(a)
Interpretation:
The type(s) of intermolecular forces existing in between the molecules of the given compounds have to be identified.
Concept Introduction:
Intermolecular forces are the forces existing between molecules, atoms, ions or dipoles.
Depending upon the type of species involved, the intermolecular forces can be classified as follows:
- Dipole-Dipole interactions.
- Ion-Dipole interactions.
- Dipole-induced dipole interactions.
- Ion-induced dipole interactions.
- Dispersion forces.
- Hydrogen bonding.
- Dipole-Dipole interaction is the interaction between two polar molecules which have net dipole moments.
- Ion-Dipole interaction is the interaction between an ionic species (such as cation or anion) and a polar molecule.
- Dipole-induced dipole is the interaction between an atom (non- polar species) and a polar molecule. In this interaction, a polar molecule induces its dipole moment to a non-polar species which lacks dipole moment.
- Ion-induced dipole interaction is the interaction between an atom (non- polar species) and an ionic species. In this interaction, an ionic species such as cation or anion, induces dipole in a non-polar species which lacks dipole moment.
- Dispersion force is the interaction between non-polar molecules.
- Hydrogen bonding can also be defined as coulombic attraction between the hydrogen atom and an electronegative atom. It is a special type of Dipole-Dipole interaction.
(b)
Interpretation:
The type(s) of intermolecular forces existing in between the molecules of the given compounds have to be identified.
Concept Introduction:
Intermolecular forces are the forces existing between molecules, atoms, ions or dipoles.
Depending upon the type of species involved, the intermolecular forces can be classified as follows:
- Dipole-Dipole interactions.
- Ion-Dipole interactions.
- Dipole-induced dipole interactions.
- Ion-induced dipole interactions.
- Dispersion forces.
- Hydrogen bonding.
- Dipole-Dipole interaction is the interaction between two polar molecules which have net dipole moments.
- Ion-Dipole interaction is the interaction between an ionic species (such as cation or anion) and a polar molecule.
- Dipole-induced dipole is the interaction between an atom (non- polar species) and a polar molecule. In this interaction, a polar molecule induces its dipole moment to a non-polar species which lacks dipole moment.
- Ion-induced dipole interaction is the interaction between an atom (non- polar species) and an ionic species. In this interaction, an ionic species such as cation or anion, induces dipole in a non-polar species which lacks dipole moment.
- Dispersion force is the interaction between non-polar molecules.
- Hydrogen bonding can also be defined as coulombic attraction between the hydrogen atom and an electronegative atom. It is a special type of Dipole-Dipole interaction.
(c)
Interpretation:
The type(s) of intermolecular forces existing in between the molecules of the given compounds have to be identified.
Concept Introduction:
Intermolecular forces are the forces existing between molecules, atoms, ions or dipoles.
Depending upon the type of species involved, the intermolecular forces can be classified as follows:
- Dipole-Dipole interactions.
- Ion-Dipole interactions.
- Dipole-induced dipole interactions.
- Ion-induced dipole interactions.
- Dispersion forces.
- Hydrogen bonding.
- Dipole-Dipole interaction is the interaction between two polar molecules which have net dipole moments.
- Ion-Dipole interaction is the interaction between an ionic species (such as cation or anion) and a polar molecule.
- Dipole-induced dipole is the interaction between an atom (non- polar species) and a polar molecule. In this interaction, a polar molecule induces its dipole moment to a non-polar species which lacks dipole moment.
- Ion-induced dipole interaction is the interaction between an atom (non- polar species) and an ionic species. In this interaction, an ionic species such as cation or anion, induces dipole in a non-polar species which lacks dipole moment.
- Dispersion force is the interaction between non-polar molecules.
- Hydrogen bonding can also be defined as coulombic attraction between the hydrogen atom and an electronegative atom. It is a special type of Dipole-Dipole interaction.

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Chapter 11 Solutions
ALEKS 360; 18WKS F/ GEN. CHEMISTRY >I<
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- Select all molecules which are chiral. Brarrow_forwardUse the reaction coordinate diagram to answer the below questions. Type your answers into the answer box for each question. (Watch your spelling) Energy A B C D Reaction coordinate E A) Is the reaction step going from D to F endothermic or exothermic? A F G B) Does point D represent a reactant, product, intermediate or transition state? A/ C) Which step (step 1 or step 2) is the rate determining step? Aarrow_forward1. Using radii from Resource section 1 (p.901) and Born-Lande equation, calculate the lattice energy for PbS, which crystallizes in the NaCl structure. Then, use the Born-Haber cycle to obtain the value of lattice energy for PbS. You will need the following data following data: AH Pb(g) = 196 kJ/mol; AHƒ PbS = −98 kJ/mol; electron affinities for S(g)→S¯(g) is -201 kJ/mol; S¯(g) (g) is 640kJ/mol. Ionization energies for Pb are listed in Resource section 2, p.903. Remember that enthalpies of formation are calculated beginning with the elements in their standard states (S8 for sulfur). The formation of S2, AHF: S2 (g) = 535 kJ/mol. Compare the two values, and explain the difference. (8 points)arrow_forward
- General Chemistry - Standalone book (MindTap Cour...ChemistryISBN:9781305580343Author:Steven D. Gammon, Ebbing, Darrell Ebbing, Steven D., Darrell; Gammon, Darrell Ebbing; Steven D. Gammon, Darrell D.; Gammon, Ebbing; Steven D. Gammon; DarrellPublisher:Cengage Learning
