The water in a 1 liter balloon at 4 degrees Celsius weighs 9.81 Newtons on earth at sealevel.
Lifting 9.81 Newtons 170 meters requires 1667.7 Newton meters of energy.
1667.7 Newton meters = 398.589866 calories.
1 calorie will raise 1 gram of water 1 degree Celsius.
1 liter of water at 4 degrees Celsius has the mass of 1000 grams.
Upon impact, assuming that the object into which the water impacted received no energy transfer and that the water did not evaporate, and that the balloon fell absolutely frictionlessly,,,i.e., it fell in some textbook author's small twisted mind, the water would have gained 398.589866 calories / 1000 grams = 0.398589866 Celsius...rounded to 1 place (Your least precise term was 1 liter) you could expect a 0.4 Celsius temperature increase...assuming you had an instantaneously recording thermometer and that there was no chemical reaction with the substrate into which the balloon impacted and that the contracting rubber shards of the balloon did not add to the heat and that the moon was in conjunction with Venus...This is so hypothetical that it is laughable. Somebody needs a hobby.
When the temperature increases, the air inside the balloon will expand, causing the balloon to inflate. If the temperature increase is too drastic, the pressure inside the balloon can exceed its limits and cause it to burst. However, this depends on the material and durability of the balloon.
Yes, when you blow up a balloon, the air inside the balloon gets compressed, increasing its temperature slightly. This is due to the gas laws, particularly the ideal gas law, which states that an increase in pressure results in a proportional increase in temperature.
The pressure inside the balloon will increase due to the increase in temperature caused by the rubbing (which is a form of mechanical work). According to the ideal gas law, pressure is directly proportional to temperature when volume is constant.
This requires one simple equation and then a further understanding of it. PV=nRT where P is pressure, V is volume, T is temperature, n is the number of molecule, R is some constant. From this we can easily see that an increase in temperature does in fact cause an increase in volume. To see why lets think about what temperature is. Temperature is a measure of average kinetic energy. So an increase in temperature increases the average kinetic energy. An increase in average kinetic energy means that average velocity must be increased (K.E = .5(mv^2)). More velocity means that the molecules in the balloon are flying faster, and since pressure is the same, the molecules spread out more, which must increase the volume.
Heat causes more activity in the atoms inside the balloon. This causes expansion as they are bouncing around inside more than when they were cold. They need more room. The expansion causes failure in the balloon.
When the temperature is colder the particles in the balloon travel slower, making the balloon not able to increase in size it decreases.When the temperature is hot it allows the balloon to expand because the particles in the balloon are moving rapidly. in conclusion the the cold makes the balloon decrease in size and the heat allows it to expand.
When the temperature increases, the air inside the balloon will expand, causing the balloon to inflate. If the temperature increase is too drastic, the pressure inside the balloon can exceed its limits and cause it to burst. However, this depends on the material and durability of the balloon.
The volume will increase in proportion to the increase in absolute temperature.
The warm temperature inside the greenhouse can cause the air molecules inside the balloon to expand, increasing the pressure inside. This can lead to the balloon either expanding in size or potentially bursting.
When the temperature is colder the particles in the balloon travel slower, making the balloon not able to increase in size it decreases.When the temperature is hot it allows the balloon to expand because the particles in the balloon are moving rapidly. in conclusion the the cold makes the balloon decrease in size and the heat allows it to expand.
The volume will increase in proportion to the increase in absolute temperature.
Yes, when you blow up a balloon, the air inside the balloon gets compressed, increasing its temperature slightly. This is due to the gas laws, particularly the ideal gas law, which states that an increase in pressure results in a proportional increase in temperature.
The pressure inside the balloon will increase due to the increase in temperature caused by the rubbing (which is a form of mechanical work). According to the ideal gas law, pressure is directly proportional to temperature when volume is constant.
This requires one simple equation and then a further understanding of it. PV=nRT where P is pressure, V is volume, T is temperature, n is the number of molecule, R is some constant. From this we can easily see that an increase in temperature does in fact cause an increase in volume. To see why lets think about what temperature is. Temperature is a measure of average kinetic energy. So an increase in temperature increases the average kinetic energy. An increase in average kinetic energy means that average velocity must be increased (K.E = .5(mv^2)). More velocity means that the molecules in the balloon are flying faster, and since pressure is the same, the molecules spread out more, which must increase the volume.
It would increase. The balloon would expand because when temperature increases, volume increases as well.
The volume of the balloon will increase on the sunny windowsill due to the increase in temperature. This follows Charles's Law, which states that the volume of a gas is directly proportional to its temperature when pressure is constant.
Decrease the pressure of the surrounding environment. Thus, the force acting on the balloon from the outside decreases, allowing the air pressure that creates a force inside the balloon to have less of a counteracting force.