
100
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)

26.41 + 9.04
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)

26.41 + 9.04

Note that contribution from Cl-35
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)

26.41 + 9.04

Note that contribution from Cl-35 is about 3 times that from Cl-37
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)

26.41 + 9.04

= 35.45
 Example calculation
Contribution from Cl-35 + Contribution from Cl-37

75.53 24.47
(34.97) + (36.96)
100 100

(0.7553 x 34.97) + (0.2447 x 36.96)

26.41 + 9.04
Weighted average = 35.45
appears on periodic table
 Weighted Averages
Masses listed on periodic table are weighted
averages of natural isotopic abundances
Magnesium comes in three common forms
78.70% is magnesium-24
10.13% is magnesium-25
11.17% is magnesium-26
Exact masses are
magnesium-24 23.98504
magnesium-25 24.98584
magnesium-26 25.98259
 Weighted Averages
Masses listed on periodic table are weighted
averages of natural isotopic abundances
Magnesium comes in three common forms
78.70% is magnesium-24 The average MUST
10.13% is magnesium-25 be somewhere
between 24 and 26!
11.17% is magnesium-26
Exact masses are
magnesium-24 23.98504
magnesium-25 24.98584
magnesium-26 25.98259
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26
78.70 10.13
(23.98504) + (24.98584)
100 100
+ 11.17
(25.98259)
100
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26
78.70 10.13
(23.98504) + (24.98584)
100 100
+ 11.17
(25.98259)
100

0.7870 (23.98504) + 0.1013 (24.98584)

+ 0.1117 (25.98259)
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26

0.7870 (23.98504) + 0.1013 (24.98584)

+ 0.1117 (25.98259)
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26

0.7870 (23.98504) + 0.1013 (24.98584)

+ 0.1117 (25.98259)

= 18.87623 + 2.53107 + 2.90226
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26

0.7870 (23.98504) + 0.1013 (24.98584)

+ 0.1117 (25.98259)

= 18.87623 + 2.53107 + 2.90226

= 24.30955
 Example calculation
Contribution from Mg-24 + Contribution from Mg-25
+ Contribution from Mg-26

0.7870 (23.98504) + 0.1013 (24.98584)

+ 0.1117 (25.98259)

= 18.87623 + 2.53107 + 2.90226

= 24.30955
= 24.31 (4 sig figs allowed)
The Periodic Table
As more elements were discovered,
researchers noted “triplets” that had similar
chemical properties
Lithium, sodium, and potassium react
vigorously with water
Chlorine, bromine, and iodine are all
pungent nonmetals
 Dmitri Mendeleev
Let chemical character dictate placement
rather than atomic weight
Co (53.9882 amu) before Ni (58.6934 amu)
Te (127.60) before I (126.9045 amu)
His positioning in 1869 anticipated quantum
theory by 60 years
An early version of Mendeleev’s
periodic table
 Here it is
commemorated in
stone on the side
of a Russian
science building
The Periodic Table
Each row is a period
 Each row is a period
1
 Each row is a period
1
2
 Each row is a period
1
2
3
 Each row is a period
1
2
3
4
 Each row is a period
1
2
3
4
5
6
7
7 periods so far
 Each row is a period
1
2
3
4
5
6
7
7 periods so far

These actually fit in here!
 The Periodic Table

It’s not a convenient shape to print when inserted
Each column is a family
1A
Each column is a family
The alkali metal family
 Element Families
Elements in the same family exhibit similar
properties
Alkali metals are:
soft shiny metals
react violently with water to produce alkaline
(basic) solutions
http://www.youtube.com/watch?v=eCk0lYB_8c0
never found in elemental form
 Lessons Learned
Recognize the contributions of Zeno, Democritus,
Dalton, Urey, Mendeleev and Pauli to our
knowledge of atomic structure

Distinguish between elements and compounds; pure
substances and mixtures; heterogeneous and
homogeneous mixtures

Name and give symbols of common elements

Know fundamental forces - strong nuclear,
electrostatic, gravitational
 Lessons Learned
Explain the composition of different atoms
according to the number of protons, neutrons and
electrons they contain

Know what cations and anions are. Use charge to
predict electron numbers and vice versa

Understand what isotopes are, how to write isotope
notation, and how to use their natural abundances to
compute average atomic masses