A block m, rests on a surface. A second block m₂ sits on top of the first block. A horizontal force F applied to the bottom block pulls both blocks at constant velocity. Here m₁ = m₂ = m. m₂ my necessary.) (a) What is the normal force exerted by the surface on the bottom block? (Use the following as necessary: m and g as N₁ = (b) What is the normal force exerted by the bottom block on m₂? (Use the following as necessary: m and g as necessary.) N₂ = (c) How would your answers to parts (a) and (b) change if m₁ = 7m and m₂ ON₁ = 3.5mg, N₂ = 3.5mg ON₁ = 8mg, N₂ = mg ON₁ = 8mg, N₂ = 7mg ON₁ = 6mg, N₂ = 5.25mg (d) How would your answers to parts (a) and (b) change if m₁ = m and m₂ = 7m? H mg ON₁ = 8mg, N₂ ON₁ = 6mg, N₂ = 5.25mg ON₁ = 8mg, N₂ = 7mg ON₁ = = 3.5mg, N₂ 3.5mg, N₂ = 3.5mg 16 :9: esc F1 Q 2 F2 W #3 APR 28 00 20 F3 E 6000 $ 4 F4 R 45 % F5 T 16 ali MacBook Air F6 6 Y & 7 JA F7 D 8 DII

A block m, rests on a surface. A second block m₂ sits on top of the first block. A horizontal force F applied to the bottom block pulls both blocks at constant velocity. Here m₁ = m₂ = m. m₂ my necessary.) (a) What is the normal force exerted by the surface on the bottom block? (Use the following as necessary: m and g as N₁ = (b) What is the normal force exerted by the bottom block on m₂? (Use the following as necessary: m and g as necessary.) N₂ = (c) How would your answers to parts (a) and (b) change if m₁ = 7m and m₂ ON₁ = 3.5mg, N₂ = 3.5mg ON₁ = 8mg, N₂ = mg ON₁ = 8mg, N₂ = 7mg ON₁ = 6mg, N₂ = 5.25mg (d) How would your answers to parts (a) and (b) change if m₁ = m and m₂ = 7m? H mg ON₁ = 8mg, N₂ ON₁ = 6mg, N₂ = 5.25mg ON₁ = 8mg, N₂ = 7mg ON₁ = = 3.5mg, N₂ 3.5mg, N₂ = 3.5mg 16 :9: esc F1 Q 2 F2 W #3 APR 28 00 20 F3 E 6000 $ 4 F4 R 45 % F5 T 16 ali MacBook Air F6 6 Y & 7 JA F7 D 8 DII

College Physics

10th Edition

ISBN:9781285737027

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter4: The Laws Of Motion

Section4.5: Applications Of Newton's Laws

Problem 4.6QQ: For the woman being pulled forward on the toboggan in Figure 4.33, is the magnitude of the normal...

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