This resource provides alternate or additional learning opportunities for students learning the three Newton's Laws of Motion. It includes a collection of interactive materilas, videos, and other digital media. Physics TEKS, (4)(D)

This resource, aligned with Chemistry TEKS (5)(C), provides alternative or additional tier-one learning options for students using the periodic table to identify and explain trends.

This is a tier I instructional resource to provide a scaffolded learning experience for TEKS (5)(6)(C).

This resource provides instructional resources for Newton's First Law, the law of inertia.

This resource is to support TEKS (8)(6)(C), specifically the Newton's third law or the law of action-reaction.

Given schematic diagrams, illustrations or descriptions, students will identify the relationship of electric and magnetic fields in applications such as generators, motors, and transformers.

Given diagrams, illustrations, scenarios, or relevant data, students will calculate the power of a physical system.

Given diagrams, illustrations or relevant data, students will identify examples of kinetic and potential energy and their transformations.

Using diagrams, illustrations, and relevant data, students will calculate the net work done on an object, the change in an object's velocity, and the change in an object's kinetic energy.

Given descriptions, diagrams, scenarios, or chemical symbols, students will model covalent bonds using electron dot formula (Lewis structures).

This resource provides alternative or additional tier-one learning options for students learning about heat transfer, Chemistry TEKS (11)(B).

This resource supports Chemistry TEKS (11)(A).

This resources allows students to explore the postulates of the Kinetic Molecular Theory in order to better understand why gas particles behave the way that they do.  

In this video, we explore the difference between distance traveled (an example of a scalar) and displacement (an example of a vector), and we review some basic vector math.

In this video, we explore the difference between speed and velocity, and their relationship to distance and displacement.

In this video, we introduce the three primary kinematics equations and apply them to one-dimensional problems. The term "acceleration" is also introduced.

In this video, we analyze hypothetical experiments by graphing position, velocity, and acceleration versus time, qualitatively.

In this video, we apply the three primary kinematic equations to projectile motion problems.

In this video, the inherent (classical) relativity of velocity measurements is explored, qualitatively and quantitatively, in both one and two dimensions.

In this video, we will study the wave-like properties of light.