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Slide 1 / 126 Slide 2 / 126
AP Chemistry
Compounds
2015-09-14
www.njctl.org
Slide 3 / 126
Table of Contents: Compounds Pt. B
· States of Matter
· Molecular Geometry
Click on the topic to go to that section
· Introduction to Solubility
· Intermolecular Forces
Slide 4 / 126
Molecular Geometry
Return to Tableof Contents
Slide 5 / 126
Molecular Shapes
Molecules are three dimensional objects. Their shapes affect their properties. In order to determine the shape of a molecule we use Valence-Shell Electron-Pair Repulsion theory (VSEPR).
According to VSEPR theory, the molecules will adopt a shape/geometry that will reduce the repulsion between the bonded electrons; the electrons want to be as far apart as possible.
Slide 6 / 126
VSEPR NumbersVSEPR theory assigns a 3-digit code to each molecular shape.
To determine this code we must first sketch the Lewis structure.
1. The first digit of the VSEPR number is the total number of electron-domains around the central atom. That means the total number of bonds and lone pairs. Note: Double and triple bonds only count as 1 electron domain.
3 6
O
O
O
3
Slide 7 / 126
Molecular Shape and VSEPR TheoryElectron Domain Geometries
"AB" Designation
(# of bonds)
# of unbonded pairs of
electrons on "A" atom
Shape Bond Angles Example
AB2 0 linear 180
AB3 0 trigonal planar 120
AB4 0 tetrahedral 109.5
AB5 0 trigonal bypyramidal
90, 120, 180
AB6 0 octahedral 90, 180
**Note: Pi bonds act with the sigma bonds to contribute to the repulsions that result in the molecular shape, however they do not act as a separate constituent around the "A" atom.
Slide 8 / 126
1 What is the electron domain geometry of CH4?
A linearB trigonal planarC tetrahedralD octahedral
Slide 8 (Answer) / 126
1 What is the electron domain geometry of CH4?
A linearB trigonal planarC tetrahedralD octahedral
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C
Slide 9 / 126
2 What is the EDG of H2O?
A linearB trigonal planarC tetrahedralD octahedral
H H
O
Slide 9 (Answer) / 126
2 What is the EDG of H2O?
A linearB trigonal planarC tetrahedralD octahedral
H H
O
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Ans
wer
C
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3 What is the EDG of CO2?
A linearB trigonal planarC trigonal bipyramidalD octahedral
C OO
Slide 10 (Answer) / 126
3 What is the EDG of CO2?
A linearB trigonal planarC trigonal bipyramidalD octahedral
C OO
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Ans
wer
B
Slide 11 / 126
VSEPR Numbers2. The second digit of the VSEPR number is the total number of bonding-domains around the central atom. That means the number of single, double or triple bonds. Remember, double and triple bonds only count as 1 domain.
3 3 6 4
O
O
O
3 2
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4 Students type their answers here
3 3 0 6 4 2
O
O
O
3 2 1
VSEPR Numbers3. The third digit of the VSEPR number is the total number of lone pairs around the central atom.
You can check your work - the first digit is always equal to the
sum of the second and third.
What are the shapes of BH3, XeF4, and O3?
Slide 12 (Answer) / 126
4 Students type their answers here
3 3 0 6 4 2
O
O
O
3 2 1
VSEPR Numbers3. The third digit of the VSEPR number is the total number of lone pairs around the central atom.
You can check your work - the first digit is always equal to the
sum of the second and third.
What are the shapes of BH3, XeF4, and O3?
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Ans
wer
BH3 - Trigonal Planar
XeF4 - Square Planar
O3 - Bent117
Slide 13 / 126
Molecular Geometry
The molecular geometry of a molecule is the shape formed by the bonded atoms. Lone pairs may play a role by decreasing the angle between bonded elements. This occurs because lone pairs generate a greater force of repulsion.
Click here to view a PhET simulation
Slide 14 / 126
I
NF 3Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
For Ions
+ -
Slide 14 (Answer) / 126
I
NF 3Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
For Ions
+ -
[This object is a pull tab]
Ans
wer
N F
F
F
4 3 1EDG: tetrahedralMG: trigonal pyramidal
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I
SiF 4Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
Slide 15 (Answer) / 126
I
SiF 4Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
[This object is a pull tab]
Ans
wer
4 4 0EDG: tetrahedralMG: tetrahedral
F
Si
F
F F
Slide 16 / 126
I
IF5Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
Slide 16 (Answer) / 126
I
IF5Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
[This object is a pull tab]
Ans
wer
6 5 1EDG: octahedralMG: square pyramidal
FFI
FF F
Slide 17 / 126
I
NO 2-Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
Slide 17 (Answer) / 126
I
NO 2-Practice
Elements Bonds & Electrons
Cl H C O N SF Xe B
Draw a Lewis Structure and determine the electron domain geometry (EDG) and the molecular geometry (MG).
Si For Ions
+ -
[This object is a pull tab]
Ans
wer
3 2 1EDG: trigonal planarMG: bent
NO O
-
Slide 18 / 126
5 Which of the following would have a see-saw shape?
A I only
B II only
C III only
D I and II only
I. XeO2F2
II. IBr3
III. SeH2
Slide 18 (Answer) / 126
5 Which of the following would have a see-saw shape?
A I only
B II only
C III only
D I and II only
I. XeO2F2
II. IBr3
III. SeH2
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Ans
wer
A
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6 Which of the following is ranked properly from largest to smallest bond angles within the molecule?
A II only
B III only
C II and III only
D I, II, and III
I. CH4, PCl3, SF5
II. XeF2, H2O, XeF4
III. NO3-, NO2
-, CH4
Slide 19 (Answer) / 126
6 Which of the following is ranked properly from largest to smallest bond angles within the molecule?
A II only
B III only
C II and III only
D I, II, and III
I. CH4, PCl3, SF5
II. XeF2, H2O, XeF4
III. NO3-, NO2
-, CH4
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Ans
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D
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7 Which of the following does NOT have a bent shape?
A BeCl2
B SeH2
C SCl2
D OH2
Slide 20 (Answer) / 126
7 Which of the following does NOT have a bent shape?
A BeCl2
B SeH2
C SCl2
D OH2
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Ans
wer
A
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8 Which of the following has a planar shape?
A C2H4
B PH3
C SiH4
D PF5
Slide 21 (Answer) / 126
8 Which of the following has a planar shape?
A C2H4
B PH3
C SiH4
D PF5
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Ans
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A
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9 Which of the following contribute to the shape of the molecule?
A Only the number of bonded e- pairs around atom
B Only the number of un-bonded and bonded e- pairs around the atom
C Only the atomic radii of atoms
D Only the atomic radii and bonded e- pairs around the atom
Slide 22 (Answer) / 126
9 Which of the following contribute to the shape of the molecule?
A Only the number of bonded e- pairs around atom
B Only the number of un-bonded and bonded e- pairs around the atom
C Only the atomic radii of atoms
D Only the atomic radii and bonded e- pairs around the atom
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B
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10 Which of the following is TRUE regarding the effect of substitution of un-bonded pairs of electrons in place of bonded pairs of electrons on the molecular shape?
A The bond angle increases due to the decreased repulsions
B The bond angle decreases due to the decreased repulsions
C The bond angle decreases due to the increased repulsions
D The bond angle increased due to the increased repulsions
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10 Which of the following is TRUE regarding the effect of substitution of un-bonded pairs of electrons in place of bonded pairs of electrons on the molecular shape?
A The bond angle increases due to the decreased repulsions
B The bond angle decreases due to the decreased repulsions
C The bond angle decreases due to the increased repulsions
D The bond angle increased due to the increased repulsions
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Ans
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C
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11 Which of the following would be the correct shape of the BF3 molecule?
A bent
B trigonal planar
C trigonal pyramidal
D see-saw
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11 Which of the following would be the correct shape of the BF3 molecule?
A bent
B trigonal planar
C trigonal pyramidal
D see-saw
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Ans
wer
B
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Slide 25 (Answer) / 126 Slide 26 / 126
Molecular Polarity
Two factors contribute to the polarity of a molecule:
Polarity of bonds
Polar bonds are necessary for a molecule to be polar but do not guarantee polarity.
Symmetry
To be polar a molecule must be asymmetrical to ensure an uneven distribution of electrons.
Molecules in which the electrons are not evenly distributed experience a dipole moment when in an electric field and are said to be polar.
Slide 27 / 126
Molecular Polarity
Asymmetrical Shapes
Bent, Trigonal pyramidal, T-Shape, See-saw, Square pyramidal
Asymmetry and polarity can also result from a heterogenous group of atoms attached to the central atom thereby creating asymmetrical differences in electronegativity. CHCl3 is a classic example. -
-
-
+
Certain shapes are asymmetrical in nature due to unbonded electrons and can, therefore, result in polar molecules.
Slide 28 / 126
Molecular Polarity
H2O H2S
SH H
Both molecules are asymmetrical and exhibit a dipole moment but water's dipole moment is significantly
higher than hydrogen sulfide due to the greater electronegativity difference between O and H.
Dipole moment = 1.85 D Dipole moment = 0.97 D
If the molecule is asymmetrical, the more polar the bonds, the more polar the molecule
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13 Which of the following molecules would have the highest dipole moment?
A NH3
B PH3
C BF3
D CH4
Slide 29 (Answer) / 126
13 Which of the following molecules would have the highest dipole moment?
A NH3
B PH3
C BF3
D CH4
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Ans
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A
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14 Which of the following molecules would be expected to have the highest dipole moment?
A BeCl2
B CO2
C HCN
D H2S
Slide 30 (Answer) / 126
14 Which of the following molecules would be expected to have the highest dipole moment?
A BeCl2
B CO2
C HCN
D H2S
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Ans
wer
C
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15 Which of the following is TRUE regarding molecular polarity?
A Polar molecules must be asymmetrical and have polar bonds
B Polar molecules must have polar bonds and can be symmetrical or asymmetrical
C Polar molecules cannot have polar bonds
D Polar molecules do not require polar bonds but do require asymmetry
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15 Which of the following is TRUE regarding molecular polarity?
A Polar molecules must be asymmetrical and have polar bonds
B Polar molecules must have polar bonds and can be symmetrical or asymmetrical
C Polar molecules cannot have polar bonds
D Polar molecules do not require polar bonds but do require asymmetry
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A
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16 Which of the following explains the low dipole moment of CCl4 (0.0 D)?
A There is a small electronegativity difference between C and Cl
B The bonds are non-polar
C The molecule is symmetrical
D The atoms in the molecule are small
E The IR spectra for the molecule has few peaks
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16 Which of the following explains the low dipole moment of CCl4 (0.0 D)?
A There is a small electronegativity difference between C and Cl
B The bonds are non-polar
C The molecule is symmetrical
D The atoms in the molecule are small
E The IR spectra for the molecule has few peaks[This object is a pull tab]A
nsw
er
C
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Intermolecular Forces
Return to Tableof Contents
Slide 34 / 126
Intermolecular Forces
INTRAMOLECULAR INTERMOLECULAR
attractive forces within a molecule
attractive forces between different molecules
*Note: Intermolecular forces are much weaker than intramolecular forces due to the greater distance between charges which diminishes the Coulombic attractions.
Covalent bonds are intramolecular forces. The properties of a substance also depend on intermolecular forces (IMFs).
IMFs exist between neighboring molecules as opposed to intramolecular forces which exist inside molecules.
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London Dispersion Forces
London dispersion forces occur between all molecules and are caused by the temporary polarization of molecules due to the
random positions of electrons
e-
e-e-
e-e- e-
e- e-
e- e-
e-e- e-e-e- e-
-+
Normal Polarized
e- e-
e-e- e-e-e- e-
-+e- e-
e-e- e-e-e- e-
-+
These polarized molecules then form attractions called London dispersion forces.
London Dispersion Force
There are essentially two types of IMFs: London Dispersion Forces and Dipole-Dipole Forces.
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London Dispersion Forces
Iodine (I2) Flourine (F2)
106 electrons 18 electrons
MP = 113.7 C, solid @ 25 C MP = -219.7 C, gas @ 25 C
The surface area of the molecule also influences the ability of "LDF's" to form. The greater the surface area, the greater the
"LDF's", all else being equal.
The greater the number of electrons in the molecule, the greater the polarization and the stronger the London
dispersion forces will be.
Slide 37 / 126
17 The indicated interaction pointed to by arrow is an intermolecular force.
True
False
Slide 37 (Answer) / 126
17 The indicated interaction pointed to by arrow is an intermolecular force.
True
False
[This object is a pull tab]A
nsw
er
False
Slide 38 / 126
18 Which of the following is TRUE regarding intra and inter molecular forces?
A Intra are stronger due to decreased coulombic attractions
B Intra are stronger due to increased coulombic attractions
C Inter are stronger due to decreased coulombic attractions
D Inter are stronger due to increased coulombic attractions
Slide 38 (Answer) / 126
18 Which of the following is TRUE regarding intra and inter molecular forces?
A Intra are stronger due to decreased coulombic attractions
B Intra are stronger due to increased coulombic attractions
C Inter are stronger due to decreased coulombic attractions
D Inter are stronger due to increased coulombic attractions
[This object is a pull tab]
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B
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19 Which of the following would experience the greatest London dispersion forces between molecules?
A CO2
B Br2
C H2
D CH4
Slide 39 (Answer) / 126
19 Which of the following would experience the greatest London dispersion forces between molecules?
A CO2
B Br2
C H2
D CH4
[This object is a pull tab]
Ans
wer
B
Slide 40 / 126
20 Which of the following solids would require the least energy to sublimate (change from a solid to a gas)?
A C3H8(s)
B O2(s)
C CH4(s)
D Ar(s)
Slide 40 (Answer) / 126
20 Which of the following solids would require the least energy to sublimate (change from a solid to a gas)?
A C3H8(s)
B O2(s)
C CH4(s)
D Ar(s)
[This object is a pull tab]A
nsw
er
C
Slide 41 / 126
21 Butane (C4H10) can exist as one of two isomers: isobutane and n-butane shown to the right. The melting points of isobutane and n-butane are -160 C and -140 C respectively. Which of the following BEST explains why?
A Isobutane is more polarized due to having fewer electrons
B n-butane is more polarized due to having more electrons
C Isobutane and n-butane have equal numbers of electrons but isobutane has less surface area
D Isobutane and n-butane have equal numbers of electrons but n-butane has more surface area
isobutane
n-butane
Slide 41 (Answer) / 126
21 Butane (C4H10) can exist as one of two isomers: isobutane and n-butane shown to the right. The melting points of isobutane and n-butane are -160 C and -140 C respectively. Which of the following BEST explains why?
A Isobutane is more polarized due to having fewer electrons
B n-butane is more polarized due to having more electrons
C Isobutane and n-butane have equal numbers of electrons but isobutane has less surface area
D Isobutane and n-butane have equal numbers of electrons but n-butane has more surface area
isobutane
n-butane
[This object is a pull tab]
Ans
wer
D
Slide 42 / 126
Dipole-Dipole Forces
Attractions between opposite poles of polar molecules. The more polar the molecule, the greater the charges, which results in
stronger Coulombic attractions.
H Cl
+ -
H Cl
+ -
dipole-dipole force
H F
+ -
H F
+ -
dipole-dipole force
MP = -85 C MP =19 C less polar more polar
Unlike "LDF's", Dipole-Dipole forces exist only between molecules with permanent dipoles and are therefore stronger
than "LDF's" bond for bond.
Slide 43 / 126
Only F, O, and N are electronegative enough to generate the high positive charge on H to necessary to create a hydrogen
bond with a neighboring F, O, or N.
F F
Hydrogen Bonds
Hydrogen BondsHydrogen bonds are a special type of dipole-dipole force that
is generated between the highly electropositive H on a molecule and a highly electronegative atom on a neighboring
molecule.
Slide 44 / 126
NH
OH-Bond
R
O
R
Hydrogen bonding stabilizes the secondary structure of proteins
Intermolecular ForcesHydrogen bonds play an important role in polymers both
synthetic (plastics) and natural (proteins).
Slide 45 / 126
Substance # of e- Strength of LDF's H-Bonds? Boiling Point
(1 atm)
H2Te 106 High No -2.2 C
H2Se 70 Medium No -41.3 C
H2S 34 Low No -60.0 C
H2O 20 Very low Yes 100.0 C
Intermolecular ForcesHydrogen bonds create unexpectedly high melting and boiling
points.
Slide 46 / 126
22 Which of the following would have dipole-dipole intermolecular forces?
A Br2
B CH4
C CH3F
D CF4
Slide 46 (Answer) / 126
22 Which of the following would have dipole-dipole intermolecular forces?
A Br2
B CH4
C CH3F
D CF4
[This object is a pull tab]
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wer
C
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23 In which of the following substances would hydrogen bonding be found between molecules?
A HCl
B CH3F
C CH3NH2
D CH3COCH3
Slide 47 (Answer) / 126
23 In which of the following substances would hydrogen bonding be found between molecules?
A HCl
B CH3F
C CH3NH2
D CH3COCH3
[This object is a pull tab]
Ans
wer
C
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24 The indicated bond is a hydrogen bond.
True
False
Slide 48 (Answer) / 126
24 The indicated bond is a hydrogen bond.
True
False
[This object is a pull tab]
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False
Slide 49 / 126
25 Which of the following arrows points to a hydrogen bond in the molecule below?
AB
C
DE
Slide 49 (Answer) / 126
25 Which of the following arrows points to a hydrogen bond in the molecule below?
AB
C
DE
[This object is a pull tab]
Ans
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E
Slide 50 / 126
Substance LDF Rank H-Bonds DDF
RankMP @1
atm BP @ 1 atm
Heat of Vaporization
H2O 3 Yes 1 0 C 100 C 40.6 kJ/mol
I2 1 No 3 114 C 184 C 41.6 kJ/mol
CH3COCH3 2 No 2 -95 C 56 C 29 kJ/mol
*When comparing properties of molecular compounds, first determine if the molecule is polar. If it is, dipole-dipole forces will be part of the discussion. If not, LDF's will be the only intermolecular force to consider.
Intermolecular ForcesWhen evaluating properties such as boiling point, one must consider the forces present in each substance. Although LDF's are in general weaker than dipole-dipole forces (DDF's), large non-polar molecules can have higher boiling points than smaller polar molecules, even those with hydrogen bonding.
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26 Which of the following best explains why ammonia (NH3) has a higher boiling point than methane (CH4)?
A Ammonia is non-polar and methane is polar
B Ammonia can form hydrogen bonds while methane cannot
C Ammonia has greater london dispersion forces
D Ammonia can form london dispersion forces while methane cannot
Slide 51 (Answer) / 126
26 Which of the following best explains why ammonia (NH3) has a higher boiling point than methane (CH4)?
A Ammonia is non-polar and methane is polar
B Ammonia can form hydrogen bonds while methane cannot
C Ammonia has greater london dispersion forces
D Ammonia can form london dispersion forces while methane cannot
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B
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27 Which of the following best explains how carbon tetrabromide has a higher boiling point than water?
A CBr4 is more polar and can form stronger dipole - dipole forces
B CBr4 can form chlorine bonds which are stronger than hydrogen bonds
C CBr4 has greater London dispersion forces due to the larger electronegativity differences
D CBr4 has greater London dispersion forces due to the greater polarizability of the molecule
Slide 52 (Answer) / 126
27 Which of the following best explains how carbon tetrabromide has a higher boiling point than water?
A CBr4 is more polar and can form stronger dipole - dipole forces
B CBr4 can form chlorine bonds which are stronger than hydrogen bonds
C CBr4 has greater London dispersion forces due to the larger electronegativity differences
D CBr4 has greater London dispersion forces due to the greater polarizability of the molecule
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wer
D
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28 Which of the following would be expected to have the highest heat of vaporization?
A H2
B Kr
C PH3
D CO2
Slide 53 (Answer) / 126
28 Which of the following would be expected to have the highest heat of vaporization?
A H2
B Kr
C PH3
D CO2
[This object is a pull tab]
Ans
wer
C
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29 Which of the following would have the lowest boiling point?
A HI
B I2
C Br2
D F2
Slide 54 (Answer) / 126
29 Which of the following would have the lowest boiling point?
A HI
B I2
C Br2
D F2
[This object is a pull tab]
Ans
wer
D
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30 Which of the following would correctly rank the following from highest to lowest boiling point?
A NH3 > PH3 > CCl4
B CCl4 > NH3 > PH3
C PH3 > NH3 > CCl4
D NH3 > CCl4 > PH3
Slide 55 (Answer) / 126
30 Which of the following would correctly rank the following from highest to lowest boiling point?
A NH3 > PH3 > CCl4
B CCl4 > NH3 > PH3
C PH3 > NH3 > CCl4
D NH3 > CCl4 > PH3
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Ans
wer
B
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States of Matter
Return to Tableof Contents
Slide 57 / 126
Solids, Liquids, and Gases
Property Solid Liquid Gas
Compressibility Very Low Very Low High
Density High High LowViscosity Very High Medium Very Low
Potential Energy Low Medium High
Note: Water is unique in that its liquid state is more dense than the solid state.
Recall that viscosity is the resistance to flow. The weaker the particle interactions, the lower the viscosity.
The properties of each state differ from each other considerably.
Slide 58 / 126
Solids, Liquids, and Gases
Electrical Conductivity of NaCl
NaCl(s) = Non-conductive
NaCl(l) = Conductive
Density of H2O
H2O(l) @ 0 C = 999 g/L
H2O(g) @ 0 C = 0.804 g/L
Viscosity of H2O
H2O (l) @100 C = 0.664 u
H2O (g) @100 C = 0.011 u
The properties of a material will vary depending on its state.
Slide 59 / 126
31 Students type their answers here
Solids, Liquids, and Gases
Why is the viscosity of water is so much less in the gas state?
Slide 59 (Answer) / 126
31 Students type their answers here
Solids, Liquids, and Gases
Why is the viscosity of water is so much less in the gas state?
[This object is a pull tab]
Ans
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The Coulombic attractions are much weaker so the molecules demonstrate very little resistance to the sheering forces that cause molecules to flow past one another.
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Solids
Recall the properties of various solids.
Solid Melting Point Conductivity Malleability
Metallic High Yes High
Ionic High As a liquid LowCovalent Network Very High Some Low
Molecular Low No Low
Slide 61 / 126
Liquids
Hydraulic systems take advantage of a liquids ability to take the shape of its container and low compressibility to exert a force.
Liquids distinguish themselves from the solid phase by the ability to flow due to diminished coulombic attractions between particles.
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Liquids
H2O CH3COCH3 C6H6
Types of attractions
weak LDF's, H-
Bonds
medium LDF's, weak DDF's Strong LDF's
Viscosity (m Pa*s) 0.892 0.308 0.602
Comparing three molecular liquids
*Note: Recall LDF stands for London Dispersion Forces
The viscosity of a liquid is influenced by the strength of the Coulombic attractions between particles.
Slide 63 / 126
Liquids
For instance a 0W-40 oil indicates that the oil will stay thicker (higher viscosity) at both 0C and 100 C than does oil rated as 5W-30.
The viscosity of a motor oil is critical to correct engine performance. Engine oil ratings indicate the resistance to flow at 0C and at 100 C.
If the oil gets too thin, it will not lubricate adequately and goodbye engine!
Slide 64 / 126
32 Which of the following is NOT true regarding the liquid state?
A It is significantly more compressible than the solid state
B The viscosity is less than the solid state
C The density is less than the solid state for most materials
D The Coulombic attractions are weaker than in the solid state
Slide 64 (Answer) / 126
32 Which of the following is NOT true regarding the liquid state?
A It is significantly more compressible than the solid state
B The viscosity is less than the solid state
C The density is less than the solid state for most materials
D The Coulombic attractions are weaker than in the solid state
[This object is a pull tab]
Ans
wer
A
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33 Which of the following is TRUE regarding viscosity?
A The stronger the coulombic attractions, the lower the viscosity
B The higher the temperature, the higher the viscosity
C Solids have lower viscosities than liquids
D A substance with a low viscosity will flow easier than one with a high viscosity
Slide 65 (Answer) / 126
33 Which of the following is TRUE regarding viscosity?
A The stronger the coulombic attractions, the lower the viscosity
B The higher the temperature, the higher the viscosity
C Solids have lower viscosities than liquids
D A substance with a low viscosity will flow easier than one with a high viscosity
[This object is a pull tab]
Ans
wer
D
Slide 66 / 126
34 Which of the following liquids would be expected to have the highest viscosity?
A CH3COCH3
B C6H14
C C4H10
D CH3CH2CH2OH
Slide 66 (Answer) / 126
34 Which of the following liquids would be expected to have the highest viscosity?
A CH3COCH3
B C6H14
C C4H10
D CH3CH2CH2OH
[This object is a pull tab]
Ans
wer
D
Slide 67 / 126
35 Which of the following make gases unsuitable to use in hydraulics?
A They are too viscous
B The Coulombic attractions are too strong
C The gas state is too compressible
D The gas state cannot flow
Slide 67 (Answer) / 126
35 Which of the following make gases unsuitable to use in hydraulics?
A They are too viscous
B The Coulombic attractions are too strong
C The gas state is too compressible
D The gas state cannot flow
[This object is a pull tab]
Ans
wer
C
Slide 68 / 126
Kinetic Molecular Theory of Gases
Assumption 1:
Gas molecules occupy a negligible volume of their container. So... the volume of a gas is assumed to be equal to the volume
of the container. Gas
molecules
Slide 69 / 126
Kinetic Molecular Theory of GasesAssumption 2:
Gas molecules are in constant motion and routinely collide with each other and with the walls of the container thus exerting a
pressure whose magnitude depends on the frequency and forcefulness of these collisions.
Slide 70 / 126
Assumption 3:
Each gas molecule does not experience any Coulombic attractions from the other gas molecules or container and
therefore do not "stick" to each other, resulting in collisions that are perfectly elastic.
Note: These assumptions are based on "ideal" gases. Real gases do not behave exactly this way but it gives us a theoretical framework for discussing the properties of gases.
Kinetic Molecular Theory of Gases
Slide 71 / 126
36 Which of the following is a correct assumption of the kinetic molecular theory of gases?
A Gases do not collide with each other
B Gases collide but lose energy with every collision
C Gases experience weak coulombic attractions between molecules
D A gas occupies a neglible volume of their container
Slide 71 (Answer) / 126
36 Which of the following is a correct assumption of the kinetic molecular theory of gases?
A Gases do not collide with each other
B Gases collide but lose energy with every collision
C Gases experience weak coulombic attractions between molecules
D A gas occupies a neglible volume of their container
[This object is a pull tab]
Ans
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D
Slide 72 / 126
37 Which of the follow is NOT true regarding the difference between gases and the liquid and/or solid states?
A The volume of gas is fixed while the liquid changes volume to fill its container.
B In terms of Coulombic forces: solids > liquids > gases
C Gas particles are in constant motion while liquid and solid particles are relatively fixed.
D In terms of distance between particles: solids < liquids < gases
Slide 72 (Answer) / 126
37 Which of the follow is NOT true regarding the difference between gases and the liquid and/or solid states?
A The volume of gas is fixed while the liquid changes volume to fill its container.
B In terms of Coulombic forces: solids > liquids > gases
C Gas particles are in constant motion while liquid and solid particles are relatively fixed.
D In terms of distance between particles: solids < liquids < gases
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Ans
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A
Slide 73 / 126
38 Kinetic Molecular Theory (KMT) is used to describe the behavior of...
A All gases
B Ideal gases
C Real gases
D Noble gases
Slide 73 (Answer) / 126
38 Kinetic Molecular Theory (KMT) is used to describe the behavior of...
A All gases
B Ideal gases
C Real gases
D Noble gases
[This object is a pull tab]
Ans
wer
B
Slide 74 / 126
Basic Gas Laws
At a given temperature, the gas molecules possess a wide range of kinetic energies. This is known as the Boltzmann distribution.
The higher the temperature, the greater the speed of the gases, the greater the kinetic energy.
*Note: Even at low temperatures, some of the gas molecules have as much energy as the average energy of the gas molecules at a much higher temperature.
# of gas molecules
Molecular speeds
Temperatures
The temperature of a gas is equivalent to the average kinetic energy of the gas molecules
Slide 75 / 126
Basic Gas Laws
The higher the temperature, the greater the speed and kinetic energy of the molecules thereby increasing BOTH the frequency and force of each collision thereby increasing the pressure.
P
T (K)
The greater the number of moles of a gas, the greater the frequency of collisions and the higher the pressure.
P
moles
The pressure of a gas is directly proportional to the Kelvin temperature and the number of moles.
Slide 76 / 126
Basic Gas Laws
As the volume increases, the collisions become less numerous and the pressure decreases.
less collisions more collisions
Pressure
Volume
The pressure of a gas is inversely proportional to the volume.
Slide 77 / 126
Basic Gas Laws
As the temperature increases, the volume must expand against a constant pressure.
V
T (K)
As the number of moles are increased, the volume will expand against a constant pressure.
V
moles
The volume of a gas is directly proportional to the Kelvin temperature and the number of moles.
Slide 78 / 126
39 Which of the following influence the pressure of an ideal gas?
A The frequency of collisions
B The frequency and force of collisions
C The force of collisions
D Neither the frequency or force of collisions
Slide 78 (Answer) / 126
39 Which of the following influence the pressure of an ideal gas?
A The frequency of collisions
B The frequency and force of collisions
C The force of collisions
D Neither the frequency or force of collisions
[This object is a pull tab]
Ans
wer
B
Slide 79 / 126
40 Which of the following would be TRUE when a gas condenses?
A It will become more compressible
B It will become less dense
C The coulombic attractions will decrease
D The potential energy of the molecules will decrease
Slide 79 (Answer) / 126
40 Which of the following would be TRUE when a gas condenses?
A It will become more compressible
B It will become less dense
C The coulombic attractions will decrease
D The potential energy of the molecules will decrease
[This object is a pull tab]
Ans
wer
D
Slide 80 / 126
41 Which of the following is NOT TRUE regarding a gas?
A All N2 gas molecules will have the same kinetic energy at a given temperature
B The volume of a gas is directly related to it's temperature (in Kelvin)
C If the Kelvin temperature of a gas is doubled, the pressure will double all else being constant
D Collisions between gas molecules are elastic
Slide 80 (Answer) / 126
41 Which of the following is NOT TRUE regarding a gas?
A All N2 gas molecules will have the same kinetic energy at a given temperature
B The volume of a gas is directly related to it's temperature (in Kelvin)
C If the Kelvin temperature of a gas is doubled, the pressure will double all else being constant
D Collisions between gas molecules are elastic
[This object is a pull tab]
Ans
wer
A
Slide 81 / 126
42 A gas in a rigid container registers a pressure of 3.2 atm at 0 C. If the temperature is cooled to -20 C, which of the following would be TRUE?
A The volume of the container will decrease.
B The inter-molecular distances will increase
C The average kinetic energy of the gas molecules will increase
D The frequency of collisions will decrease
E None of these
Slide 81 (Answer) / 126
42 A gas in a rigid container registers a pressure of 3.2 atm at 0 C. If the temperature is cooled to -20 C, which of the following would be TRUE?
A The volume of the container will decrease.
B The inter-molecular distances will increase
C The average kinetic energy of the gas molecules will increase
D The frequency of collisions will decrease
E None of these [This object is a pull tab]
Ans
wer
D
Slide 82 / 126
43 Which of the following in NOT true about increasing the pressure on a gas in a sealed container?
A Increasing the pressure will cause the temperature to increase
B With enough pressure the gas will condense to a liquid
C Increasing the pressure will cause the volume to decrease
D Increasing the pressure will decrease the number of moles of gas in the chamber
Slide 82 (Answer) / 126
43 Which of the following in NOT true about increasing the pressure on a gas in a sealed container?
A Increasing the pressure will cause the temperature to increase
B With enough pressure the gas will condense to a liquid
C Increasing the pressure will cause the volume to decrease
D Increasing the pressure will decrease the number of moles of gas in the chamber
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D
Slide 83 / 126
Basic Gas Laws
Example: What would be the effect on the volume of a gas if the pressure were doubled and the temperature were increased from 10 C to 20 C?
SOLUTION
V and P are inversely related, V and T are directly related
Since P doubled, volume will decrease by factor of two.
Since K temperature increased by 293/273, the volume will increase by 293/273.
1 L x 1 atm x 293 K = 0.52 L
2 atm 283 K
The relationships between the various qualities of a gas can be used to predict the change in the pressure, volume, moles,
or temperature of a gas.
Slide 84 / 126
44 A 9 L expandable container containing a gas is heated in an isobaric manner (constant pressure) from 17 C to 117 C. What would be the new volume at 117 C?
Slide 84 (Answer) / 126
44 A 9 L expandable container containing a gas is heated in an isobaric manner (constant pressure) from 17 C to 117 C. What would be the new volume at 117 C?
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12 L
Slide 85 / 126
45 A flexible balloon is dropped out a spaceship on Mars. Inside the spacecraft, the balloon has a pressure of 0.6 atm, a temperature of 20 C, and a volume of 18 L. What would be the new volume of the balloon if the pressure on Mars was 0.08 atm and the temperature was -30 C?
Slide 85 (Answer) / 126
45 A flexible balloon is dropped out a spaceship on Mars. Inside the spacecraft, the balloon has a pressure of 0.6 atm, a temperature of 20 C, and a volume of 18 L. What would be the new volume of the balloon if the pressure on Mars was 0.08 atm and the temperature was -30 C?
[This object is a pull tab]
Ans
wer
112 L
Slide 86 / 126
46 Density is defined as the mass of a substance per a given volume (D = m/V). Which of the following statements must be TRUE of the density of a gas?
A Density is proportional to volume
B Density is inversely proportional to the number of moles of the gas
C Density is inversely proportional to volume
D There is no relationship between density and the number of moles of the gas
Slide 86 (Answer) / 126
46 Density is defined as the mass of a substance per a given volume (D = m/V). Which of the following statements must be TRUE of the density of a gas?
A Density is proportional to volume
B Density is inversely proportional to the number of moles of the gas
C Density is inversely proportional to volume
D There is no relationship between density and the number of moles of the gas [This object is a pull tab]
Ans
wer
C
Slide 87 / 126
47 A gas is heated from 100 K to 300 K and the pressure is dropped from 100 mbar to 50 mbar. Which of the following would be TRUE regarding the density?
A The density will inrease by a factor of 3
B The density will decrease by a factor of 3
C The density will increase by a factor of 6
D The density will decrease by a factor of 6
Slide 87 (Answer) / 126
47 A gas is heated from 100 K to 300 K and the pressure is dropped from 100 mbar to 50 mbar. Which of the following would be TRUE regarding the density?
A The density will inrease by a factor of 3
B The density will decrease by a factor of 3
C The density will increase by a factor of 6
D The density will decrease by a factor of 6
[This object is a pull tab]
Ans
wer
D
Slide 88 / 126
48 A 0.5 mole sample of helium gas in an isobaric chamber is heated from 100 C to 300 C. What is the density of the gas at 300 C if the gas occupies a volume of 2 L at 100 C?
Slide 88 (Answer) / 126
48 A 0.5 mole sample of helium gas in an isobaric chamber is heated from 100 C to 300 C. What is the density of the gas at 300 C if the gas occupies a volume of 2 L at 100 C?
[This object is a pull tab]
Ans
wer
0.65 g/L
Slide 89 / 126
49 Oxygen gas has a density of 1.43 g/L @STP. Hydrogen gas has a density of 0.098 g/L @STP. To what pressure (in atm) must the hydrogen gas be raised to increase its density to be equal to that of oxygen? Assume a rigid container and isothermal compression.
Slide 89 (Answer) / 126
49 Oxygen gas has a density of 1.43 g/L @STP. Hydrogen gas has a density of 0.098 g/L @STP. To what pressure (in atm) must the hydrogen gas be raised to increase its density to be equal to that of oxygen? Assume a rigid container and isothermal compression.
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Ans
wer
14.59 atm
Slide 90 / 126
Ideal Gas Law
PV = nRT
It is critical that you pay attention to units. Recall that 760 mm Hg = 1 atm = 760 torr and K = oC + 273
The ideal gas law expresses the relationships of the pressure, volume, temperature, and mole amounts of a gas as a single equation.
= 8.314 J mol-1 K-1
= 0.08206 L atm mol-1 K-1
= 62.36 L torr mol-1 K-1
R
(gas constant)
Slide 91 / 126
50 What is the mass of a sample of argon gas @ a temperature of 15 C, a pressure of 450 mm Hg, and occupying a 120 mL container?
Slide 91 (Answer) / 126
50 What is the mass of a sample of argon gas @ a temperature of 15 C, a pressure of 450 mm Hg, and occupying a 120 mL container?
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Ans
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0.12 g
Slide 92 / 126
51 What is the volume of a 32 gram sample of O2 gas @ 0 C and 760 torr?
Slide 92 (Answer) / 126
51 What is the volume of a 32 gram sample of O2 gas @ 0 C and 760 torr?
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Ans
wer
22.4 L
Slide 93 / 126
52 At what temperature would a 87 gram sample of xenon gas be at 450 torr pressure and occupying a 2.5 L container?
Slide 93 (Answer) / 126
52 At what temperature would a 87 gram sample of xenon gas be at 450 torr pressure and occupying a 2.5 L container?
[This object is a pull tab]
Ans
wer
27 K
Slide 94 / 126
53 What is the density (in g/L) of a sample of chlorine gas @ 300 K and a pressure of 1.6 atm?
Slide 94 (Answer) / 126
53 What is the density (in g/L) of a sample of chlorine gas @ 300 K and a pressure of 1.6 atm?
[This object is a pull tab]
Ans
wer
4.54 g/L
Slide 95 / 126
54 A gas has a vapor density of 1.23 g/L @15 C and 1 atm pressure. What is the formula of the gas?
A CH4
B CCl4
C CH3Cl
D C2H6
Slide 95 (Answer) / 126
54 A gas has a vapor density of 1.23 g/L @15 C and 1 atm pressure. What is the formula of the gas?
A CH4
B CCl4
C CH3Cl
D C2H6
[This object is a pull tab]
Ans
wer
D
Slide 96 / 126
55 A 22.50 gram sample of a gas in a 2.50 L container @ -4 C exerts a pressure of 4.52 atm. Identify the gas.
A O2
B Ar
C CO2
D NH3
Slide 96 (Answer) / 126
55 A 22.50 gram sample of a gas in a 2.50 L container @ -4 C exerts a pressure of 4.52 atm. Identify the gas.
A O2
B Ar
C CO2
D NH3
[This object is a pull tab]
Ans
wer
C
Slide 97 / 126
56 Identify the gas in which a 42 gram sample occupies 33.6 L @STP.
A CO2
B CH4
C O2
D N2
Slide 97 (Answer) / 126
56 Identify the gas in which a 42 gram sample occupies 33.6 L @STP.
A CO2
B CH4
C O2
D N2
[This object is a pull tab]
Ans
wer
D
Slide 98 / 126
57 A 36 gram sample of helium gas exerts a pressure of 450 mm Hg @ 10 C. What is the molar volume of the gas at these conditions?
Slide 98 (Answer) / 126
57 A 36 gram sample of helium gas exerts a pressure of 450 mm Hg @ 10 C. What is the molar volume of the gas at these conditions?
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Ans
wer
39.2 L/mol
Slide 99 / 126
58 Oxygen gas is collected by dispensing it from a gas cylinder into a previously evacuated tube. Use the data below to find the molar volume of the gas @STP.
Mass of cylinder initially = 110.400 grams
Mass of cylinder after dispensing gas = 110.273 grams
Volume of gas dispensed @ 15 C = 100.3 mL
Pressure of gas collected @ 15 C = 763 mm Hg
Slide 99 (Answer) / 126
58 Oxygen gas is collected by dispensing it from a gas cylinder into a previously evacuated tube. Use the data below to find the molar volume of the gas @STP.
Mass of cylinder initially = 110.400 grams
Mass of cylinder after dispensing gas = 110.273 grams
Volume of gas dispensed @ 15 C = 100.3 mL
Pressure of gas collected @ 15 C = 763 mm Hg
[This object is a pull tab]
Ans
wer
23.8 L/mol
Slide 100 / 126
Law of Partial Pressures
Ptot = PA + PB + PC ....
Since moles and P are directly related it follows that:
Ntot = NA + NB + NC ....
The relationship between pressure and moles is often conveniently expressed as:
PA = NA
PTOT NTOT
If a sample contains more than one type of gas the total pressure of the gas mixture is the sum of the components' pressures.
Slide 101 / 126
59 Air is roughly 79% by mole amount nitrogen gas, 20% oxygen by mole amount, and 1% other trace gases. What is the partial pressure of oxygen gas in an air sample with a pressure of 745 torr?
Slide 101 (Answer) / 126
59 Air is roughly 79% by mole amount nitrogen gas, 20% oxygen by mole amount, and 1% other trace gases. What is the partial pressure of oxygen gas in an air sample with a pressure of 745 torr?
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Ans
wer
149 torr
Slide 102 / 126
60 A sample of butane gas (C4H10) is collected over water @ 17C. The vapor pressure of water at this temperature is 16.4 mm Hg. What is the partial pressure of butane collected if the total pressure is 762 mm Hg?
Slide 102 (Answer) / 126
60 A sample of butane gas (C4H10) is collected over water @ 17C. The vapor pressure of water at this temperature is 16.4 mm Hg. What is the partial pressure of butane collected if the total pressure is 762 mm Hg?
[This object is a pull tab]
Ans
wer
745.6 mm Hg
Slide 103 / 126
61 A sample of He, Ar, and Ne at 10 C contains 10 grams of each gas. Which of the following would be TRUE of the mixture?
A There is an equal number of moles of each gas
B Each gas would exert the same partial pressure
C Each gas would have have the same average kinetic energy
D Each gas would have equal number of molecules in the sample
Slide 103 (Answer) / 126
61 A sample of He, Ar, and Ne at 10 C contains 10 grams of each gas. Which of the following would be TRUE of the mixture?
A There is an equal number of moles of each gas
B Each gas would exert the same partial pressure
C Each gas would have have the same average kinetic energy
D Each gas would have equal number of molecules in the sample [This object is a pull tab]
Ans
wer
C
Slide 104 / 126
62 What is the partial pressure of hydrogen gas if a mixture containing 4 grams of H2, 16 grams of O2, and 17 grams of NH3 exerts a total pressure of 1.2 atm?
Slide 104 (Answer) / 126
62 What is the partial pressure of hydrogen gas if a mixture containing 4 grams of H2, 16 grams of O2, and 17 grams of NH3 exerts a total pressure of 1.2 atm?
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Ans
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0.69 atm
Slide 105 / 126
63 Examine the container below which consists of two glass flasks connected by a valve. What is the pressure of the helium gas after the valve has been opened?
valve
2 L of He @ 2atm 0.8 L of Ar @1 atm
Slide 105 (Answer) / 126
63 Examine the container below which consists of two glass flasks connected by a valve. What is the pressure of the helium gas after the valve has been opened?
valve
2 L of He @ 2atm 0.8 L of Ar @1 atm
[This object is a pull tab]
Ans
wer
1.43 atm
Slide 106 / 126
Graham's Law of Effusion
For gases at the same temperature...
KEa = KEb ----> mava2 = mbvb
2 ----> ma = vb2
mb va2
This law can be practically viewed two ways:
1. A gas that is twice as heavy will move 2(1/2) or 1.41 x slower.
2. A gas that is twice as fast must be 22 or 4x lighter.
Effusion refers to the random movement of gas molecules through a small opening. The speed of a gas is inversely proportional to the square root of the mass.
Slide 107 / 126
Graham's Law of Effusion
Example: What is the molar mass of a gas that travels at four times the speed of chlorine gas?
4 x speed = 42 x lighter = 16 x lighter
Cl2 = 70 g/mol divided by 16 = 4.3 g/mol
Example: How much faster would helium move compared to neon?
Ne is 20/4 or 5 x heavier than He so will move 5(1/2) or 2.23 x slower than He.... or He will move 2.23x faster than Ne.
Slide 108 / 126
64 A container filled with 2 moles each of Ar, Ne, and NH3 is punctured creating a small hole. Which of the following would be the correct order of the gases inside the container after 2 hours have passed?
A NNH3 > NNe > NAr
B NAr > NNH3 > NNe
C NNe > NAr > NNH3
D NAr > NNe > NNH3
Slide 108 (Answer) / 126
64 A container filled with 2 moles each of Ar, Ne, and NH3 is punctured creating a small hole. Which of the following would be the correct order of the gases inside the container after 2 hours have passed?
A NNH3 > NNe > NAr
B NAr > NNH3 > NNe
C NNe > NAr > NNH3
D NAr > NNe > NNH3
[This object is a pull tab]
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wer
D
Slide 109 / 126
65 Which of the following gases will travel at approximately 2.5x the speed of Xe?
A O2
B Ne
C H2
D SiH4
Slide 109 (Answer) / 126
65 Which of the following gases will travel at approximately 2.5x the speed of Xe?
A O2
B Ne
C H2
D SiH4
[This object is a pull tab]A
nsw
er
B
Slide 110 / 126
66 How much slower will carbon dioxide move compared to ammonia (NH3)?
Slide 110 (Answer) / 126
66 How much slower will carbon dioxide move compared to ammonia (NH3)?
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Ans
wer
1.61 x slower
Slide 111 / 126
67 Two samples of gases (oxygen and hydrogen) occupy the same amount of space at the same temperature and pressure. Which would NOT be true?
A Both gases have the same average kinetic energy
B Both gases have the same average molecular speed
C Both gas samples have the same number of molecules
D The mass of each gas sample would be different
Slide 111 (Answer) / 126
67 Two samples of gases (oxygen and hydrogen) occupy the same amount of space at the same temperature and pressure. Which would NOT be true?
A Both gases have the same average kinetic energy
B Both gases have the same average molecular speed
C Both gas samples have the same number of molecules
D The mass of each gas sample would be different[This object is a pull tab]
Ans
wer
B
Slide 112 / 126
Ideal vs. Real GasesAll gases are real and therefore do not fully conform to our assumptions of ideal gases. Real gases do occupy a very small part of their container.
Therefore the volume that we measure is too large, the gas molecules are actually taking up some of the room!
The larger the gas molecule, the more real and less ideal it behaves. For example, C3H8(g) will behave less ideal than H2(g)
Slide 113 / 126
Ideal vs. Real Gases
Real gases do experience coulombic attractions/repulsions between molecules.
These attractions and repulsions cause the molecules to take the scenic route and collide less frequently making the measured pressure less than the ideal.
The greater the inter-molecular forces, the less ideal and more real the gas will behave.
Slide 114 / 126
Ideal vs. Real Gases
At high temperatures, the gas molecules move too fast to form Coulombic attractions making them behave more ideally.
At low pressures, the volume of the container is large thereby making the molecules occupy a non-existent fraction of it making them behave more ideally.
Gases behave most ideal (less real) at high temperatures and low pressures.
Slide 115 / 126
68 Which of the following is TRUE regarding real gases?
A I only
B II only
C III only
D I and II only
E I, II, and III
I. Their measured pressure is less than an ideal gas
II. Their measured volume is higher than that of an ideal gas
III. They experience coulombic attractions/repulsions
Slide 115 (Answer) / 126
68 Which of the following is TRUE regarding real gases?
A I only
B II only
C III only
D I and II only
E I, II, and III
I. Their measured pressure is less than an ideal gas
II. Their measured volume is higher than that of an ideal gas
III. They experience coulombic attractions/repulsions
[This object is a pull tab]
Ans
wer
E
Slide 116 / 126
69 Which of the following gases would behave most ideally?
A CO2
B N2
C CH4
D He
Slide 116 (Answer) / 126
69 Which of the following gases would behave most ideally?
A CO2
B N2
C CH4
D He
[This object is a pull tab]
Ans
wer
D
Slide 117 / 126
70 Which of the following gases would behave most real?
A NH3
B CO
C CO2
D F2
Slide 117 (Answer) / 126
70 Which of the following gases would behave most real?
A NH3
B CO
C CO2
D F2
[This object is a pull tab]
Ans
wer
A
Slide 118 / 126
71 Which of the following gases and set of conditions will behave most ideally?
AB
CD
E
Gas Temperature Pressure
H2O 500 K 3 atmH2O 100 K 0.1 atmH2O 100 K 3 atmCH4 500 K 3 atmCH4 500 K 0.1 atm
Ans
wer
Slide 119 / 126
72 Which sample would have the highest number of molecules?
A B C
D All have the same number of molecules
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
Slide 119 (Answer) / 126
72 Which sample would have the highest number of molecules?
A B C
D All have the same number of molecules
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
[This object is a pull tab]
Ans
wer
B
Slide 120 / 126
73 Which sample would have the fastest moving gas molecules?
A B C
D All gas molecules will move at the same speed at this temperature
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
Slide 120 (Answer) / 126
73 Which sample would have the fastest moving gas molecules?
A B C
D All gas molecules will move at the same speed at this temperature
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
[This object is a pull tab]A
nsw
er
C
Slide 121 / 126
74 Which sample would would have the highest density?
A B C
D All would have the same density
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
Slide 121 (Answer) / 126
74 Which sample would would have the highest density?
A B C
D All would have the same density
Temp: 20 C 20 C 20 C
Gas: N2 O2 He
Pressure: 1 atm 2 atm 1 atm
Volume: 5 L 5 L 5 L
[This object is a pull tab]
Ans
wer
B
Slide 122 / 126
Intro to Solubility
Return to Tableof Contents
Slide 123 / 126
75 Students type their answers here
SolubilityIntermolecular forces play a role in solubility. Water is an excellent solvent for polar solutes such as ethanol (C2H5OH), soluble ionic salts (NaCl, K3PO4, etc), or polar gases like ammonia (NH3).
Why?
Slide 123 (Answer) / 126
75 Students type their answers here
SolubilityIntermolecular forces play a role in solubility. Water is an excellent solvent for polar solutes such as ethanol (C2H5OH), soluble ionic salts (NaCl, K3PO4, etc), or polar gases like ammonia (NH3).
Why?
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Ans
wer
Water is a polar molecular. Its hydrogen bonds are attracted to the charges on the solute, pulling apart the polar or ionic compound and dissolving it in
the water.
Slide 124 / 126
76 Students type their answers here
ApplicationFat soluble vitamins dissolve best in non-polar solvents such as bile salts released from the liver. The structure for vitamin K is below. Do you think it is a fat soluble or water soluble vitamin?
Slide 124 (Answer) / 126
76 Students type their answers here
ApplicationFat soluble vitamins dissolve best in non-polar solvents such as bile salts released from the liver. The structure for vitamin K is below. Do you think it is a fat soluble or water soluble vitamin?
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Ans
wer
Vitamin K is mostly nonpolar, so it is fat soluble
Slide 125 / 126
Molecular Polarity
Many pigments used to create color in paints are non-polar and require a non-polar solvent such as hexane (C6H14) to dissolve.
Many molecules have non-polar and polar regions and require an "amphipathic" solvent that also shares those qualities. Acetone (CH3COCH3) is an excellent choice for these applications.
Polarity influences solubility. Polar solutes are more soluble/miscible in polar solvents and non-polar solutes are more soluble in non-polar solvents.
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77 Which of the following would be LEAST soluble in benzene (C6H6)?
A C2H2
B SiH4
C I2
D CH2F2
Slide 126 (Answer) / 126
77 Which of the following would be LEAST soluble in benzene (C6H6)?
A C2H2
B SiH4
C I2
D CH2F2
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Ans
wer
D