A stationary block of mass 5 kg explodes into two pieces L and R that slide across a frictionless floor. The left piece slides across the region with friction and stops, the right piece compresses a spring. Momentum is conserved during the explosion. Piece L has a mass of 2 kg and encounters a flat surface with coefficient of kinetic friction µL = 0.4 and slides to a stop in distance di = 0.5 m. Piece R slides across the frictionless surface and compresses the spring of spring constant 120 N/m. How far does piece R compress the spring? k = 120 N/m HL = 0.4

A stationary block of mass 5 kg explodes into two pieces L and R that slide across a frictionless floor. The left piece slides across the region with friction and stops, the right piece compresses a spring. Momentum is conserved during the explosion. Piece L has a mass of 2 kg and encounters a flat surface with coefficient of kinetic friction µL = 0.4 and slides to a stop in distance di = 0.5 m. Piece R slides across the frictionless surface and compresses the spring of spring constant 120 N/m. How far does piece R compress the spring? k = 120 N/m HL = 0.4

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter11: Collisions

Section: Chapter Questions

Problem 29PQ: A dart of mass m is fired at and sticks into a block of mass M that is initially at rest on a rough,...

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