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Chemistry
1-8 Math
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SELECT SUBJECT
All Chemistry
A.
Properties of Matter
B.
Atomic Structure
C.
Periodic Table
D.
Chemical Bonding
E.
Chemical Reactions
F.
Measurements and Calculations
G.
Stoichiometry
H.
Kinetic Molecular Theory
I.
Solutions
J.
Rates of Reactions and Equilibrium
K.
Acids and Bases
L.
Thermochemistry
M.
Oxidation-Reduction Reactions and Electrochemistry
N.
Nuclear Chemistry
O.
Organic Chemistry
Chemistry
»
D.
Chemical Bonding
D.1.
Intramolecular Forces
D.1.M.
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D.1.Q.
Unit Challenge
D.1.1.
Ionic Bonding
D.1.1.O.
Overview
D.1.1.1.
Identifying ionic bonding
D.1.1.2.
Predicting when two elements will take part in ionic bonding
D.1.1.3.
Recognizing polyatomic ions
D.1.1.4.
Writing ionic compounds
D.1.1.5.
Naming ionic compounds
D.1.1.6.
Naming using the stock system for transitional metals
D.1.1.7.
Oxidation states and oxidation numbers
D.1.2.
Covalent Bonds
D.1.2.O.
Overview
D.1.2.1.
Identifying a covalent bond
D.1.2.2.
Identifying polar and nonpolar covalent bonds with symbols
D.1.2.3.
Identifying polar and nonpolar covalent bonds with electronegativities
D.1.2.4.
Naming and formula writing for covalent bonds
D.1.3.
Metallic Bonds
D.1.3.O.
Overview
D.1.3.1.
Identifying properties of metallic bonds
D.1.4.
Comparing Types of Bonds
D.1.4.O.
Overview
D.1.4.1.
Ordering strength of bonds of intramolecular forces
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D.2.
Network Solids/Crystalline Solids
D.2.M.
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D.2.Q.
Unit Challenge
D.2.1.
Ionic Crystals
D.2.1.O.
Overview
D.2.1.1.
Identifying force that hold bonds together
D.2.1.2.
Identifying properties such as hardness and electrical conductivity, melting point
D.2.2.
Covalent Crystals
D.2.2.O.
Overview
D.2.2.1.
Identifying force that hold bonds together
D.2.2.2.
Identifying properties such as hardness and electrical conductivity, melting point
D.2.3.
Molecular Crystals
D.2.3.O.
Overview
D.2.3.1.
Identifying force that hold bonds together
D.2.3.2.
Identifying properties such as hardness and electrical conductivity, melting point
D.2.4.
Metallic Crystals
D.2.4.O.
Overview
D.2.4.1.
Identifying force that hold bonds together
D.2.4.2.
Identifying properties such as hardness and electrical conductivity, melting point
D.2.5.
Comparing Crystals
D.2.5.O.
Overview
D.2.5.1.
Compare properties of all crystals
D.2.5.2.
Compare relative strengths of crystals
D.2.6.
Hydrates
D.2.6.O.
Overview
D.2.6.1.
Finding the percent composition of water in a hydrate
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D.3.
Lewis Dot Structures
D.3.M.
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D.3.Q.
Unit Challenge
D.3.1.
Atoms and Monatomic Ions
D.3.1.O.
Overview
D.3.1.1.
Drawing Lewis dot structures for individual atoms using the period table and number of valence electrons
D.3.1.2.
Drawing Lewis dot structures for monatomic ions
D.3.1.3.
Finding incorrect Lewis dot structures for elements
D.3.2.
Molecules and Polyatomic Ions
D.3.2.O.
Overview
D.3.2.1.
Predicting ionic formula based on Lewis dot structure
D.3.2.2.
Drawing Lewis dot structures for simple molecules
D.3.2.3.
Drawing Lewis dot structures for simple polyatomic ions
D.3.2.4.
Calculating formal charges
D.3.2.5.
Finding incorrect Lewis dot structures for compounds and ions
D.3.3.
Molecules and Polyatomic Ions with Double and Triple Bonds (Sigma and Pi Bonds)
D.3.3.O.
Overview
D.3.3.1.
Drawing Lewis Dot Structures with double bonds
D.3.3.2.
Drawing Lewis Dot structures with triple bonds
D.3.3.3.
Identifying Resonance structures
D.3.3.4.
Comparing bond lengths for single, double, and triple bonds
D.3.3.5.
Comparing bond lengths considering resonance structures
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D.4.
Molecular Geometry (VSEPR Model)
D.4.M.
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D.4.Q.
Unit Challenge
D.4.1.
VSEPR Model
D.4.1.O.
Overview
D.4.1.1.
Predicting molecular arrangement or shape based on electron pairs
D.4.1.2.
Predicting molecular arrangement or shape from bond angles
D.4.1.3.
Predicting linear shape
D.4.1.4.
Predicting bent shape (2 bonded, 1 lone pair)
D.4.1.5.
Predicting trigonal planar shape
D.4.1.6.
Predicting tetrahedral shape
D.4.1.7.
Predicting trigonal pyramidal shape
D.4.1.8.
Predicting bend shape (2 bonded, 2 lone pairs)
D.4.1.9.
Predicting trigonal bipyramidal shape
D.4.1.10.
Predicting octahedral shape
D.4.2.
Hybridization
D.4.2.O.
Overview
D.4.2.1.
Recognizing sp hybrid orbitals
D.4.2.2.
Recognizing sp
2
hybrid orbitals
D.4.2.3.
Recognizing sp
3
hybrid orbitals
D.4.2.4.
Recognizing sp
3
d hybrid orbitals
D.4.2.5.
Recognizing sp
3
d
2
hybrid orbitals
D.4.3.
Sigma and Pi Bonds
D.4.3.O.
Overview
D.4.3.1.
Identifying sigma bonds
D.4.3.2.
Identifying pi bonds
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D.5.
Intermolecular Bonds
D.5.M.
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D.5.Q.
Unit Challenge
D.5.1.
Hydrogen Bonding
D.5.1.O.
Overview
D.5.1.1.
Identifying differences between hydrogen bonding and covalent bonding and polarity
D.5.1.2.
Identify how Cohesion and adhesion produce capillary action of water
D.5.1.3.
Identify how surface tension in water forms
D.5.1.4.
Identify specific density properties associated with hydrogen bonding
D.5.1.5.
Identify reason for high boiling point
D.5.1.6.
Predicting whether a compound most likely will form hydrogen bonds
D.5.2.
Van der Waals Forces
D.5.2.O.
Overview
D.5.2.1.
Identifying a Dipole-Dipole force
D.5.2.2.
Identifying Ion-Dipole force
D.5.2.3.
Identifying London dispersion Forces
D.5.2.4.
Ordering relative strength of Van der Waals Force compared to other forces
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