Question

The _____ point of water is at \(32^{\circ}\) on the Fahrenheit temperature scale.

Short answer

The freezing point of water is at \(32^{\circ}\) on the Fahrenheit temperature scale.

Step-by-step solution

Identify the property of water at \(\boldsymbol{32^{\circ}}\) Fahrenheit

To identify the point of water at \(32^{\circ}\) Fahrenheit, we need to know that in the Fahrenheit temperature scale, the boiling and freezing points of water are at \(212^{\circ}\)F and \(32^{\circ}\)F, respectively. Step 2:

Fill in the blank with the proper term

Since the statement is about water at \(32^{\circ}\) Fahrenheit, which is the freezing point, we will fill in the blank with the term "freezing." The completed statement: The freezing point of water is at \(32^{\circ}\) on the Fahrenheit temperature scale.

Key concepts

Fahrenheit Temperature Scale

The Fahrenheit temperature scale is a way to measure temperature, primarily used in the United States. It was developed by the German physicist Daniel Gabriel Fahrenheit in the early 18th century. On the Fahrenheit scale, the freezing point of water is at exactly 32 degrees (written as 32°F), and the boiling point is at 212°F under standard atmospheric pressure. It's important to understand that these specific values are quite different from those on the Celsius scale, where water freezes at 0°C and boils at 100°C.

Thermometers calibrated to the Fahrenheit scale can be used in various applications ranging from weather forecasting to medical diagnostics. Despite its widespread usage within the US, the Fahrenheit system is not commonly used globally, where the Celsius scale is preferred for most scientific and day-to-day temperature measurements.

Physical Properties of Water

Water is an essential compound with unique physical properties that are vital to the existence of life. Some of these key properties include its solid state (ice) being less dense than its liquid state, which is why ice floats on water. This unique characteristic is the result of the molecular structure of water and hydrogen bonding.

Additionally, water has high specific heat, meaning it can absorb a lot of heat before its temperature rises significantly. This property helps regulate Earth's climate and makes it an excellent coolant. Water also has high surface tension, cohesive and adhesive properties, and is considered a universal solvent because it can dissolve more substances than any other liquid. These physical properties contribute to the critical role water plays in the environment and within biological organisms.

States of Matter

Matter exists in different states based on the temperature and pressure conditions. The common states of matter are solid, liquid, gas, and plasma. For water, these states manifest as ice, liquid water, and water vapor.

The state of matter is determined by the arrangement and motion of its molecules. In solids, such as ice, molecules are tightly packed and only vibrate in place, giving the solid a definite shape and volume. In liquids, the molecules are less tightly packed and can move around more freely, allowing liquids to take the shape of their container but maintaining a consistent volume. In gases, like water vapor, molecules move rapidly and are spaced far apart, so a gas will expand to fill the shape and volume of its container. Understanding these states is fundamental to grasping many scientific concepts, from elementary school science projects to advanced thermodynamics.