Yes, it does.
The sun causes the air inside the balloon to heat up, making the molecules move faster and spread out. As a result, the pressure inside the balloon increases, causing the balloon to shrink because the air molecules are now more densely packed.
Because as the balloon is heated, the gases on the inside of the balloon begin to expand and press out on the walls of balloon. If a balloon is refridgerated, the opposite is true: the gases on the inside of the balloon will begin to contract, causing the balloon to shrink.
As the air temperature increases, the air molecules inside the balloon also warm up and move faster, causing them to exert more pressure on the balloon walls. This can lead to the balloon expanding or even popping if the pressure becomes too great. Conversely, a decrease in air temperature will cause the air molecules to slow down, reducing the pressure and potentially causing the balloon to shrink.
Pressure inside of a balloon is created by the movement of the air molecules against the inner surface of the balloon. The more air inside the balloon, the more molecules that are hitting the same surface are, so there is more pressure.
When you leave a balloon in the freezer overnight, the air inside the balloon cools down and contracts, causing the balloon to shrink. The particles in the air inside the balloon lose kinetic energy and move more slowly, resulting in a decrease in pressure and volume inside the balloon.
When heat is applied to a balloon filled with water, the water absorbs some of the heat energy, preventing the balloon from reaching a temperature high enough to burst. The water inside the balloon also helps dissipate the heat more evenly, reducing the likelihood of a rapid increase in pressure that could cause the balloon to pop.
As temperature increases, the air molecules inside the balloon also heat up, causing them to move faster and exert more pressure on the walls of the balloon. This can cause the balloon to expand. Conversely, a decrease in temperature will cause the air molecules to slow down, resulting in a decrease in pressure and the balloon to shrink.
Yes, the pressure inside a balloon is typically slightly higher than atmospheric pressure to keep the balloon inflated. When a balloon is fully inflated, the pressure inside the balloon is balanced by the tension in the balloon's material, which allows it to maintain its shape.
Adding more air molecules to a balloon increases the number of collisions between the molecules and the balloon walls, thereby increasing the pressure inside the balloon. This increase in air pressure causes the balloon to expand until the pressure inside matches the pressure outside.
The pressure inside a balloon is determined by factors such as the amount of air or gas in the balloon, the volume of the balloon, and the temperature of the air or gas inside. As more air or gas is added to the balloon, the pressure will increase. Conversely, if air or gas is released from the balloon, the pressure will decrease.
When a balloon is inflated, the pressure inside the balloon increases. This is because as the balloon expands, the air molecules become more tightly packed together, increasing the pressure. The pressure remains higher inside the balloon until the balloon is stretched to its maximum capacity.
As you pull the rubber sheet downward, the balloon inside will be compressed and shrink in size due to the decreasing volume of the space within the rubber sheet. The air molecules inside the balloon will get more tightly packed together, causing the pressure inside the balloon to increase.