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MODELS OF THE ATOM

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Title: MODELS OF THE ATOM

1
MODELS OF THE ATOM

CHM 130
GCC

2
Review - Rounding

Round 399

Hopefully you said 400 not 4. What is wrong with
4???
The zeroes ARE important, they are place holders.
400 and 4 are NOT the same! If you had 400 in
the bank but they said you had only 4 youd be
pissed off! Round 2389 to 2 sig fig, now round
to 1 sig fig
Answer 2400 NOT 24 2000 NOT
2
3
1. An element is made of tiny, indestructible
particles called atoms. (Not quite true why?)
5.1 DALTONS ATOMIC THEORY
4
2. All atoms of an element are identical and have
the same properties. (Not quite true why?)
5
3. Atoms of different elements combine to form
compounds.
6
4. Compounds contain atoms in small whole number
ratios.e.g. Each H2O molecule consists of one O
and two H atoms, not ½ atoms or ¾ atoms.
7
5. Atoms of 2 or more elements can combine to
form different compounds. E.g. C and O may form
CO or CO2
8
5.2 Thomson cathode ray experiment
9
Thompson Plum Pudding Model http//highered.mcgr
aw-hill.com/sites/0072512644/student_view0/chapter
2/animations_center.html

Atom is charged
e-s are distributed throughout atoms like
raisins in plum pudding

10
5.3 Rutherfords Scattering Experiment
http//www.mhhe.com/physsci/chemistry/animations/c
hang_2e/rutherfords_experiment.swf
11
Explanation of Scattering
12
Nuclear Model
1) The atom is mostly empty space with electrons
moving around. 2) Each atom has a small, dense
nucleus with the Protons Neutrons.
13
Rutherfords model
If nucleus size of a small marble, then atom is
the size of Cardinals stadium!
14
Subatomic Particles
15
5.4 Atomic Notation
16
ATOMIC NUMBER

Every atom of an element has the same of
protons
The of protons defines an element
Carbon atoms ALWAYS have 6 protons

17
Mass number
Mass number protons neutrons So how
calculate neutrons?
neutrons mass - protons
18
Isotopes
Isotopes of an element have the same atomic
number ( pro), but a different mass number (
neu). Ex carbon-12, carbon-13 and
carbon-14 How many protons do the above have?
Neutrons?
6
6, 7, 8
19

Ex. 1 Write the atomic notation for
potassium-40.
How many neutrons are there?
______________

40 19 21
20
Ex. 2 a. Write the atomic notation for
bromine-81. b. How many neutrons are
there? _________________
81 - 35 46
21
16 8 8 8 17 8 9 8 18 8 10 8
22
5.5 Atomic Mass

Masses of atoms are so small that we define the
atomic mass unit (amu)
Mass of proton neutron ? 1 amu.
Mass of electron is basically zero amu

23
Atomic mass
Atomic Mass in the P. Table is the weighted
average of all atoms for that element in the
world, so that is why it is NOT a whole number.
24
Natural isotopes of carbon carbon-12 (98.89)
carbon-13 (1.11)
The atomic mass reported for carbon (12.01 amu)
is closer to carbon-12 since it is most abundant
isotope for C. (There is a ton more C-12 than
C-13.)
25
Example Use the Periodic Table to determine the
most abundant isotope a. lithium-6 or
lithium-7 b. chlorine-35 or chlorine-37
26
5.6 Light has two components
Wavelength (?) is the distance between peaks
Frequency (?) is the number of wave cycles
per second. (like a beat)
27

As wavelength ?, the frequency ?, and the energy ?

28
Which wave has higher energy? Lower frequency?
29
Radiant Spectrum
30
5.7 In 1900, Max Planck proposed the
controversial idea that energy was emitted in
small bundles called quanta.

a particle of light energy is called a photon

31
Ball loses potential energy continuously as it
rolls down a ramp.
Ball loses potential energy in quantized amounts
as it bounces down a stairway.
32
5.8 Bohr Model 1913

Neils Bohr proposed that electrons orbit around
the nucleus, occupying orbits with distinct
energy levels.
Electrons are quantized!

33
Bohr model of the atom

The electrons orbit around the nucleus kinda like
planets orbit around the sun but in 3D.
These orbits are called energy levels or shells.
Each orbit has a specific radius and energy, so a
certain distance from the nucleus.

34
Bohr Model
The orbit closest to the nucleus is lowest in
energy the energy increases with distance from
the nucleus. Proven by line spectra.
35
When the light from a heated element passes
through a prism, a series of narrow lines is
seen.These lines are the emission line spectrum.
36
Atomic Fingerprints
Each element produces a different emission line
spectrum, so its own unique color.
37
Each element has its own energy levels that are
unique.
38

Bohr theory explains 3 lines in H2 spectra.
Electrons gain energy from heat or electricity
and jump to a higher energy level. These
excited electrons ultimately lose energy and
drop to lower energy levels, which causes light
to be emitted.

39
5.9 Each Energy Level Can Be Subdivided Into
Sublevels.

Levels 1-7
sublevels s, p, d, and f.

40
Each Level Has n Sublevels1st level has One
Sublevel 1s2nd level has Two Sublevels 2s
2p3rd level - Three Sublevels 3s 3p 3d4th level
- Four Sublevels 4s 4p 4d 4fThis is depicted
on next slide.
41
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42

Orbitals are regions in space where there is a
high probability of finding an electron.
One orbital can hold a maximum of 2 electrons.

43
Each sublevel contains a specific number of
orbitals.
s has 1 orbital p has 3 d has 5 f has 7 Orbitals
are boxes on next slide
44
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45
5.10 Electron Configuration Shorthand
description of electrons by sublevel.

Sublevels are filled in order of increasing
energy.
1s lt 2s lt 2p lt 3s lt 3p lt 4s
You will do configurations for the 1st 20
elements.
Note the 3d sublevel is higher in energy than the
4s which is why we fill 4s first

46
Writing electron configurations