#acl snarf:read,write,delete,revert,admin FacultyGroup:read,write All:read ||<:30%>[[PiraScheme#Mechanics| Table of Mechanics Demonstration]]||<:30%>[[MEEquipmentList| List of Mechanics Equipment & Supplies]]||<:30%>[[Demonstrations|Lecture Demonstrations]]|| = Air Track Totally Inelastic Collision, 1N30.32 = '''Topic and Concept:''' Linear Momentum, [[Linear_Momentum#Collisions1D| 1N30. Collisions in One Dimension]] '''Location:''' * Floor Item: ME, South Wall {{attachment:InelasticActionShot02-400.jpg}} '''Abstract:''' A moving glider collides with a stationary one and sticks. ||<:style="width: 60%" :40%>'''Equipment'''||<:30%>'''Location'''||<:25%>'''ID Number'''|| || || || || ||2.25 m Air Track||Floor Item: ME, South Wall|| || ||Small & Large Air Track Gliders||ME, Bay A4, Shelf #4|| || ||Red Clay||Double Steel Door Bin Cabinet|| || ||Air Hose||Floor Item: ME, South Wall|| || ||[[RedWhiteGasCart|Red & White Gas Carts]]||ME, Bay B1, Shelf #2|| || '''''Important Setup Notes:''''' * This demonstration requires a supply of compressed air, permanent supplies located in rooms 2103, 2223, 2241. '''Setup and Procedure:''' 1. Place air track on lecture bench, and connect the compressed air supply from the lower white panel of the [[RedWhiteGasCart|Red & White Gas Cart]] to the track using an air hose. 1. Make sure that the gliders to be used have clay on one side and that the clay juts out a little off center (see photo). 1. Place two gliders on the track, one on an end of the track and the other roughly in the middle. 1. Turn on the air supply by opening the valve located on the lower white panel of the cart. 1. If the gliders seem to slide in one direction, this is most likely due to the track being unlevel. Adjust the set screws until this no longer occurs. It is a good idea to do this ahead of time. 1. Give the glider on the end a good push toward the glider at rest to create a collision. '''Cautions, Warnings, or Safety Concerns:''' * Make sure you are using compressed air (white panel) and NOT methane gas (red panel) which is extremely flammable! '''Discussion:''' In conservative systems, momentum is always conserved. In the lab frame, one glider is in motion and one is at rest. Thus, the total momentum of the system is P,,0,, = m,,1,, * v,,1,, where m,,1,, is the mass of the glider in motion and v,,1,, is its speed. In an inelastic collision, the two bodies stick to each other. Since P,,0,, = P,,f,, , ignoring friction and air resistance, the speed of the two cars together is lower than the initial speed of the first glider. P,,f,, = (m,,1,, + m,,2,,) * v,,1+2,,. ||{{attachment:InelasticGliders-02-250.jpg}}||{{attachment:InelasticLongGliders-03-250.jpg}}||{{attachment:InelasticShortGliders-04-250.jpg}}||{{attachment:AirTrackWithGliders-250.jpg}}|| ||{{attachment:InelasticActionShot01-250.jpg}}||{{attachment:InelasticActionShot03-250.jpg}}||{{attachment:InelasticActionShot04-250.jpg}}||{{attachment:InelasticActionShot05-250.jpg}}|| ||{{attachment:AirHose03-250.jpg}}||{{attachment:AirHose02-250.jpg}}||{{attachment:AirHose01-250.jpg}}|| '''Videos:''' * [[https://www.youtube.com/user/LectureDemostrations/videos?view=1|Lecture Demonstration's Youtube Channel]] '''References:''' * [[http://hyperphysics.phy-astr.gsu.edu/hbase/elacol.html|Elastic & Inelastic Collisions - Hyperphysics]] * [[https://en.wikipedia.org/wiki/Inelastic_collision|Inelastic Collisions - Wikipedia]] [[Instructional|Home]]