when you but the bottle in hot water the balloon particles push apart and cause expansion
When the bottle is placed in hot water, the air inside the bottle will heat up and expand, creating an increase in pressure. This increased pressure will cause the balloon to inflate as the air molecules inside the bottle push against the stretched balloon. The energy transfers involve the transfer of heat energy from the hot water to the air inside the bottle, which then increases the kinetic energy of the air molecules, resulting in the inflation of the balloon.
The balloon will inflate as the air inside the bottle warms up and expands, creating higher pressure in the bottle. This pressure pushes against the balloon, causing it to stretch and inflate. The energy transfers involved include the heat energy transferred from the hot water to the air in the bottle, then to the balloon, and finally to the elastic potential energy stored in the stretched balloon.
When the bottle is placed in hot water, the air inside expands due to the increased temperature. This causes the balloon to inflate as the air pressure inside the bottle increases.
When the bottle is placed in hot water, the air inside it expands due to the increase in temperature. This expanded air flows into the balloon, causing it to inflate. The molecules of gas inside the bottle have more kinetic energy when heated, leading to increased pressure and volume, pushing the air into the balloon.
The hot water heats up the air inside the bottle, causing it to expand, forcing some of the air out of the bottle and into the balloon, causing it to inflate. The larger the bottle, the more air that will be pushed into the balloon. The air in the balloon will quickly cool and, since hot air is less dense and therefore rises, the cooler air is forced back into the bottle to be heated up. Eventually the air will be a constant temperature and the balloon will reach the limit of inflation. As the water cools, the air cools and the balloon begins to deflate.
When the bottle is placed in hot water, the air inside the bottle will heat up and expand, creating an increase in pressure. This increased pressure will cause the balloon to inflate as the air molecules inside the bottle push against the stretched balloon. The energy transfers involve the transfer of heat energy from the hot water to the air inside the bottle, which then increases the kinetic energy of the air molecules, resulting in the inflation of the balloon.
The balloon will inflate as the air inside the bottle warms up and expands, creating higher pressure in the bottle. This pressure pushes against the balloon, causing it to stretch and inflate. The energy transfers involved include the heat energy transferred from the hot water to the air in the bottle, then to the balloon, and finally to the elastic potential energy stored in the stretched balloon.
When a bottle of hot water is placed near a balloon stretched over the top, the air inside the balloon will expand due to the heat, causing the balloon to inflate. Conversely, if the hot water cools down, the air will contract and the balloon will deflate.
When the bottle is placed in hot water, the air inside expands due to the increased temperature. This causes the balloon to inflate as the air pressure inside the bottle increases.
which term describes what happens to a cold balloon when placed in a hot car
When a bottle-and-balloon system is placed in hot water, the air inside the bottle expands due to an increase in temperature. Since the bottle is sealed off from the outside, the expanding air has nowhere to go, causing the balloon to inflate as a result of the increased pressure inside the bottle.
When the bottle is placed in hot water, the air inside it expands due to the increase in temperature. This expanded air flows into the balloon, causing it to inflate. The molecules of gas inside the bottle have more kinetic energy when heated, leading to increased pressure and volume, pushing the air into the balloon.
The hot water heats up the air inside the bottle, causing it to expand, forcing some of the air out of the bottle and into the balloon, causing it to inflate. The larger the bottle, the more air that will be pushed into the balloon. The air in the balloon will quickly cool and, since hot air is less dense and therefore rises, the cooler air is forced back into the bottle to be heated up. Eventually the air will be a constant temperature and the balloon will reach the limit of inflation. As the water cools, the air cools and the balloon begins to deflate.
Air inside the bottle expands when the bottle is heated. Some of it leaves the bottle until the pressure of the heated air remaining in the bottle equals the pressure of the air in the room. The balloon is then placed over the neck of the bottle and prevents any more air from entering or leaving the bottle. The air inside the bottle cools to the temperature of the ice water. The cooler air inside the bottle takes less space (volume) than it did when hot, so it sucks the balloon inside the neck of the bottle. Air pressure inside the bottle causes the balloon to stretch and enlarge until the air pressure inside the bottle, including the air in the balloon, has the same pressure as the air in the room.
it would burn straight thorough
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When a balloon is placed in ice, the air inside it cools down and contracts, causing the balloon to deflate slightly. As the air molecules lose energy and move closer together, the volume of the balloon decreases. Once the balloon is removed from the ice and allowed to warm back up, the air inside it expands, causing the balloon to reinflate.