In this video, we demonstrate a CubeSat table-top model to introduce students to small satellites used in modern space missions. The demo explains CubeSat structure, size standards, and how these compact satellites are launched and used for Earth observation, communication, and scientific research.
In this video, we demonstrate a Time Indicator table-top model to explain how time varies across different places on Earth. Using Earth’s rotation and reference lines, students learn how day, night, and time zones are connected.
In this video, we demonstrate a Solar System table-top model to understand the structure of our solar system. Students learn about the Sun, planets, their order, and basic motions through a simple and engaging visual demonstration.
In this video, we demonstrate Solar and Lunar Eclipses using a table-top model. Students learn how the Sun, Earth, and Moon align to cause eclipses and understand the difference between solar and lunar eclipses through a clear visual demonstration.
In this video, we demonstrate a Phases of the Moon table-top model to explain why the Moon appears to change shape. Using a simple hands-on setup, students can visualize the Sun–Earth–Moon system and understand how Moon phases occur.
In this video, we explore a Globe table-top model to understand Earth’s shape, axis, rotation, and major features. This hands-on demo helps students visualize continents, oceans, hemispheres, and how Earth rotates in space.
In this video, we demonstrate a Four Seasons table-top model to explain how Earth’s tilted axis and revolution around the Sun cause seasonal changes. This simple visual model helps students clearly understand why different seasons occur at different times of the year.
In this video, we demonstrate a Day and Night table-top model to show how Earth’s rotation causes day and night. Using a simple hands-on setup, students can clearly visualize sunlight falling on Earth and understand why different places experience day and night at different times.
In this video, we build a Foucault’s Pendulum model to demonstrate one of the most fascinating proofs of Earth’s rotation. This simple DIY experiment helps visualize how the plane of oscillation changes due to Earth rotating beneath the pendulum.
The Gravity Tower is a hands-on experiment used to demonstrate the effect of gravity on falling objects. By dropping different objects from the same height, students can observe how gravity causes all objects to accelerate downward at the same rate, regardless of their mass, when air resistance is minimal. This activity helps students understand fundamental concepts such as gravitational acceleration, free fall, and the difference between mass and weight, reinforcing key principles of classical physics through direct observation.
Newton's cradle is a device, usually made of metal, that demonstrates the principles of conservation of momentum and conservation of energy in physics with swinging spheres. When one sphere at the end is lifted and released, it strikes the stationary spheres, compressing them and thereby transmitting a pressure wave through the stationary spheres, which creates a force that pushes the last sphere upward. The last sphere swings back and strikes the stationary spheres, repeating the effect in the opposite direction. The cradle thus demonstrates conservation of momentum and energy.