Quantitative Analysis -Work, kinetic energy, and gravitational energyFor each of the following situations:a. Choose an initial and final state (states A and B) that will be appropriate (interesting) foranalysis.b. If there is not already a physical diagram of the situation and there should be one for properanalysis, include one.c. Construct a system schema of the situation. Do not forget to include the system boundary forthe system specified by the problem. Choose your system wisely.d. Construct an energy bar chart and system flow diagram (LOL plots) for each problem.e. You are allowed to add other energy storage modes. You do not have to use the energystorage modes that are printed in each LOL plot.f. Find the unknown value.1. A heavy, 100-kg anvil is dropped from the top of a tower that is 200 m tall. Once it reachedthe floor, it caved 10 cm into it before stopping. Calculate the average force the groundexerted on the anvil to stop it.System/FlowE, E,E, E,Position APosition BEnergy (J)Energy (J)

Name: Quantitative Analysis -Work, kinetic energy, and gravitational energy
Uploaded: 2024-03-20T06:57:57.000Z
Channel: Bartleby
Description: Quantitative Analysis -Work, kinetic energy, and gravitational energyFor each of the following situations:a. Choose an initial and final state (states A and B) that will be appropriate (interesting) foranalysis.b. If there is not already a physical

solution: Given that m = 100 kg h = 200 m d = 10 cm= 0.1 m

Science

Physics

1. A heavy, 100-kg anvil is dropped from the top of a tower that is 200 m tall. Once it reached the floor, it caved 10 cm into it before stopping. Calculate the average force the ground exerted on the anvil to stop it.

1. A heavy, 100-kg anvil is dropped from the top of a tower that is 200 m tall. Once it reached the floor, it caved 10 cm into it before stopping. Calculate the average force the ground exerted on the anvil to stop it.

University Physics Volume 3

17th Edition

ISBN:9781938168185

Author:William Moebs, Jeff Sanny

Publisher:William Moebs, Jeff Sanny

Chapter5: Relativity

Section: Chapter Questions

Problem 66P: There is approximately of energy available from fusion of hydrogen in the world's oceans. (a) If of...

See similar textbooks

Similar questions

3. DETAILS n mq MY NOTES ASK YOUR TEACHER PRACTICE ANOTHER You are working with a movie director and investigating a scene with a cowboy sliding off a tree limb and falling onto the saddle of a moving horse. The distance of the fall is several meters, and the calculation shows a high probability of injury to the cowboy from the stunt. Let's look at a simpler situation. Suppose the director asks you to have the cowboy step off a platform 2.95 m off the ground and land on his feet on the ground. The cowboy keeps his legs straight as he falls, but then bends at the knees as soon as he touches the ground. This allows the center of mass of his body to move through a distance of 0.660 m before his body comes to rest. (Center of mass will be formally defined in Linear Momentum and Collisions.) You assume this motion to be under constant acceleration of the center of mass of his body. To assess the degree of danger to the cowboy in this stunt, you wish to calculate the average force upward on…
Quantitative Analysis - Introducing Elasti For each of the following situations: a. Choose an initial and final state (states A and B) that will be appropriate (interesting) for analysis. b. If there is not already a physical diagram of the situation and there should be one for proper analysis, include one. c. Construct a system schema of the situation. Do not forget to include the system boundary for the system specified by the problem. Choose your system wisely. d. Construct an energy bar chart and system flow diagram (LOL plots) for each problem. e. You are allowed to add other energy storage modes. You do not have to use the energy storage modes that are printed in each LOL plot. f. Find the unknown value. 1. A toy car is pressed onto a small spring so that it compresses it 5 cm and is then released. The spring's stiffness constant is 400 N/m and the cart's mass is 250 g. How fast is the cart moving when it leaves the spring?
I'm trying to understand the different types of energies. I understand the definitions, but when I apply them to situations, it doesn't make much sense to me. I have the following: A. Entrophy - measure of the amt of disorder, or randomness in a system B. Kinetic Energy - Energy in Motion C. Heat - kinetic energy contained in the random motion of atoms & molecules D. Chemical Energy - type of potential energy which arises from the arrangement of atoms and be release in chemical reactions E. Conservation of Energy: Kinetic to Potential Energy - its not possible to destroy or create energy F. Conservation of Energy: Potential to Kinetic G. Potential Energy - Energy an object has because of its location or structure When I try to apply to the following, I come up with this: A: A Glass falls off the shelf & breaks B. An orange falling from a tree C. During exercise you get extremely hot. D Animals consume food (organic molecules) to make ATP to walk, breathe, etc. E. A large…
I was asked to repost this in order to get help with D and E A student of mass 40 kg dives from the 25 meter platform into the pool below. A. Determine the Ug stored in the person-Earth system when the student is at the top of the platform. B. Calculate how much K does the diver possess at impact. Calculate the diver’s velocity at impact. C. Repeat steps a and b for a 80 kg diver. Explain your results (using energy in your argument). D. If she jumped from a platform that was twice as high, how many times greater would be her velocity at impact? Explain your results (using energy). E. How much higher would the platform have to be in order for her velocity to be twice as great?
A student of mass 40 kg dives from the 25 meter platform into the pool below. A. Determine the Ug stored in the person-Earth system when the student is at the top of the platform. B. Calculate how much K does the diver possess at impact. Calculate the diver’s velocity at impact. C. Repeat steps a and b for a 80 kg diver. Explain your results (using energy in your argument). D. If she jumped from a platform that was twice as high, how many times greater would be her velocity at impact? Explain your results (using energy). E. How much higher would the platform have to be in order for her velocity to be twice as great?
Q. 3 State and explain work-energy theorem.
Question #30. Please use the attached equation sheet and start with an equation from the sheet and work from there. You can manipulate anyway you want you just have to start from the equation sheet.
ANSWER THE FOLLOWING QUESTIONS: 1. Why is it impossible for a totally isolated system to exist in nature? Explain briefly. 2. What is the sum of the kinetic and potential energy of a system? 3. The living cell exhibits thermodynamic equilibrium. True or False? Why?
The specific energy and density of gasoline is -47.3 MJ/kg and 716 kg/m3, respectively. What is its energy density? A. -0.066 m3/MJ B. -0.066 MJ/m3 C. - 33. 867 MJ/m3 D. - 33, 867 m3/MJ
I. A baseball with a mass of 0.65 kg was pitch into the air at a height of 25 meter above the ground with a velocity of 15 m/s. Determine the followinga. the baseball's kinetic energyb. the gravitational potential energy of the baseball relative to the ground. II. Solve the work done by a 600 W electric mixer in 2.3 minutes.
2.B.83 Question Help v Suppose you require 2500 food Calories per day. a. What is your average power, in watts? b. How much energy, in joules, do you require from food in a year? Counting all forms of energy (such as gasoline, electricity, and energy for heating), the average person consumes about 350 billion joules of energy each year. Compare this value to the energy needed from food alone. a. What is your average power, in watts? Approximately (Round to the nearest whole number as needed.) watts
1.) How many particles are present in a closed container if the energy it contains is 95204.74 J, and the diatomic oxygen gas is moving at a velocity of 21.45 m/s? Use only the whole number for the value of atomic mass unit. Express your answer in proper scientific notation. 2.) A car generating a power of 97010.23 watts is traveling on a road with a coefficient of kinetic friction of 0.05. If the velocity of it upon reaching its destination is 29.16 m/s and has been accelerationg at a rate of 3.45m/s^2, what is the mass of the car?