The contact between a balloon and a sweater is softer and less likely to pop the balloon compared to the contact between a balloon and a wall, which is harder and more likely to pop the balloon. The sweater provides a cushioning effect on the balloon, while the wall does not.
Rubbing the balloon on the sweater creates a static charge imbalance on the balloon's surface, making it negatively charged. When brought close to a wall, which is usually neutrally charged, the negative charges on the balloon attract the positive charges in the wall, causing the balloon to stick due to electrostatic forces.
Rubbing the balloon on a sweater creates static electricity on its surface, giving it a positive charge. When brought close to a wall, which typically has a negative charge, the two opposite charges attract each other, causing the balloon to stick to the wall.
Rubbing a balloon on a wet sweater can transfer some of the water molecules onto the balloon. This can create a slightly charged surface on the balloon, causing it to have a higher static charge and potentially stick to other objects due to static electricity.
When you rub a balloon against your hair or a sweater, it gains a negative charge due to the transfer of electrons. The salt, being a conductor, is attracted to the balloon due to this charge, creating an electrostatic force that causes the salt to stick to the balloon.
Charged particles
The contact between a balloon and a sweater is softer and less likely to pop the balloon compared to the contact between a balloon and a wall, which is harder and more likely to pop the balloon. The sweater provides a cushioning effect on the balloon, while the wall does not.
Rubbing the balloon on the sweater creates a static charge imbalance on the balloon's surface, making it negatively charged. When brought close to a wall, which is usually neutrally charged, the negative charges on the balloon attract the positive charges in the wall, causing the balloon to stick due to electrostatic forces.
Rubbing the balloon on a sweater creates static electricity on its surface, giving it a positive charge. When brought close to a wall, which typically has a negative charge, the two opposite charges attract each other, causing the balloon to stick to the wall.
Rubbing a balloon on a wet sweater can transfer some of the water molecules onto the balloon. This can create a slightly charged surface on the balloon, causing it to have a higher static charge and potentially stick to other objects due to static electricity.
When you rub a balloon against your hair or a sweater, it gains a negative charge due to the transfer of electrons. The salt, being a conductor, is attracted to the balloon due to this charge, creating an electrostatic force that causes the salt to stick to the balloon.
Using a balloon to generate static electricity and observing it sticking to a sweater can lead to questions about the nature of static electricity, the materials involved, and the forces at play. By systematically altering variables like the type of sweater or the balloon's charge, one can conduct experiments to better understand the phenomenon, making it a scientific investigation.
The test variable in this experiment would be the type of material the objects are made of. By testing different materials like plastic, metal, and paper, you can see if the ability to stick to the wall is influenced by the material type.
Rubbing a balloon on hair or a sweater causes it to accumulate a static charge. When the charged balloon comes near the paper, it can actually induce the opposite charge on the paper, creating an attractive force between the two objects. This is known as static electricity.
When you rub a balloon against your hair or a wool sweater, the balloon becomes negatively charged by picking up electrons. The wall or surface it is brought close to may have a positive charge, which attracts the negatively charged balloon due to electrostatic forces, causing it to stick to the wall.
You can stick a stick through a balloon by first inserting the stick through an uninflated balloon, then inflating the balloon while holding the stick in place to prevent it from puncturing the balloon. This creates an illusion that the stick has been pushed through the balloon.
Some of the real life examples of static electricity are:rubbing the balloon on your hair and your hair will stick onto the balloonrubbing plastic pen or comb on a jumper & pieces of paper will stick onto itbrushing your hair & hair will stick on your skin if you have a long hairif your hair's down, & you're going to put your sweater on your hair will stick onto your sweater