Unit 6 Practice Packet: Bonding PDF

Summary

This is a practice packet for unit 6 on chemical bonding. It contains vocabulary definitions, practice questions, and activities that could be used to teach or assess the topic of bonding.

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PRACTICE PACKET UNIT 6: BONDING
Regents Chemistry: Mr. Palermo

Practice Packet
Unit 6: Bonding

Vocabulary: _______________
Lesson 1: __________________
Lesson 2: __________________
Review: __________________
Lesson 3: __________________
Lesson 4: __________________
Lesson 5: __________________
Lesson 6: ___________________

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PRACTICE PACKET UNIT 6: BONDING

Vocabulary
For each word, provide a short but specific definition from YOUR OWN BRAIN! No boring textbook
definitions. Write something to help you remember the word. Explain the word as if you were explaining
it to an elementary school student. Give an example if you can. Don’t use the words given in your
definition!

Ionic Bond: ___________________________________________________________________________________________________________

Covalent Bond: _______________________________________________________________________________________________________

Metallic Bond: ________________________________________________________________________________________________________

Molecular: ____________________________________________________________________________________________________________

Sea of mobile electrons: _____________________________________________________________________________________________

Electronegativity: ____________________________________________________________________________________________________

Polar Bond: ___________________________________________________________________________________________________________

Nonpolar Bond: ______________________________________________________________________________________________________

Polar Molecule: ______________________________________________________________________________________________________

Nonpolar Molecule: __________________________________________________________________________________________________

Linear Molecule: _____________________________________________________________________________________________________

Bent Molecule: _______________________________________________________________________________________________________

Pyramidal Molecule: _________________________________________________________________________________________________

Tetrahedral Molecule: _______________________________________________________________________________________________

Shared pairs: ________________________________________________________________________________________________________

Unshared pairs: ______________________________________________________________________________________________________

Symmetrical: _________________________________________________________________________________________________________

Intermolecular Forces: ______________________________________________________________________________________________

Hydrogen Bonding: __________________________________________________________________________________________________

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PRACTICE PACKET UNIT 6: BONDING
INQUIRY LESSON1:

SUBSTANCE MODEL #1:
For each of the following substances, place the symbol of the first element in its spot on the periodic table
using pen. Then, place the symbol of the second element in the substance in its spot on the periodic table
using pencil.
NaCl LiBr KF ZnCl2 Fe2O3 CuI2 Al2S3

QUESTIONS FOR SUBSTANCE MODEL #1:
1. Where are all the first elements located on the periodic table (symbols in pen)?

2. Based on your knowledge about the periodic table, what “classification” would you give these
elements? Metal or Non-Metal?

3. Where are all the second elements located on the periodic table (symbols in pencil)?

4. Based on your knowledge about the periodic table, what “classification” would you give these
elements? Metal or Non-Metal?

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PRACTICE PACKET UNIT 6: BONDING
SUBSTANCE MODEL #2

For each of the following substances, place the symbol of the first element in its spot on the periodic
table. Then, place the symbol of the second element in the substance in its spot on the periodic table.
CCl4 P2O5 N2O4 NI3 PBr3 F2Se

QUESTIONS FOR SUBSTANCE MODEL #2:
1. Where are all the first elements located on the periodic table?

2. Based on your knowledge about the periodic table, what “classification” would you give these
elements? Metal or Non-Metal?

3. Where are all the second elements located on the periodic table?

4. Based on your knowledge about the periodic table, what “classification” would you give these
elements? Metal or Non-Metal?

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PRACTICE PACKET UNIT 6: BONDING
TYING IT TOGETHER:
1. MODEL 1 substances are called ionic compounds and MODEL 2 substances are called covalent
molecules. Write a simple rule that will allow you to classify compounds as ionic or covalent on
the basis of what you have learned from the model.

2. Did the subscripts (the little numbers shown in the compound formulas) provide any insight into
determining whether a substance is ionic or covalent? Why or why not?

ELEMENT EVALUATION:
Fill in the following tables identifying the type of element present in the substance. Use “M” for metal,
and “NM” for non-metal.

1ST ELEMENT 2nd ELEMENT CLASSIFICATION
FORMULA
(Metal Or Non Metal) (Metal Or Non Metal) (Ionic or Covalent?)

NaBr

SF6

CoBr2

BaS

NO2

C6H6

CrCl3

Determine the Properties of Ionic and Covalent Substances (At your lab station, observe the
properties of both ionic and covalent substances and write them in the table below.

Ionic Properties Covalent Properties

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 PRACTICE PACKET UNIT 6: BONDING
LESSON 1: INTRO TO BONDING & TYPES OF BONDS
Objective:
 Identify whether a bond is being broken or formed based upon energy being absorbed or released
 Distinguish between the three types of bonds and Decide which type of bond is present based
upon the atoms involved
 Classify a substance as Ionic, Covalent or Metallic based upon its properties

1. For each phrase, check either “bond breaking” or “bond forming”

Bond Bond
Breaking Forming
a. Stability of the chemical system increases
b. Energy is released
c. Cl + Cl  Cl2
d. exothermic
e. endothermic
f. N2  N + N
g. Energy is absorbed
h. Stability of the chemical system decreases
Complete the Venn diagram below with properties of ionic and Covalent Bonds:

Ionic Bonds Covalent
Bonds
Bonds formed between two nonmetals are _______________ and involve the ____________ of electrons.

Bonds formed between two atoms of the same metal involve a sea of _______________________ electrons.

Bonds formed between metals and nonmetals are ____________ and involve the ___________ of electrons.
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PRACTICE PACKET UNIT 6: BONDING
Describe the following as ionic, metallic, or covalent (molecular):

NaCl _____ Al _____ Lithium _____

CO2 _____ C6H12O6 _____ Strontium bromide _____

Au _____ Ti _____ Tin (II) chloride _____

MgBr2 _____ K2O _____ Nitrogen (IV) oxide _____

Fe _____ CH4 _____ Hydrogen selenide _____

H2O _____ H2S _____ Copper (II) phosphate _____

Ca3(PO4)2 _____ PI3 _____ Lead (IV) nitrate _____

REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
LESSON 2: Bond Polarity
Objective:
 Assess compounds and identify the presence polyatomic ions
 Describe the type of bonds present in a polyatomic ion

1. Electronegativity values generally _______________ down a group and ____________ across a period.
2. Metals tend to have ____________ electronegativity values and nonmetals are _____________ values.

Fill in the table below determining if the substance is ionic or covalent. If it is covalent then
determine the electronegativity difference to identify if the covalent bond is polar or nonpolar.

Covalent

Substance Ionic Electronegativity
Polar Non Polar
Difference

1. I2

2. PCl3

3. SiO2

4. Br2

5. CO2

6. NaCl

7. CH4

8. N2O5

9. NH3

10. KCl

11. Indicate which atom will have the positive charge and which will have the negative charge in the
following polar bonds:

H-Cl H-F S-F N-O

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PRACTICE PACKET UNIT 6: BONDING

12. Organize the following in order from least to most polar bonds: HCl, HF, H2O, NH3, HI

13. Identify and explain each bond drawn below:
Type of Bond Explanation

For each statement check if it describes ionic, polar covalent, nonpolar covalent, or metallic bonds:
Ionic Polar Nonpolar Metallic
Covalent Covalent
15. A transfer of electrons between two atoms
16. Positive nuclei dispersed in a sea of mobile electrons
17. Metals and nonmetals bonding
18. One atom loses, and another atom gains electrons
19. Two atoms share electrons equally
20. Metals bonding only
21. Electronegativity differences under 0.4
22. A bond resulting from electrostatic charges between opposite
charged particles
23. Two atoms share electrons unequally
24. Nonmetals bonding only
25. Electronegativity differences over 0.4 and between 2 Non
metals

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PRACTICE PACKET UNIT 6: BONDING

REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
PROPERTIES OF BONDS REVIEW:
1. Imagine you shrunk yourself down to the size of a molecule and were placed inside a beaker of water.
Draw what you would see after you dissolved NaCl in the water.

2. Why does NaCl(aq) conduct electricity but NaCl(s) does not?

3. Imagine you shrunk yourself down to the size of a molecule and were placed inside a beaker of water.
Draw what you would see after you dissolved C6H12O6 in the water.

4. Why doesn’t C6H12O6 (aq) conduct electricity?

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PRACTICE PACKET UNIT 6: BONDING
At each lab station is a substance to be tested. Using the conductivity tester, determine if the substance
conducts in the solid phase and record in the table below. Now using the tester, determine if the substance
conducts in solution (aq). Wipe of the end of the tester with a paper towel and move on to the next station.
Use information in the table below to identify each compound as Ionic or Covalent Compounds.

Substance Phase at Conductivity as Conductivity as a Melting Point Ionic or
Room a pure solid liquid Covalent
Temperature (aq or molten)
A solid 1049oC
B solid 223oC
C liquid 20oC
D solid 378oC
E liquid -94oC
F solid 650oC

List the properties of Ionic compounds: _________________________________________________________

List the properties of Covalent compounds: ______________________________________________________

5. For each example, check if it describes breaking or forming bonds:
Breaking bonds Forming bonds
The stability of the system increases
N2  N + N
Endothermic
I + I  I2
The stability of the system decreases
Exothermic

6. For each example provide the molecule, bond and determine when and if it conducts electricity:
Type of Bond Type of Molecule Conducts electricity?
(Metallic, ionic, covalent, (metallic, ionic, molecular) (check all that apply)
both ionic and covalent)
No (s) (l) (aq)
a. Li2O
b. AlCl3
c. F2
d. CH4
e. HI
f. Fe
g. Na3PO4
h. CaO

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PRACTICE PACKET UNIT 6: BONDING

7. Indicate which type of substance is described by each statement.
Type of substance
a.Can conduct electricity in the solid and liquid phases
A soft substance whose atoms are held together by
b.
covalent bonds
c. Low melting point and poor electrical conductor
d. Can conduct electricity when aqueous or molten (liquid)
e. Can be polar or nonpolar
f. Can dissolve in water to produce mobile ions

8. Explain the following in terms of charged particles:
a. liquid mercury is a good electrical conductor

b. molten NaCl conducts electricity while solid NaCl does not

c. an aqueous solution of KBr conducts electricity while solid KBr does not

d. CH4 is a poor electrical conductor

How do you rate your understanding so far?

4 I “get” it.
3 I am almost there
2 I need help
1 I need lots of help

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PRACTICE PACKET UNIT 6: BONDING
INQUIRY ACTIVITY LESSON 3

Lewis Dot Lewis Dot Structure Becomes
Metal or Gain or lose How
Element Structure of Stable ION like which
Nonmetal electrons? many e-
as an ATOM noble gas?

Lithium

Aluminum

Radium

Fluorine

Sulfur

Phosphorous

Recall that all compounds are neutral so the total charge must equal zero. Using your chart, draw
Lewis structures for the following compounds:
Lithium Fluoride Lithium Sulfide Lithium Phosphide

Aluminum Fluoride Aluminum Sulfide Aluminum Phosphide

Radium Fluoride Radium Sulfide Radium Phosphide

1. Why do the metals bond with nonmetals?

2. What determines how many atoms of the metal and nonmetal will combine to form the compound?

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PRACTICE PACKET UNIT 6: BONDING
LESSON 3: LEWIS (ELECTRON) DOT DIAGRAMS FOR IONIC COMPOUNDS

Objective:
 Construct Lewis diagrams for ionic compounds

1. Complete the table below (electron dot diagrams for ions)

Electron- Electron Electron- Electron
Ion dot Configuration Ion dot Configuration
Diagram structure
sodium oxide
a. c.
Na+ O2
aluminum bromide
b. d.
Al3+ Br

2. How many valence electrons do cations show in the Lewis dot diagrams? ____ anions? ____

3. Draw the following LEWIS DOT DIAGRAMS for ionic compounds and give their formula and/or name:

Lewis Diagram Formula Lewis Diagram Name
Sodium fluoride CsCl

Potassium oxide MgO

Rubidium nitride SrI2

Calcium bromide BaS

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PRACTICE PACKET UNIT 6: BONDING
Lewis Diagram Formula Lewis Diagram Name
Strontium sulfide Fe2O3

Aluminum iodide CuO

Copper (I) sulfide NiCl3

REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
LESSON 4: LEWIS (ELECTRON) DOT DIAGRAMS FOR COVALENT
SUBSTANCES
Objective:
 Construct lewis dot diagrams for covalent compounds

Complete the chart.

Compound Total valence Lewis Diagram Shared pairs of Unshared pairs of
electrons electrons electrons
H2
2 H:H 1 0

F2

O2

H2O

Cl2

NH3

CO2

CH4

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PRACTICE PACKET UNIT 6: BONDING
Compound Total valence Lewis Diagram Shared pairs of Unshared pairs of
electrons electrons electrons
CCl4

N2

HF

H2S

REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
LESSON 5: MOLECULAR POLARITY
Objective:
 Determine the polarity of a molecule
 Determine the shape of a molecule

1. Fill in the chart below.

2. In terms of lone pair electrons, how can you determine if a molecule is polar?

3. What molecular shapes are always polar?

4. What molecular shapes are always nonpolar?

5. How can a molecule be nonpolar if it contains polar bonds?

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PRACTICE PACKET UNIT 6: BONDING
6. Fill in the chart below

Molecule Dot Diagram Distribution of Charge Molecular Polarity Molecular Shape
(symmetrical or (polar or nonpolar (linear, pyramidal,
asymmetrical) molecule) tetrahedral or bent)

CO2

CH4

NH3

H2O

REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
LESSON 6: INTERMOLECULAR FORCES (IMF’S)
Objective:
 Determine the type of intermolecular force that exists between covalent compounds

1. Fill in the table below:

London Dipole-Dipole Hydrogen Bonds
Dispersion Forces Forces **only force tested on
Regents

Type of molecule

Strength

Example

In terms of Intermolecular Forces, to explain the following phenomenon:

2. Why does gasoline (C8H18) remain in the liquid phase but our Bunsen burner gas made out of the
same elements (CH4) remain in the gas phase?

3. Why does dry ice (solid CO2) sublime (go from a solid directly to a gas) at room temperature but sugar
and salt don’t even melt?

4. Which substance has the strongest intermolecular forces of attraction and which has the weakest?
Molar mass Boiling Point
(˚C)

H2O 18.0 100

H2S 34.1 -62

H2Se 81.0 -42

H2Te 129.6 -2

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5. In terms of intermolecular forces, why does water have the highest boiling point in the table above?

6. Which substance has the strongest intermolecular forces of attraction and which has the weakest?
Molar mass Boiling Point
(˚C)

HF 20.0 19

HCl 36.5 -84

HBr 80.9 -67

HI 12.9 -35

7. Why does HF have the highest boiling point in the table above?

8. Surface tension is a result of strong intermolecular forces. Which of the compounds in question 4 has
the strongest surface tension?

9. Which of the following will have the higher boiling point? Explain your answer using intermolecular
forces. NH3 or N2

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PRACTICE PACKET UNIT 6: BONDING
REGENTS PRACTICE

ASSESS YOURSELF ON THIS LESSON:
If you missed any regents practice questions you should see me for extra help and/or re-watch the lesson video assignment

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PRACTICE PACKET UNIT 6: BONDING
READING: NETWORK SOLIDS
The best example of a network solid is a “diamond”. Look at the model of a diamond below. Note that the
carbon atoms are bonded together with covalent bonds. The basic building unit is an atom of carbon. The
structure has a very definite tetrahedral crystal shape, because these atoms are arranged and held rigidly in a
fixed pattern. A diamond is very hard (a “10” on the Moh’s Scale of Hardness…the highest value possible). In
order to scratch a diamond, you must break 1000’s of very strong covalent bonds! Similarly, to melt (or boil) a
network solid, like a diamond, you must break 1000’s of these covalent bonds. This involves considerable
energy and is the reason for their high melting points. It is because of these high temperatures and their
hardness that network solids are frequently used in industry as “abrasives” (on sandpaper and on the tips of
drills for cutting tools). You don’t have to worry about them melting if it gets too hot from friction or being
scratched and dulled when contacting most other surfaces. Network solids have the type of properties you
would expect from atoms being held together via strong covalent bonds, e.g. diamonds. They have very high
melting points and are practically insoluble; are mostly nonconductors (no free electrons or ions); and they are
very brittle (atoms must maintain a fixed crystal structure, if they are pushed too close together …. they repel).

Graphite is also shown below. Note that it is also pure carbon, like a diamond. However, the covalent bonds
only attach carbon atoms in 2 directions, not 3 like diamonds. The dashed lines between the layers of
covalently bonded carbon atoms represent weak Van der Waal forces. Graphite is a 2 dimensional network
solid. The strong covalent bonds only go in “plates”, in 2 directions. The “plates” are connected via weak VDW
forces. Graphite STILL has a high melting point. – You must weaken/break all of its bonds (VDW and Covalent)
to melt it. But since the weaker VDW forces are present and break easily, graphite is often used as a “dry
lubricant”. If you squirt graphite dust into a lock, it will lodge between the lock’s moving metallic parts. When
you put in a key and turn, the graphite structure will break apart between its “plates.” VDW’s break and make
it turn more easily. Graphite also has free, “delocalized” electrons (it is a resonant structure… there really are
no double bonds present, but free electrons) thus…graphite is a network solid that is capable of conducting
electricity. This is not characteristic of most network solids. Of course, pencil lead is graphite. What bonds
break when you write??? Silicon bonds like carbon to form a network structure. The computer industry
depends on “silicon chips,” which are made conductive by placing impurities in their structure. These then
provide for free electrons and allow the chip to do its job. But, pure silicon does not conduct.

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Many network solids are composed of various combinations of relatively few elements on the periodic table.
The elements B, C, Al, Si are found in many network solids. They can be pure or combine with one another or
combine with elements near them. For example, SiO2, quartz is an example of a network solid. Corundum,
Al2O3, is a network and a common abrasive used on “sandpaper”. Many gemstones, like diamond, are network
solids. Emerald is made of the mineral “beryl”. Its formula is Be3Al2 (Si6O18). Ruby is a form of corundum.

1. What is a Network solid? Give an example

2. What are some physical properties of Network solids?

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