Transcript Slide 1

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Significant Figures – start at the left and proceed to the right
1. If the number does not have a decimal point count until there are no
more non zero numbers
2. If the number has a decimal point start counting at the first non-zero
number and continue counting until you run out of decimal places
• Vocabulary
50. Valence Bond Theory
25. Law of Conservation of Mass
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Observation
Hypothesis
Experiment
Theory
Law
Chemistry
Matter
Energy
Chemical Properties
Physical Properties
Extensive Properties
Intensive Properties
Scientific (natural) law
Anion
Cation
Molecular Geometry
Accuracy
Precision
Exact numbers
Stoichiometry
Ionic Compound
Covalent Compound
Inorganic Compound
Organic Compound
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Law of Conservation of Energy
Law of Definite Proportions
Law of Multiple Proportions
compounds
Molecules
Isotopes
Atomic number
Atomic Mass
chemical formula
empirical formula
molecular formula
structural formula
bond line formula
ball and stick model
space filling model
mole
Electronic Geometry
percent weight
percent error
percent composition
percent yield
%RSD
limiting reactant
VSEPR
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Stoichiometric Coefficient
Electron Affinity
Electronegativity
Covalent Bond
Ionic Bond
Dipole
London Dispersion Forces
Resonance
Hybrid orbital
area of high electron density
Aufbrau Principle
Hund’s Rule
Pauli Exclusion Principle
Valence Electrons
Atomic Radii
Ionic Radii
Ionization energy
Oxidation Number
Formal Charge
Polarizability
Dipole Moment
Polar Covalent Bond
Coordinate Covalent Bond
Molecular Geometry
Table of Common Ions
Common Positive Ions (Cations)
Monovalent
Hydronium
(or hydrogen)
Lithium
Sodium
Potassium
Rubidium
Cesium
Francium
Silver
Ammonium
Thalium
Copper I
H3O+
H+
Li+
Na+
K+
Rb+
Cs+
Fr+
Ag+
NH4+
Tl+
Cu+
Divalent
Magnesium
Calcium
Strontium
Beryllium
Manganese II
Barium
Zinc
Cadmium
Nickel II
Palladium II
Platinum II
Copper II
Mercury II
Mercury I
Iron II
Cobalt II
Chromium II
Lead II
Tin II
Mg2+
Ca2+
Sr2+
Be2+
Mn2+
Ba2+
Zn2+
Cd2+
Ni2+
Pd2+
Pt2+
Cu2+
Hg2+
Hg22+
Fe2+
Co2+
Cr2+
Pb2+
Sn2+
Trivalent
Aluminium
Antimony III
Bismuth III
Al3+
Sb3+
Bi3+
Iron III
Cobalt III
Chromium III
Fe3+
Co3+
Cr3+
Table of Common Ions
Common Negative Ions (Anions)
Monovalent
Hydride
Fluoride
Chloride
Bromide
Iodide
Hydroxide
Permangante
Cyanide
Thiocynate
Acetate
Nitrate
Bisulfite
Bisulfate
Bicarbonate
Dihydrogen phosphate
Nitrite
Amide
Hypochlorite
Chlorite
Chlorate
Perchlorate
HFlClBrIOHMnO4CNSCNC 2H 3O 2NO3HSO3HSO4HCO3H2PO4NO2NH2ClOClO2ClO3ClO4-
Divalent
Oxide
Peroxide
Sulfide
Selenide
Oxalate
Chromate
Dichromate
Tungstate
Molybdate
tetrathionate
Thiosulfate
Sulfite
Sulfate
Carbonate
Hydrogen phosphate
Trivalent
Nitride
O2O22S2Se2C2O42CrO42Cr2O72WO42MoO42S4O62S2O32SO32SO42CO32HPO42- Phosphate
N3-
PO43-
Given
or determined
from balanced stoichiometric
equation
mass of
molecule
Molar Mass
given or calculated from
periodic table
density
molarity, ppm,
molality, normality,
etc.
Vol solution
Concentration
solution
Calculate
from molecular
formula or balanced
equation
moles of
molecule
Avogadro's
Number
Molar Ratio
moles of
element, or
other reactant
or product
Number of
molecules
Dimensional Analysis:
These concepts lead to solving
problems determining limiting reactant
and percent yield.
Molar Mass
given or calculated from
periodic table
Avogadro's
Number
Mass of
element,
or reactant
or product
Number of
atoms,
or molecules
of reactant
or product
Quantum Numbers
n and l define the energy of the electron
The principal quantum number has the symbol ~ n which defines the
energy of the shell
n = 1, 2, 3, 4, ...... “shells”
The angular momentum quantum number has the symbol ~  which defines the
subshells.
 = 0, 1, 2, 3, 4, 5, .......(n-1)
 = s, p, d, f, g, h, .......(n-1)
The symbol for the magnetic quantum number is m which defines the orbital.
m = -  , (-  + 1), (-  +2), .....0, ......., ( -2), ( -1), 
The last quantum number is the spin quantum number which has the symbol m s which characterizes the single electron.
The spin quantum number only has two possible values. ms = +½ or -½ one spin up ↑ and one spin down ↓
Electrons:
The Nucleus:
Hund’s Rule states that each orbital will be filled singly
Build by adding the required number of protons
before pairing begins. The singly filled orbitals will have
(the atomic number) and neutrons (the mass of the atom)
a parallel spin.
Pauli’s Exclusion Principle states that paired
electrons in an orbital will have opposite spins.
Fill the electrons in starting with the lowest energy level
adhering to Hund’s and Pauli’s rules.
Ionic
Polar Covalent
Covalent
Determine Inductive effect
Count the number of electrons the element should have
Determine how equally electrons are shared (DEN) >1.7 consider it ionic
Oxidation number
Never Have a Full Octet
Formal charge
Always Have a Full Octet
Sometimes Have a Full Octet
Sometimes Exceed a Full Octet
To calculate a formal charge
1. draw the Lewis dot structure
2. draw circles around each atom and the
electrons associated with it. Remember that
formal charges are associated with covalent
bonds and that all electrons are shared equally.
3. compare to the group number for that atom. If
the number is larger the formal charge is
negative, smaller the formal charge is positive.
To calculate an oxidation number
1. list all the elements follow with an equal sign
2. follow with the number of atoms of that type in the
molecule
1. follow with a multiplication sign
2. If the element is O follow with a -2
3. If the element is H follow with a +1
4. any other element enter a ?
5. follow with an = sign, do the math
6. draw a total line, then enter the charge on the molecule
7. Do the algebra backwards to solve for ?
VSEPR Theory
Lone pair to lone pair is the strongest repulsion.
2 Lone pair to bonding pair is intermediate repulsion.
3 Bonding pair to bonding pair is weakest repulsion.
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Mnemonic for repulsion strengths
lp/lp > lp/bp > bp/bp
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Lone pair to lone pair repulsion is why bond angles in water are less than 109.5o.
Electronic geometry is determined by the locations of regions of high electron density around the central
atom(s). Electron pairs are not used in the molecular geometry determination just the positions of
the atoms in the molecule are used.
Molecular geometry determined by the arrangement of atoms around the central atom(s).
Summary of Electronic & Molecular Geometries
Regions of High Electron
Density
Electronic Geometry
Hybridization
2
Linear
sp
3
Trigonal planar
sp2
4
Tetrahedral
sp3
5
Trigonal bipyramidal
sp3d
6
Octahedral
sp3d2