Identify questions to investigate arising from practical problems and issues involving floating, sinking, and buoyancy (e.g., “What factors affect the amount of cargo a barge can hold?”, “Why do some objects float and some objects sink?”, and “How can a ship made of steel float in the ocean?”).

Examine contributions of people from various cultures to understanding the principles of buoyancy, including Archimedes Principle, and the development of watercraft such as canoes and kayaks.

Explain the concept of force and provide examples of different types of contact and non-contact forces.

Illustrate, using force diagrams, the movement of objects in fluids in terms of balanced and unbalanced forces acting on the objects.

Use a spring scale to determine the relationship between mass and weight for various substances.

Express the quantitative relationship between pressure, force, and area in fluids.

Conduct a fair test to identify which factors determine whether a given object will float or sink, and discuss reasons why scientists control some variables when conducting a fair test.

Use a technological problem-solving process to design, construct, and evaluate a prototype of an object that floats and can carry the greatest amount of cargo.

Explain how buoyancy is controlled in nature (e.g., fish, humans, and sharks) and in constructed devices (e.g., submarines, airplanes, airships, scuba gear, and hot air balloons).

Compare different fluids to determine how they alter the buoyant force on a given object.

Explain the operation of technologies whose development is based on scientific understanding of the properties of fluids (e.g., personal flotation devices, float planes, surfboards, gliders, anti-freeze tester, and heart pumps).

Analyze designs of traditional and contemporary watercraft (e.g., canoe, kayak, lake boat, catamaran, and jet-ski) with respect to the principles of buoyancy.