Grade: High School - 1

PII.1.1
For a system consisting of a single object with a net external force applied, qualitatively and quantitatively predict changes in its linear momentum using the impulse-momentum theorem and in its translational kinetic energy using the work-energy theorem.

I Can Statements	Academic Vocabulary
I can use the impulse-momentum theorem to qualitatively predict changes in the linear momentum of a system consisting of a single object with a net external force applied. I can use the impulse-momentum theorem to quantitatively predict changes in the linear momentum of a system consisting of a single object with a net external force applied. I can use the work-energy theorem to qualitatively predict changes in the translational kinetic energy of a system consisting of a single object with a net external force applied. I can use the work-energy theorem to quantitatively predict changes in the translational kinetic energy of a system consisting of a single object with a net external force applied.	Energy Potential Energy Kinetic Energy Momentum Mass Velocity Force Impulse

I Can Statements

Academic Vocabulary

I can use the impulse-momentum theorem to qualitatively predict changes in the linear momentum of a system consisting of a single object with a net external force applied.

I can use the impulse-momentum theorem to quantitatively predict changes in the linear momentum of a system consisting of a single object with a net external force applied.

I can use the work-energy theorem to qualitatively predict changes in the translational kinetic energy of a system consisting of a single object with a net external force applied.

I can use the work-energy theorem to quantitatively predict changes in the translational kinetic energy of a system consisting of a single object with a net external force applied.

Energy
Potential Energy
Kinetic Energy
Momentum
Mass
Velocity
Force
Impulse

Cross Cutting Concepts
Energy and Matter

Looking Back	Looking Ahead
Operationally define “impulse” as the area under a force vs. change in clock reading (time) curve and be able to determine the change in linear momentum of a system acted on by an external force. Predict the change in linear momentum of an object from the average force exerted on the object and time interval during which the force is exerted. (PI.5.2)	For a system consisting of a two objects with no net external forces applied, qualitatively and quantitatively analyze a two dimensional interaction (i.e. collision or separation) to show that the total linear momentum of the system remains constant. (PII.1.2)

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Grade: High School - 1

PII.1.1 For a system consisting of a single object with a net external force applied, qualitatively and quantitatively predict changes in its linear momentum using the impulse-momentum theorem and in its translational kinetic energy using the work-energy theorem.

PII.1.1
For a system consisting of a single object with a net external force applied, qualitatively and quantitatively predict changes in its linear momentum using the impulse-momentum theorem and in its translational kinetic energy using the work-energy theorem.