Under varying conditions of pressure and temperature, most substances can exist in 3 states of matter. So we're talking about solids, liquids, or gases. Now we're going to say these forms of matter have an effect on physical properties which deal with physical appearance or state. Now with these states of matter, we have 2 terms you should familiarize yourself with. We have compressibility and viscosity. Compressibility is the capacity to flatten or reduce in size by increasing pressure. So something that's incredibly compressible can have its size decreased. Usually that is associated with gas molecules. Gas molecules spread themselves out as far as possible within a container. I can apply outward pressure on this and squeeze the gas molecules closer together. Now, viscosity. Viscosity is the resistance to flow or to change in shape. Something that is highly viscous moves very slowly, because it has a high resistance to flow. Think of honey versus water. Water can flow very easily in its liquid form. It has a low viscosity. There's not that much resistance to its flow. Honey, on the other hand, moves much more slowly, so it is more viscous. So just remember, the higher the viscosity, the higher the resistance to flow, the slower the substance will move.
- 1. Matter and Measurements4h 29m
- What is Chemistry?5m
- The Scientific Method9m
- Classification of Matter16m
- States of Matter8m
- Physical & Chemical Changes19m
- Chemical Properties8m
- Physical Properties5m
- Intensive vs. Extensive Properties13m
- Temperature (Simplified)9m
- Scientific Notation13m
- SI Units (Simplified)5m
- Metric Prefixes24m
- Significant Figures (Simplified)11m
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- Dimensional Analysis22m
- Density12m
- Specific Gravity9m
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- 2. Atoms and the Periodic Table5h 23m
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- Isotopes17m
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- Atomic Mass (Simplified)17m
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- Electromagnetic Spectrum (Simplified)11m
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- 8. Gases, Liquids and Solids3h 25m
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- Chemistry Gas Laws16m
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- 11. Nuclear Chemistry56m
- BONUS: Lab Techniques and Procedures1h 38m
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- 21. The Generation of Biochemical Energy2h 8m
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- 23. Lipids2h 26m
- Intro to Lipids6m
- Fatty Acids25m
- Physical Properties of Fatty Acids6m
- Waxes4m
- Triacylglycerols12m
- Triacylglycerol Reactions: Hydrogenation8m
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- Glycerophospholipids15m
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- Steroids15m
- Cell Membranes7m
- Membrane Transport10m
- 24. Lipid Metabolism1h 45m
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- 26. Nucleic Acids and Protein Synthesis2h 54m
- Intro to Nucleic Acids4m
- Nitrogenous Bases16m
- Nucleoside and Nucleotide Formation9m
- Naming Nucleosides and Nucleotides13m
- Phosphodiester Bond Formation7m
- Primary Structure of Nucleic Acids11m
- Base Pairing10m
- DNA Double Helix6m
- Intro to DNA Replication20m
- Steps of DNA Replication11m
- Types of RNA10m
- Overview of Protein Synthesis4m
- Transcription: mRNA Synthesis9m
- Processing of pre-mRNA5m
- The Genetic Code6m
- Introduction to Translation7m
- Translation: Protein Synthesis18m
States of Matter - Online Tutor, Practice Problems & Exam Prep
The 3 States of Matter include gases, liquids and solids.
Analyzing the States of Matter
States of Matter Concept 1
Video transcript
States of Matter Concept 2
Video transcript
So here when we take a look at the 3 states of matter, we first look at gases. Gases themselves can assume both the volume and shape of their containers. Liquids, on the other hand, can assume the shape, but not necessarily the volume of their container. Let's say your volume is a 100 ml beaker, and you only have 10 ml of your liquid. You could put all that liquid within that beaker, but there just isn't enough of it to fill up the whole beaker. There's only 10 ml of it. Solids, they maintain both their shape and their volume. When it comes to gases, gases are highly compressible, so they have a high compressibility. That means that I can put them in a container, apply pressure to that container, and cause those gas molecules to come closer and closer together. That's what we mean by highly compressible. Your molecules are far enough apart that I can apply outside pressure and bring them closer together. Here, liquids, the molecules are not right next to each other as tightly. They're moving around freely. Because of this, we're going to say that they have a moderate compressibility. I could squeeze them closer together but not by much. For solids, solids are locked in place, with each other. Here, they have a low compressibility. I can't squeeze the atoms any closer together. Next, viscosity. Viscosity, remember, is our resistance to flow; something that is viscous moves very slowly. Gases move around and jump around pretty easily inside of a container. Because of this, we'll say gases have a low viscosity. Liquids like water, water kind of moves pretty quickly but not all liquids are like water. Because of this, we're going to say liquids have more of a moderate viscosity. Solids, you take a solid you like, your calculator put on the table. It's not going to move pretty easily. You have to apply force to it to move it. That's because solids generally have a high viscosity. They have a high resistance to flow. They don't want to move unless you make them move. Right? So when we take a look at our 3 phases of matter, keep in mind their shape and volume in terms of a container, their viscosity, as well as their compressibility.
States of Matter Example 1
Video transcript
Here it states an unknown substance has a volume of 12.1 liters, and upon quadrupling the pressure, the volume remains unchanged, which helps in determining the likely physical state of the unknown. The choices are solid, liquid, gas, or neutron. Well, here, a neutron is not one of our physical states of matter, so we can eliminate that option. That means our answer is either a, b, or c. Here, they're telling us that we're quadrupling the pressure, and the volume doesn't change at all. Remember, gases are highly compressible. Thus, changing the pressure by this much would cause a significant change in the volume of the gas. Liquids are not as compressible as gases, but they would also be affected if we quadrupled the pressure. The volume would adjust slightly for liquids. So, it can't be a liquid. It would have to be a solid. Solids themselves are not compressible in terms of applying pressure to them. The volume more or less would stay the same. So here, out of all our options, option a is the correct answer.
Which of the following choices will have the lowest observed viscosity?
Nitric acid, which is used in the production of fertilizers, plastics and dyes, has a melting point of – 42ºC and a boiling point of 83ºC. Determine its physical state at a temperature of 110ºC.
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Here’s what students ask on this topic:
What are the three states of matter and their properties?
The three states of matter are solids, liquids, and gases. Solids maintain both their shape and volume, with low compressibility and high viscosity, meaning they resist flow and require force to move. Liquids take the shape but not the volume of their containers, have moderate compressibility, and moderate viscosity, allowing them to flow more easily than solids but less so than gases. Gases assume both the shape and volume of their containers, are highly compressible, and have low viscosity, meaning they flow and spread out easily within a container.
How does compressibility differ among solids, liquids, and gases?
Compressibility refers to the ability of a substance to decrease in volume under pressure. Gases are highly compressible because their molecules are far apart, allowing them to be squeezed closer together. Liquids have moderate compressibility; their molecules are closer than in gases but still have some space to be compressed. Solids have low compressibility because their molecules are tightly packed in a fixed structure, leaving little room for further compression.
What is viscosity and how does it vary among the states of matter?
Viscosity is the resistance of a substance to flow. Gases have low viscosity, meaning they flow easily and quickly. Liquids have moderate viscosity; they flow more easily than solids but less so than gases. For example, water has low viscosity compared to honey. Solids have high viscosity, meaning they resist flow and require force to move. This is because their molecules are tightly packed and do not move freely.
How do gases, liquids, and solids differ in terms of shape and volume?
Gases assume both the shape and volume of their containers, spreading out to fill the entire space. Liquids take the shape of their containers but do not fill the entire volume unless the container's volume matches the liquid's volume. Solids maintain both their shape and volume regardless of the container, as their molecules are tightly packed in a fixed structure.
Why are gases considered highly compressible compared to liquids and solids?
Gases are considered highly compressible because their molecules are spaced far apart, allowing them to be squeezed closer together under pressure. In contrast, liquids have molecules that are closer together, providing less space for compression, resulting in moderate compressibility. Solids have tightly packed molecules in a fixed structure, leaving little to no space for compression, making them the least compressible of the three states of matter.
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