5. A 5.0-kg glider and a 2.0-kg glider move together to the right at 4 m/s on a frictionless horizontal rail. A spring-loaded plunger between the two gliders suddenly releases, pushing them apart. After the plunger acts, the 5.0-kg glider is observed to be at rest. a. Find the 2.0-kg glider's final velocity (magnitude and direction). b. Is KE conserved in this "collision"? Why or why not? c. Find the impulse exerted on the 5.0-kg glider (magnitude and direction).

5. A 5.0-kg glider and a 2.0-kg glider move together to the right at 4 m/s on a frictionless horizontal rail. A spring-loaded plunger between the two gliders suddenly releases, pushing them apart. After the plunger acts, the 5.0-kg glider is observed to be at rest. a. Find the 2.0-kg glider's final velocity (magnitude and direction). b. Is KE conserved in this "collision"? Why or why not? c. Find the impulse exerted on the 5.0-kg glider (magnitude and direction).

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Description: ㄱontrolforeell1/s!1A>(m₂)1Zblock 2Ioption222kgWSX#3EHcmdDC5kg$om/s4RFV65⁰%afterTGBY2kgH&7->+ pos.Npl+ m₂) V₁ = M₁ V₁ fM₁ V₁ + M₂ V2 fidenticaUdonol MinJ* CO85. A 5.0-kg glider and a 2.0-kg glider move together to the right at 4 m/s on a frictionless

University Physics Volume 2

18th Edition

ISBN:9781938168161

Author:OpenStax

Publisher:OpenStax

Chapter2: The Kinetic Theory Of Gases

Section: Chapter Questions

Problem 81AP: One process for decaffeinating coffee uses carbon dioxide ( M=44.0 g/mol) at a molar density of...

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