Problem 52
Question
For most substances, the density of the solid phase is larger than for the liquid phase, but for water the reverse is true. What is the molecular-scale reason for this property of water? Why is this property important?
Step-by-Step Solution
Verified Answer
Water's hydrogen bonds create a less dense ice structure, allowing ice to float, which insulates aquatic life. This unique arrangement results from the 'V' molecular structure and hydrogen bonding.
1Step 1: Understanding Density
Density is defined as mass per unit volume. Typically, solids have particles more closely packed together relative to liquids, resulting in a higher density. However, unique molecular structures can alter this relationship.
2Step 2: Molecular Structure of Water
Water molecules form a 'V' shape, with one oxygen atom bonded to two hydrogen atoms. This structure allows water molecules to form hydrogen bonds with each other.
3Step 3: Hydrogen Bonding in Water
In the solid state, water molecules arrange into a crystalline structure due to hydrogen bonding. This structure, known as ice, has molecules positioned further apart than in the liquid state, decreasing density.
4Step 4: Importance of Water's Unique Density
This peculiar property allows ice to float on liquid water. This floating ice layer insulates the water beneath, protecting aquatic life from freezing entirely in cold climates.
Key Concepts
Molecular Structure of WaterHydrogen BondingCrystalline Ice Formation
Molecular Structure of Water
Water, a vital component of life, has a unique molecular structure that sets it apart from many other substances. At its core, a water molecule is composed of two hydrogen atoms and one oxygen atom. This arrangement gives water its famous 'V' shape, where the oxygen atom is at the cusp and the hydrogen atoms form the arms.
This configuration leads to an imbalance in electrical charge distribution, making water a polar molecule. The oxygen atom is more electronegative, meaning it pulls the shared electrons closer to itself. Hence, the oxygen side becomes slightly negative, while the hydrogen side is slightly positive. This polar nature is crucial for the formation of hydrogen bonds, significantly impacting water's properties.
This configuration leads to an imbalance in electrical charge distribution, making water a polar molecule. The oxygen atom is more electronegative, meaning it pulls the shared electrons closer to itself. Hence, the oxygen side becomes slightly negative, while the hydrogen side is slightly positive. This polar nature is crucial for the formation of hydrogen bonds, significantly impacting water's properties.
Hydrogen Bonding
Hydrogen bonding is a force of attraction between molecules, crucial for many of water's unusual characteristics. In water, the slightly positive hydrogen atoms of one molecule are attracted to the slightly negative oxygen atoms of another.
This type of bonding results in a strong, cohesive force keeping water molecules together. However, these bonds aren't as strong as covalent or ionic bonds, allowing for the liquid water state to exist at a wide range of temperatures.
The presence of hydrogen bonds in water results in a phenomenon known as "cohesion," which is the reason for water's high surface tension. It also gives rise to "adhesion," where water molecules can stick to other substances, explaining capillary action in plants.
This type of bonding results in a strong, cohesive force keeping water molecules together. However, these bonds aren't as strong as covalent or ionic bonds, allowing for the liquid water state to exist at a wide range of temperatures.
The presence of hydrogen bonds in water results in a phenomenon known as "cohesion," which is the reason for water's high surface tension. It also gives rise to "adhesion," where water molecules can stick to other substances, explaining capillary action in plants.
Crystalline Ice Formation
Unlike most substances, water expands upon freezing due to its crystalline ice formation. As water cools and approaches 0°C, the molecules slow down and arrange into a hexagonal lattice structure, held together by stable hydrogen bonds.
This lattice structure has more open space than the densely packed molecules in liquid water, which results in ice having a lower density than liquid water. Consequently, ice floats on water.
This floating ice is not just a curious phenomenon; it plays a critical role in preserving aquatic ecosystems. The ice layer acts as an insulating barrier, preventing whole bodies of water from freezing solid and thus allowing life to sustain through harsh winter conditions.
This lattice structure has more open space than the densely packed molecules in liquid water, which results in ice having a lower density than liquid water. Consequently, ice floats on water.
This floating ice is not just a curious phenomenon; it plays a critical role in preserving aquatic ecosystems. The ice layer acts as an insulating barrier, preventing whole bodies of water from freezing solid and thus allowing life to sustain through harsh winter conditions.
Other exercises in this chapter
Problem 50
What type of solid exhibits each of these sets of properties? (a) Melts below \(100{ }^{\circ} \mathrm{C}\) and is insoluble in water (b) Conducts electricity o
View solution Problem 51
Describe how each of these materials would behave if it were deformed by a hammer strike. Explain why the materials behave as they do. (a) A metal, such as gold
View solution Problem 53
Explain how the changes of the density of water with temperature causes "turnover" in a lake in the spring and fall. Explain why the turnover is important.
View solution Problem 54
The surface tension of a liquid decreases with increasing temperature. Using the idea of intermolecular attractions, explain why this is so.
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