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Unit 3
Quantum Theory
And
Periodicity
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Unit 3 - Quantum Theory and Periodicity
The quantum mechanical model is the current model of the atom that describes the probability of finding an electron in a given region of space around the nucleus. It is called the electron cloud model.
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Quantum numbers are the 4 numbers that specify the properties of atomic orbitals and the electrons that reside in them.
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The energy level, also called the principal quantum number or shell, is the first quantum number. Electrons can occupy only specific energy levels. These levels are numbered 1 – 7. The higher energy levels indicate a higher energy state for that electron and a location further away from the nucleus.
In other words, electrons near the nucleus are low energy electrons.
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The energy level indicates the size of the electron cloud. The formula 2n2 indicates the total possible electrons in an energy level.
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Example: Calculate the total possible electrons in the 1st through 4th energy levels. Remember: 2n2
Energy Level # of Electrons
1
2
3
4
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The orbital shape, also called the angular momentum quantum number, is the second quantum number. An energy level is actually made of many energy states called orbitals (subshells or sublevels).
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An orbital is a three dimensional region around the nucleus that indicates the probable location of one pair of electrons. These orbitals are s, p, d and f . The second quantum number indicates the shape of the orbital.
S - orbital
P - orbital
D - orbitals
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The s-orbital is sphere shaped.
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The p-orbital is dumb bell shaped
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d-orbitals look like leaves of clover
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f-orbitals look like flowers
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Orbital orientation, also called the magnetic quantum number, is the 3rd quantum number. The magnetic number indicates the orientation of an orbital around the nucleus. Since an ‘s’ orbital is spherical, it can have only 1 orientation.
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3 Possible Orientations for p-Orbitals
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d-Orbitals have 5
Possible Orientations
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f-Orbitals have 7 Possible Orientations
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Orbital Orientations
Orbital
Type
MAX # Electrons per Orbital
Possible Orientations
for Each Type of Orbital
Max # of Electrons if Each Orbital Orientation
is Filled
s 2 1 2
p 2 3 6
d 2 5 10
f 2 7 14
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The spin quantum number is the 4th quantum number. The spin quantum number indicates that the 2 electrons occupying a single orbital
must have
opposite spin.
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Principle Quantum #
Main Energy
Level (n)
Types of Orbitals in
Main Energy
Level (n)
# of Orientations per Orbital
Type
# of Orbitals per Main Energy Level
(n2)
Max # Electrons
In Filled Orbitals
Max # of Electrons per Main Energy
Level (2n2)
1 s 1 1 2 2
2 s
p
1
3
4 2
6
8
3 s
p
d
1
3
5
9 2
6
10
18
4 s
p
d
f
1
3
5
7
16 2
6
10
14
32
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Principle Quantum Number:
Main Energy
Level (n)
Types of Orbitals in
Main Energy
Level (n)
# Of Orientations per Orbital
Type
# of Orbitals
Per Main Energy Level
Max # of Electron per
Filled Orbital
Max # of electrons per Main Energy Level
5 s
p
d
f
1
3
5
7
(n - 1)2
16
2
6
10
14
2(n -1)2
32
6 s
p
d
1
3
5
(n - 3)2
9
2
6
10
2(n – 3)2
18
7 s
p
1
3 (n – 5)2
4
2
6
2(n – 5)2
8
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The row numbers on the periodic table are the same as the principle quantum
numbers or energy levels (n).
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Energy levels overlap so the diagram shows the order of the sublevels. The Aufbau principle states that an electron occupies the lowest energy orbital that can receive it.
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Writing Electron Configurations
Using the atomic number as the total number of electrons you can write the electron configuration for all of the elements. The number of electrons in each sublevel is written as a exponent.
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Write the electron configuration for
magnesium #12
gallium #31,
element #35.
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Periodic Table Orbital Filling Method
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Use the periodic table to write the electron configurations for the following
atoms.
Example 1: Nitrogen, 7 electrons
Example 2: Phosphorus, 15 electrons
Example 3: Cerium, 58 electrons
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Noble – Gas Notation
The Group VIII elements, helium, argon, krypton, xenon, and radon are called the noble gases. The configurations of the noble gases are often used as a shorthand method for writing longer electron configurations.
For Example: Sodium – Na has 11 electrons
Electron Configuration
1s22s22p63s1
Noble – Gas Configuration
[Ne]1s2
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Example 2: Arsenic, As, 33 electrons
Electron Configuration
1s22s22p63s23p64s23d104p3
Noble – Gas Configuration
[Ar]4s23d104p3
Example 3: Barium, Ba, 56 electrons
Example 4: Rubidium, Rb
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Using the electron configuration, you can find the valence electrons for that atom. Valence electrons are the electrons in the highest energy level.
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Electron Dot DiagramsLewis or electron dot diagrams are diagrams showing only the valence electrons in an atom. The diagram consists of the element symbol with as many as two dots on each of the four sides of the symbol.
Electron configuration 1s22s22p63s23p4
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What is the electron configuration for Silicon?
Write the electron dot diagram for silicon.
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Write the electron configuration and electron dot diagram for phosphorus – atomic # = 15 and for Arsenic – atomic # = 33.
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Electron – dot Periodic Table
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LIGHT
The ground state is the lowest energy level that an electron can
occupy.
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The excited state is a higher energy level that an electron may move to after absorbing energy.
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The amount of energy absorbed by the electron is equal to the energy of the
photon which is emitted.
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A quantum leap is the jump in energy level that an electron will make after absorbing the correct quanta of energy.
A quantum is a packet of energy that electrons absorb to change energy levels.
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Light (photons) is the form of some of the electromagnetic radiation (energy) released by electrons as they return to their ground state from their excited state.
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The particular wavelength of light produced is specific for each element and can be used to identify it.
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Electromagnetic radiation is a form of energy that exhibits wavelike behavior as it travels through space.
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A spectroscope is a device that is used to view the visible wavelengths of light produced by different atoms. The wavelengths are visible as bright lines on the spectrum.
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A flame test is a method used to identify and element by the color of flame it produces. For example, copper produces a characteristic green flame.
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Dimitri Mendeleev
He develop the 1st
periodic table of the elements.Arranged elements in order of increasing atomic mass and created columns with elements having similar properties.
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Mendeleev’s
Table
Drawbacks
Tellurium and
Iodine
Potassium and Argon
Cobalt and Nickel
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Henry Moseley (1887 – 1915)
Arranged elements in order of increasing atomic number thus reversing the order of the elements and correcting the drawbacks found in Mendeleev’s table.
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Periodic Law
Periodic law states the properties of the elements are periodic functions of their atomic number. In other words, when the elements are listed in order of atomic number, elements with similar properties appear periodically.
Therefore, elements in the same column have similar properties.
Periodic – to appear at regular intervals
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Modern Periodic TablePeriod – Row on the periodic table. Periods reflect the energy level of the electrons.
.
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A Group or Family is a column on the periodic table. Elements in the same column have similar chemical properties.
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Metals are elements located to the left of the jagged stairs except hydrogen.
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Properties of Metals
Metals are solids except mercury, which is a liquid.
Metals have luster, are malleable, ductile, and have high tensile strength.
Metals are good conductors of
heat and electricity.
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Properties of Metals
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NonmetalsNonmetals are elements located to the right of the jagged stairs plus hydrogen.
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Properties of NonmetalsNonmetals are solids or gases except bromine, which is a liquid. Nonmetals are dull, and lack other metallic properties. Nonmetals are generally poor conductors of heat and electricity.
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Metalloids
Metalloids are elements bordering the stairs except aluminum. They have properties of metals and nonmetals.
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Metalloids are generally semiconductors which means
that they conduct to varying degrees making them useful in
the computer industry.
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Group A Elements
Group A elements all have electrons in the outer s, or s and p orbitals. The group number indicates the number of valence electrons except with helium which has 2.
Examples:
IIA - Ca (20) 1s22s22p63s23p64s2
VIA – S (16) 1s22s22p63s23p4
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Group 1 (IA) ElementsGroup 1(IA) elements are the alkali metals with one valence electron. Alkali metals are soft, silver in color, and are too reactive to be found in nature in their free form. Hydrogen is NOT an alkali metal.
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Group 2 (IIA)Group 2(IIA) elements are the alkaline earth metals with 2 valence electrons. Alkaline earth metals are harder, denser, and stronger than alkali metals. They have higher melting points and are less reactive than alkali metals but are also too reactive to be found in their free state in nature.
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Group 18 (VIIA) Group 18 (VIIA) elements are the noble gases with 8 valence electrons, except helium which has 2. Noble gases are inert (nonreactive) in nature. They do not form ions.
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Group 18 (VIIA) Group 18 (VIIA) elements are the noble gases with 8 valence electrons, except helium which has 2. Noble gases are inert (nonreactive) in nature. They do not form ions.
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Group B Elements
Group B elements or transition elements (d block) have electrons in their outer d orbitals. The have varying number of valence electrons but frequently have 2 (with notable exceptions).
Example: Zn (30) 1s22s22p63s23p64s23d10
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Transition elements form very colorful ions in solution.
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Lanthanoid and Actinoid Series or Inner Transition Elements
Lanthanoid and Actinoid elements
(f-block) have electrons in their outer
f orbitals. These elements have varying numbers of valence electrons but frequently have 2 (with notable exceptions). Inner transitions metals generally form +3 ions.
Example: Nd (60)
1s22s22p63s23p64s23d104p65s24d105p66s25d14f3
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Stability of Electron Configurations
Octet Rule – Atoms having all their outer s and p orbitals filled are more stable (less reactive) than partially filled orbitals. Therefore, atoms will gain or lose electrons in order to achieve a stable configuration.
Stable configurations resemble those of noble gases which have 8 valence electrons.
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Example 1
Li has 3 electrons and it has an
electron configuration of 1s22s1. Lithium will lose its 2s1 valence electron to leave a configuration of 1s2, the same configuration has helium.
By losing this electron, lithium will then have one more proton than electron so the lithium atom will have a + 1 charge.
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Example 2
Oxygen (8) has an electron configuration of 1s22s22p4. The oxygen atom will gain two valence electrons to obtain the more stable configuration of
1s22s22p6. This is the same configuration as the noble gas, neon.
The oxygen atom will have 2 more electrons than protons and will carry a
-2 charge.
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IonsAn ion is an atom that has gained or lost electrons. Cations are atoms that have lost electrons and therefore have a positive charge. Metals lose electrons to form positive ions, cations. Metals lose all their valence electrons. Therefore, their ions are positive by the number they lose.
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Anions
An anion is an atom that has gained electrons and therefore, has a negative charge. Anion named end in –ide. S-2 is called the sulfide ion. Nonmetals gain electrons to from negative ion, anions. They gain electrons to have a stable octet (8) of electrons. Therefore, nonmetal ions are negative by the number of electrons they gain.
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Ion Formulas
Ion formulas consist of the element’s symbol followed by its charge or oxidation state.
Rubidium - Rb+1 Iron – Fe+2
Aluminum – Al+3 Lead – Pb+4
Sulfur – S-2 Iodine – I-1
Nitrogen – N-3
Hydrogen – H+1 or H-1
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Exceptions to Predicted Electron Configurations
According to the octet rule, filled and half-filled sublevels are more stable (less reactive). Therefore, in some cases, actual configuration varies from predicted configurations
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Exceptions of the Octet Rule
Predicted Configuration
Chromium Cr 1s22s22p63s23p64s23d4
Actual Configuration
1s22s22p63s23p64s13d5
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Exceptions to the Octet Rule
Predicted Configuration
Copper Cu 1s22s22p63s23p64s23d9
Actual Configuration
1s22s22p63s23p64s13d10
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Periodic Properties
As you have seen, elements in the same row are similar in their outer electron configurations. This results in these elements having
relatively the same physical properties such as density, melting point, and boiling.
These physical properties are then said to be periodic properties.
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Periodic Trends
A periodic trend is a general tendency that occurs across periods or within groups in the periodic table. Exceptions are always present in trends.
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Atomic Radii
Atomic radii is the radius of an atom.
Down a Group – radius increases.
Reasons – * Addition of energy levels
* Shielding of outer electrons
from the nucleus by inner
electrons in larger atoms.
* Electron – electron
repulsion in outer energy
levels
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Across a Period
Across a Period – Radius Decreases
Reasons – 1. no addition of energy
levels
2. increased nuclear
charge causes
electrons to be pulled
closer
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Atomic Radius Vs. Ion Radius
The radius of the ion formed from
an atom
will be smaller or larger than the
radius of
the original atom.
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If the original atom is a metal then the atom
will lose electrons to form a positive ion.
This results in the in the ion having a smaller radius than the original atom.
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If the original atom is a nonmetal, the ion is
formed when the atom gains electrons. This
will result in the ion having a larger radius
than the original atom.
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First Ionization Energy
1st Ionization Energy is the energy required to remove an electron from an atom.
Down a Group – Ionization Energy
Decreases
Reason – Outer electrons in larger
atoms are held more loosely
by the nucleus.
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1st Ionization Energy
Across a Period – Ionization Energy
Increases
Reasons – 1. Outer electrons in
smaller atoms are
held more tightly by
the nucleus.
2. An octet of electrons
is approached.
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Periodic Trend for 1st Ionization Energy