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| Friction arises from electromagnetic forces at the microscopic scale. It acts to oppose motion. The magnitude of static friction is F_fr ≤ μ_s*F_n = μ_s * m * g where μ_s is the coefficient of static friction, m is the mass of the block, and g is the acceleration due to gravity. The net force on the block along the table top is the tension (equal to the counterweight treating the pulley as frictionless and massless) minus the frictional force: F_net = T - F_fr = 0 until the block begins to move. Thus, the force registering on the scale is exactly the magnitude of the force of static friction. If T > F_fr, the block will move. The net force on the moving block is the tension minus the force due to kinetic friction: T - F_fr = T - μ_k * F_n = μ_k * m * g, where μ_k is the coefficient of kinetic friction. It is always the case that μ_s > μ_k . | Friction arises from topological imperfections of the two surfaces in contact; the rougher the surface, the harder it is to slide it across another surface. Fundamentally, it is thought to arise from Coulomb forces between the atoms in the material and their relative positions. It acts to oppose motion. The magnitude of static friction is F_fr ≤ μ_s*F_n = μ_s * m * g where μ_s is the coefficient of static friction, m is the mass of the block, and g is the acceleration due to gravity. The net force on the block along the table top is the tension (equal to the counterweight treating the pulley as frictionless and massless) minus the frictional force: F_net = T - F_fr = 0 until the block begins to move. Thus, the force registering on the scale is exactly the magnitude of the force of static friction. If T > F_fr, the block will move. The net force on the moving block is the tension minus the force due to kinetic friction: T - F_fr = T - μ_k * F_n = μ_k * m * g, where μ_k is the coefficient of kinetic friction. It is always the case that μ_s > μ_k . |
[:PiraScheme#Mechanics: Table of Mechanics Demonstration] |
[:MEEquipmentList: List of Mechanics Equipment & Supplies] |
[:Demonstrations:Lecture Demonstrations] |
Static vs. Kinetic Friction, 1K20.30
Topic and Concept:
Applications of Newton's Laws, [:AppNewtonsLaws#Friction: 1K20. Friction]
Location:
Cabinet: [:MechanicsCabinet:Mechanic (ME)]
Bay: [:MechanicsCabinetBayA1:(A1)]
Shelf: #1,2,3.. attachment: mainPhoto
Abstract:
A spring scale attached to a block is used to pull on the block until it begins to move. The force registering on the scale is largest just before the block begins to move demonstrating that static friction is greater than kinetic friction.
Equipment |
Location |
ID Number |
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Scale |
ME, Bay B1, Shelf #2 |
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Lead Block w/Attached String |
ME, Bay B1, Shelf #2 |
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Important Setup Notes:
- N/A
Setup and Procedure:
- Place the lead block on a table.
- Attach the scale to the block using the attached hook and the string attached to the block.
- Slowly and steadily pull the scale away from the block, and note the force that is registering just before the block begins to move.
- Maintainting the same pulling force, note the new amount of force registering on the scale.
- Noting the difference between the two forces, one can roughly determine the ratio of the two different coefficients of friction for the block used.
Cautions, Warnings, or Safety Concerns:
Wash hands after handling the lead block as lead is toxic. It enters the body through ingestion.
Discussion:
Friction arises from topological imperfections of the two surfaces in contact; the rougher the surface, the harder it is to slide it across another surface. Fundamentally, it is thought to arise from Coulomb forces between the atoms in the material and their relative positions. It acts to oppose motion. The magnitude of static friction is F_fr ≤ μ_s*F_n = μ_s * m * g where μ_s is the coefficient of static friction, m is the mass of the block, and g is the acceleration due to gravity. The net force on the block along the table top is the tension (equal to the counterweight treating the pulley as frictionless and massless) minus the frictional force: F_net = T - F_fr = 0 until the block begins to move. Thus, the force registering on the scale is exactly the magnitude of the force of static friction. If T > F_fr, the block will move. The net force on the moving block is the tension minus the force due to kinetic friction: T - F_fr = T - μ_k * F_n = μ_k * m * g, where μ_k is the coefficient of kinetic friction. It is always the case that μ_s > μ_k .
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Videos:
[https://www.youtube.com/user/LectureDemostrations/videos?view=1 Lecture Demonstration's Youtube Channel]
References:
[http://en.wikipedia.org/wiki/Friction Friction - Wikipedia]
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