ATOMIC THEORY REVIEW

Where did the elements come from?

Hydrogen, a little helium and less lithium were created in the big bang. The universe is about 95% hydrogen. Clouds of hydrogen gas and dust are compressed by gravity into stars. When the star's core runs out of hydrogen, the nuclear reaction pauses, and gravity compresses the star, heating it up enough to fuse helium.

Where did the elements come from?

If the star is big enough, like a supernova, it can eventually create all the elements in the periodic table up to iron. If a giant star explodes as a supernova, it will releases enough energy to make all the elements heavier than iron. So stars created the first elements!

The most common Elements in the Earth’s CRUST

Element AmountOxygen 46.1 %

Silicon 28.2 %

Aluminum 8.23 %

Iron 5.63 %

Calcium 4.15 %

The most common Elements in the Earth’s OCEANS

Element AmountOxygen 85.84 %

Hydrogen 10.82 %

Chlorine 1.94 %

Sodium 1.08 %

Magnesium 0.1292 %

The most common Elements in the Earth’s ATMOSPHERE

Element AmountNitrogen 78.1 %

Oxygen 20.9 %

Argon 0.96 %

ATOMS !!! What are the 3 subatomic particles?

ProtonsNeutronsElectrons

What is ALL matter made of?

Subatomic Particle Charges

protons (+)positive

neutrons (0)neutral

electrons (-)negative

We know that there are the same number of p+ and e- in atoms on the Periodic Table… So What is the overall charge of any atom?

The overall charge of any atom is

NEUTRAL… the positive charge cancels out the negative charge = 0!!!

What are the masses (amu) of the subatomic particles?

p+ = 1amu

n = 1amue- = 0 amu

1.66 x 10-27 kg = 1 amu

What is this AMU stuff?????

Atomic mass unit (AMU)

2.2 lbs= 1 kg

What are the two areas of an atom?

Nucleus and electron cloud

P+ & No

e-

Where are the p+, n, and e- located in an atom?

p+ in the nucleus

no in the nucleus

e- in the electron cloud

NucleusWhere is ALL the mass in an atom located?

Where is most of the volume of an atom located?

Electron Cloud

The nucleus contains the p+ and n… while the electrons “orbit” the nucleus in the energy rings of the e- cloud.

What does a Bohr model of the atom look like?

So what are the charges of the different areas?

1. So what is the overall charge of the nucleus?

Positive

2. So what is the overall charge of the electron cloud?

Negative

(opposite charges attract)

QUICK REVIEW- ATOMSSub-atomic particles:.

particles charge amu location abbrev.

Protons

Electrons

e-

Neutral (0)

+ p+nucleus

0

1

1

neutrons

Electron

cloud_

nucleus

no

protons, neutrons, and electronsnucleus and electron cloudParts of the atom:

Energy Levels of the Atom

8 e- 2e- 32e-

8 e-

18 e-

18 e- 32e-

The Nucleus

P+ N0

1st

shell7th

shell2nd

shell3rd

shell4th

shell5th

shell6th

shell

Atoms can have several energy levels. Sometimes they are also called energy rings, shells or orbits.

Lets take a look at the Periodic Table!The periods equal the number of energy shells or rings in an atom.

Beginning with Bohr Models Let’s try a few easy bohr models:

Li

Be

Bohr Model Practice

1. Ca2. O3. Ne4. K5. Rb

6. P7. F8. Cl9. Br10. I

More Bohr Model Practice11. Fr 12. Te13. Sn

14. Cs15. Kr

16. At 17. Ga18. Rn19. Ag20. W

Cs Fr Sn Te Kr At Ga Rn W Ag

Bohr Model

H vs. He

Explain why we use helium filled balloons instead hydrogen filled balloons at Parties.

Hydrogen is unstable and flammable and helium is stable!

Energy rings are not filled

Energy rings are filled

Draw the bohr models for the following atoms.

Burning Hindenburg

Complete the Bohr Models for the following elements. Ne, Ar, Kr and Xe

What 4 patterns or trends did you notice they have in common?

“Predict” what you think Radon’s (Rn) bohr model would look like.

Six rings Full shell More massive

All of the rings or shell are full.

They are all in the same group (18)

They gain an energy ring as you go down a period.

They gain more subatomic particles as you go down.

Patterns from the Bohr Models.

Ne Ar Kr Xe

Radon Bohr Model

Even More Bohr Model Practice!

21. Os 22. Hf23. Cm

24. Sr25. Ho

26. Tc27. Ac28. Zr29. Po30. Np

“Life on the Edge” with Valence Electrons

Valence electrons are electrons in the outermost shell of an atom.

They determine whether the atom will bond with another atom.

How many valence electrons does lithium have here?

1 valence electronCircle the valence electronsFrom your warm up.

Valence electrons are electrons in the outermost shell of an atom.

They determine whether the atom will bond with another atom.

How many valence electrons does lithium have here?

1 valence electronCircle the valence electronsFrom your warm up.

Arrangement of the Periodic Table

1. What atom is this?

Oxygen2. Which subatomic “particle” helped

you to determine that this Bohr model was of oxygen?

Protons

Arrangement of the Periodic Table1. The periodic table is arranged according to

what?A. Atomic SymbolB. Atomic massC. Atomic numberD. Number of Energy Shells Do the elements on the periodic table all

increase according to their masses?

No!! Can you find where they are not? There are a few of them. Look carefully!

Periodic Table Card Sort Poster

Breaking the CodePurpose: This lesson will help you identify

many of the patterns that are contained in the periodic table of elements.Use the card sort poster to answer the following questions on your paper.

Do you notice any patterns hereas the elements move to the right?

Li Na K Rb

Can you “predict” how many energy rings a bohr model of Francium (Fr) would have?

Gaining more mass

Gaining more energy rings

Gaining more p+, no, and e-.

Francium (Fr) Bohr Model

                                               

          

Seven energy rings

1 valence electro

n

What Bohr model patterns are you starting to see develop? Periodic Table Patterns

The atomic number is the same number as the number of protons and electrons.

Atoms get larger as you move down and two the right on the periodic table.

As you move from left to right on the periodic table, you gain protons and electrons and neutrons.

As you go down from the periodic table, the atom gains another energy shell or orbit.

Element Atomic Number

Atomic Mass

# of Protons

# of Electrons

# of Neutrons

Zn 30 65

Xe 54 77

Au 79 118

Hg 80 121

I 127 53

30

54

197

8020180

79

54131

30 35

305353

79

Manganese

First Energy Level: 2

Second Energy Level: 8

Third Energy Level: 8

Fourth Energy Level: 7

Yttrium

First Energy Level: 2

Second Energy Level: 8

Third Energy Level: 8

Fourth Energy Level: 18

Fifth Energy Level: 3

P39N50

2e 8e 8e 18e 3e

P25N30

2e 8e 8e 7e

Yttrium Manganese

Krypton

First Energy Level: 2

Second Energy Level: 8

Third Energy Level: 8

Fourth Energy Level: 18

Germanium

First Energy Level: 2

Second Energy Level: 8

Third Energy Level: 8

Fourth Energy Level: 14

Krypton Germanium

P36N48

2e 8e 8e 18e

P39N50

2e 8e 8e 14e

Metals vs. Non-Metals

Metals

Non-metals

Man made elements and Rare Earth metals

Stair steps

Metalloids on the Periodic Table

FA

MIL

IES

/ G

RO

UP

S

Periods/ Rows

Metalloids

Properties of Metals

Most elements are metals. 88 elements to the left of the stairstep line are metals or metal-like elements.

Tend to have Luster High density Ductile Malleable

(shininess) (heavy for their size)

(most metals can be made into thin wires)(most metals can be hammered into

thin sheets)

Properties of Non-metals

Nonmetals are found to the right of the stairstep line.

No luster Brittle Not ductile Not malleable

(dull) (breaks

easily)

Properties of Metalloids

Metalloids are elements on both sides of the stair step line. They have properties of both metals and nonmetals.

Solids Can be shiny or dull Ductile Malleable

Families on the Periodic Table

So where do the names come from?

Iron (Fe)………….……Ferrum

Sodium (Na)….. …….Natrium

Gold (Au)……………Aurum

Silver (Ag)………….Argentum

Potassium (K)………… Kalium

Copper (Cu) ………….Cuprum

Mercury (Hg) ……Hydragyrum

Antimony (Sb)………… Stibium

Tin(Sn)….………… Stannum Lead(Pb)

……………..Plumbum

Tungsten(W)………….Wolfran

These abbreviations are for there LATIN names of the elements.

Steps for creating a bohr model

1. Complete the particle inventory for the atom (protons, electrons and neutrons).

2. Draw your nucleus.3. Put the number of protons

and neutrons in the nucleus.

4. Circle how many electrons you need to use in the shells.

5. Know how many electrons and shells you will need.

6. Put 2 electrons in the first shell. If there are more than 2, begin to fill the next shell (maximum of 8).

7. You cannot begin to fill the next shell until the previous shell is filled.

8. Remember` how many electrons each shell can hold a maximum of.(2, 8, 8, 18, 18, 32, 32,)