A box of mass 3.0 kgkg slides down a rough vertical wall. The gravitational force on the box is 29.4 NN . When the box reaches a speed of 2.5 m/sm/s , you start pushing on one edge of the box at a 45∘∘ angle (use degrees in your calculations throughout this problem) with a constant force of magnitude FpFp = 23.0 NN , as shown in (Figure 1). There is now a frictional force between the box and the wall of magnitude 13.0 NN . How fast is the box sliding 2.8 ss after you started pushing on it?Using our simplified model, in which we know that the forces are constant (but we don't know what their magnitudes are), which, perhaps more than one, of the following motion diagrams could be a reasonable representation of the motion of the box? Learning Goal:VisualizeTo practice Problem-Solving Strategy 6.1 for Newtonianmechanics problems.A box of mass 3.0 kg slides down a rough vertical wall. Thegravitational force on the box is 29.4 N. When the box reaches aspeed of 2.5 m/s , you start pushing on one edge of the box at a45° angle (use degrees in your calculations throughout thisproblem) with a constant force of magnitude F, = 23.0 N , asPart AUsing our simplified model, in which we know that the forces are constant (but we don't know what their magnitudes are), which, perhaps more than one, of thefollowing motion diagrams could be a reasonable representation of the motion of the box?shown in (Figure 1). There is now a frictional force between thebox and the wall of magnitude 13.0 N. How fast is the box sliding2.8 s after you started pushing on it?ВCstart topushatCheck all that apply.Figure1 of 1ВSubmitRequest AnswerF,45°Part B Complete previous part(s)SolvetototoO O O O

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A box of mass 3.0 kgkg slides down a rough vertical wall. The gravitational force on the box is 29.4 NN . When the box reaches a speed of 2.5 m/sm/s , you start pushing on one edge of the box at a 45∘∘ angle (use degrees in your calculations throughout this problem) with a constant force of magnitude FpFp

Inquiry into Physics

8th Edition

ISBN:9781337515863

Author:Ostdiek

Publisher:Ostdiek

Chapter2: Newton's Laws

Section: Chapter Questions

Problem 26Q

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Hi, please show full solutions and also explain how you get the answers in physics terms so it's understandable. The correct final answers are written beside too. Thank you. A slider approaches a ramp that is sloped up at an angle of 10.0º at a velocity of 6.0 m/s. The coefficient of friction between the slider and the ramp is 0.2. How far up the ramp does the slider slide? (5.0 m)
3. Here is a problem that beautifully illustrates why we want this new approach. Problem: A mass of 3 kg is placed on a 600 that has a coefficient of 0.2. (Since the mass will be moving this is kinetic friction...) What is the resulting acceleration of the mass? The mass will then travel down the incline for 0.5 m until it reaches the bottom of the incline. How fast will the mass be traveling at the bottom of the incline? The mass will then slide across the floor (which is level). How far will it slide before coming to rest?
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