It all depends on the partical
The air particles within the sealed syringe expand because the heat from the water gives it energy. And when energy is added to a substance, the particles have more energy to break away from the attractions set on by the other particles. In other words, it expands. (hope that answers it for you.) as the air particles gain heat energy ,they convert this energy into their kinectic energy which makes the particles of the air to move more faster and apart from each other hence resulting in expansion
It would look very small because subatomic particles are small.
The water may have seeped out from the syringe during use due to a loose connection or a minor puncture in the tubing. It could also be condensation from temperature changes causing moisture to form near the tip of the syringe.
A one-way valve or check valve at the entrance of the gas syringe prevents water from entering the syringe. This valve allows gas to pass through but blocks the passage of liquids like water.
because all the space in the syringe is taken up by water. If you squeeze the syringe it will break.
when you push the plunger are the air particles closer together in the syringe or in the bubble
When you pull the syringe plunger back up, the volume inside the syringe increases, causing the air pressure to decrease. As a result, the air particles inside the syringe spread out to fill the newly available space, creating a lower pressure environment.
Salt look like little cristals particles.
The air particles within the sealed syringe expand because the heat from the water gives it energy. And when energy is added to a substance, the particles have more energy to break away from the attractions set on by the other particles. In other words, it expands. (hope that answers it for you.) as the air particles gain heat energy ,they convert this energy into their kinectic energy which makes the particles of the air to move more faster and apart from each other hence resulting in expansion
A syringe demonstrates the relationship between pressure and volume. When you pull the plunger, the volume inside the syringe increases, causing the pressure to decrease. This is because the air particles inside the syringe become more spread out, resulting in lower pressure.
they look like small circles which float around
To read a tuberculin syringe you simply have to look at the calibrations on the syringe. Make sure that your eye is level to avoid taking a wrong reading as a result of parallax.
A 5 micron filter syringe will capture particles larger than 5 microns, while a 0.2 micron filter syringe will capture particles larger than 0.2 microns. The 0.2 micron filter provides greater filtration efficiency for removing smaller particles compared to the 5 micron filter.
magenta vapout
small particles on surfaces
No. The particles cannot be crushed small enough to go through the syringe needle.
It looks as if you can see small particles. It can also look foggy and dark