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Chapter 11: Problem 9

List the three states of matter in order of (a) increasing molecular disorder and (b) increasing intermolecular attraction. (c) Which state of matter is most easily compressed?

Short Answer

Expert verified
(a) The order based on increasing molecular disorder is: solid, liquid, gas. (b) The order based on increasing intermolecular attraction is: gas, liquid, solid. (c) The gas state is the most easily compressed state of matter.

Step by step solution

01

(a) Increasing molecular disorder

To list the states of matter in order of increasing molecular disorder, think about the arrangement of molecules in each state: 1. Solid state: Molecules are arranged in a well-ordered and fixed pattern, with low molecular disorder. 2. Liquid state: Molecules are less ordered than in the solid state but more ordered than in the gaseous state, with moderate molecular disorder. 3. Gas state: Molecules are randomly arranged and have no fixed pattern, with high molecular disorder. So, the order based on increasing molecular disorder is: solid, liquid, gas.
02

(b) Increasing intermolecular attraction

To list the states of matter in order of increasing intermolecular attraction, consider the forces between molecules in each state: 1. Gas state: Molecules are far apart, with minimal intermolecular attraction. 2. Liquid state: Molecules are closer together than in the gas state, with moderate intermolecular attraction. 3. Solid state: Molecules are tightly packed in a fixed pattern, with strong intermolecular attraction. So, the order based on increasing intermolecular attraction is: gas, liquid, solid.
03

(c) Most easily compressed state of matter

The most easily compressed state of matter would be one in which molecules are far apart and have the least intermolecular attraction, allowing them to be pushed closer together more easily. Based on this criterion, the gas state is the most easily compressed state of matter.

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Molecular Disorder and States of Matter
In understanding molecular disorder, let's first imagine how molecules are organized in each state of matter.
In a solid state, molecules are arranged in a specific, fixed pattern almost like a tightly packed army. They have very little room to move around, resulting in low molecular disorder.
On the other hand, in the liquid state, molecules enjoy a bit more freedom. They are still close to each other but not as arranged as in solids, making them more disorderly. Think of a jigsaw puzzle that's been shifted just enough for the pieces not to fit perfectly anymore.
Then, there are gases. Here, molecules are like chaotic party guests, bouncing around with no specific path or arrangement. This randomness gives gases high molecular disorder.
So, to sum it up:
  • Solids come first with the least molecular disorder.
  • Liquids are next, being moderately disorderly.
  • Gases top the list with the most disorder.
Intermolecular Attraction in Each State
Intermolecular attraction is about how strongly molecules pull each other. This "pull" is something like gravity, where molecules want to stick together.
In gases, molecules are spread out and barely interact. They are like distant friends who rarely keep in touch, so the attraction is minimal.
In liquids, molecules are closer, mingling but with some personal space. They are like acquaintances at a networking event, with a medium level of attraction.
For solids, this attraction is strongest. Molecules stick close together, forming a tight bond akin to family members gathered around a dinner table.
The order of increasing intermolecular attraction is:
  • Gases, with the least attraction.
  • Liquids, with moderate attraction.
  • Solids, having the highest attraction.
Compressibility of Different States
When we think about compressibility, we're asking how easily we can squash molecules closer together. The more space between molecules, the easier it is to compress them.
Gas states excel at this. Imagine trying to pack a suitcase with clothes that are just lying around; they compress easily.
In contrast, liquids are not as compressible. Picture squeezing a water balloon. It gives a little, but most of the water stays in place.
Solids are the most stubborn when it comes to compression. Think of trying to squish a rock; it barely gives any space.
So, in terms of compressibility:
  • Gases are the most compressible.
  • Liquids can be compressed to a small extent.
  • Solids are the least compressible.

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Most popular questions from this chapter

In dichloromethane, \(\mathrm{CH}_{2} \mathrm{Cl}_{2}(\mu=1.60 \mathrm{D})\), the dispersion force contribution to the intermolecular attractive forces is about five times larger than the dipole-dipole contribution. Compared to \(\mathrm{CH}_{2} \mathrm{Cl}_{2}\), would you expect the relative importance of the dipole-dipole contribution to increase or decrease (a) in dibromomethane \((\mu=1.43 \mathrm{D})\), (b) in difluoromethane \((\mu=1.93 \mathrm{D})\) ? (c) Explain.

True or false: (a) For molecules with similar molecular weights, the dispersion forces become stronger as the molecules become more polarizable. (b) For the noble gases the dispersion forces decrease while the boiling points increase as you go down the column in the periodic table. (c) In terms of the total attractive forces for a given substance, dipole- dipole interactions, when present, are always greater than dispersion forces. (d) All other factors being the same, dispersion forces between linear molecules are greater than those between molecules whose shapes are nearly spherical.

(a) When you exercise vigorously, you sweat. How does this help your body cool? (b) A flask of water is connected to a vacuum pump. A few moments after the pump is turned on, the water begins to boil. After a few minutes, the water begins to freeze. Explain why these processes occur.

(a) What atoms must a molecule contain to participate in hydrogen bonding with other molecules of the same kind? (b) Which of the following molecules can form hydrogen bonds with other molecules of the same kind: \(\mathrm{CH}_{3} \mathrm{~F}_{,} \mathrm{CH}_{3} \mathrm{NH}_{2}, \mathrm{CH}_{3} \mathrm{OH}, \mathrm{CH}_{3} \mathrm{Br} ?\)

The table shown here lists the molar heats of vaporization for several organic compounds. Use specific examples from this list to illustrate how the heat of vaporization varies with (a) molar mass, (b) molecular shape, (c) molecular polarity, (d) hydrogen-bonding interactions. Explain these comparisons in terms of the nature of the intermolecular forces at work. (You may find it helpful to draw out the structural formula for each compound.)
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