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8.24: Further Topics
https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019v2/Book%3A_Custom_Physics_textbook_for_JJC/08%3A_Work_and_Energy/8.24%3A_Further_Topics
Thermal, chemical, electric, radiant, nuclear, magnetic, elastic, sound, mechanical, luminous, and mass are forms that energy can exist in.
8.16: Collisions
https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019/Book%3A_Physics_(Boundless)/08%3A_Linear_Momentum_and_Collisions/8.16%3A_Collisions
In an inelastic collision the total kinetic energy after the collision is not equal to the total kinetic energy before the collision.
4.7: Further Applications of Newton’s Laws
https://phys.libretexts.org/Courses/Prince_Georges_Community_College/PHY_1030%3A_General_Physics_I/04%3A_The_Laws_of_Motion/4.7%3A_Further_Applications_of_Newtons_Laws
Net force affects the motion, postion and/or shape of objects (some important and commonly used forces are friction, drag and deformation).
PhET: Energy Skate Park - Basics
https://phys.libretexts.org/Learning_Objects/Visualizations_and_Simulations/PhET_Simulations/PhET%3A_Energy_Skate_Park_-_Basics
Learn about conservation of energy with a skater gal! Explore different tracks and view the kinetic energy, potential energy and friction as she moves. Build your own tracks, ramps, and jumps for the ...Learn about conservation of energy with a skater gal! Explore different tracks and view the kinetic energy, potential energy and friction as she moves. Build your own tracks, ramps, and jumps for the skater.
7.3: Kinetic Energy
https://phys.libretexts.org/Courses/Joliet_Junior_College/Physics_201_-_Fall_2019/Book%3A_Physics_(Boundless)/07%3A_Work_and_Energy/7.03%3A_Kinetic_Energy
Kinetic energy related to the forces acting on a body and was referred to as “the energy of motion.” The kinetic energy of a particle is one-half the product of the particle’s mass m and the square of...Kinetic energy related to the forces acting on a body and was referred to as “the energy of motion.” The kinetic energy of a particle is one-half the product of the particle’s mass m and the square of its speed v.
4.1: Kinetic Energy
https://phys.libretexts.org/Bookshelves/University_Physics/University_Physics_I_-_Classical_Mechanics_(Gea-Banacloche)/04%3A_Kinetic_Energy/4.01%3A_Kinetic_Energy
1 This is, of course, consistent with the principle of relativity I told you about in Chapter 2: if the process in Figure $\PageIndex{2}$ is really the same as the one in Figure $\PageIndex{1}$ , o...1 This is, of course, consistent with the principle of relativity I told you about in Chapter 2: if the process in Figure $\PageIndex{2}$ is really the same as the one in Figure $\PageIndex{1}$ , only viewed in a different inertial reference frame, then, if energy is seen to be conserved in one frame, it should also be seen to be conserved in the other.
8.6: Kinetic Energy and the Work-Energy Theorem
https://phys.libretexts.org/Courses/Coalinga_College/Physical_Science_for_Educators_(CID%3A_PHYS_14)/08%3A_Energy_Physics_and_Chemistry/8.06%3A_Kinetic_Energy_and_the_Work-Energy_Theorem
The net work $W_{net}$ is the work done by the net force acting on an object. Work done on an object transfers energy to the object. The translational kinetic energy of an object of mass $m$ movin...The net work $W_{net}$ is the work done by the net force acting on an object. Work done on an object transfers energy to the object. The translational kinetic energy of an object of mass $m$ moving at speed $v$ is $KE = \frac{1}{2}mv^2$ . The work-energy theorem states that the net work $W_{net}$ on a system changes its kinetic energy, $W_{net} = \frac{1}{2}mv^2 - \frac{1}{2}mv_0^2$ .
8.8: Relative Velocity and the Coefficient of Restitution
https://phys.libretexts.org/Courses/Gettysburg_College/Gettysburg_College_Physics_for_Physics_Majors/08%3A_C8)_Conservation_of_Energy-_Kinetic_and_Gravitational/8.08%3A_Relative_Velocity_and_the_Coefficient_of_Restitution
Visually, you should notice that the distance between the red and blue curves is the same before and after (but not during) the collision; the fact that they cross accounts for the difference in sign ...Visually, you should notice that the distance between the red and blue curves is the same before and after (but not during) the collision; the fact that they cross accounts for the difference in sign of the relative velocity, which in turns means simply that before the collision they were coming together, and afterwards they are moving apart.
7.2: Kinetic Energy and the Work-Energy Theorem
https://phys.libretexts.org/Bookshelves/College_Physics/College_Physics_1e_(OpenStax)/07%3A_Work_Energy_and_Energy_Resources/7.02%3A_Kinetic_Energy_and_the_Work-Energy_Theorem
The net work $W_{net}$ is the work done by the net force acting on an object. Work done on an object transfers energy to the object. The translational kinetic energy of an object of mass $m$ movin...The net work $W_{net}$ is the work done by the net force acting on an object. Work done on an object transfers energy to the object. The translational kinetic energy of an object of mass $m$ moving at speed $v$ is $KE = \frac{1}{2}mv^2$ . The work-energy theorem states that the net work $W_{net}$ on a system changes its kinetic energy, $W_{net} = \frac{1}{2}mv^2 - \frac{1}{2}mv_0^2$ .
8.3: Kinetic Energy
https://phys.libretexts.org/Courses/Muhlenberg_College/MC%3A_Physics_121_-_General_Physics_I/08%3A_Work_and_Kinetic_Energy/8.03%3A_Kinetic_Energy
Kinetic energy related to the forces acting on a body and was referred to as “the energy of motion.” The kinetic energy of a particle is one-half the product of the particle’s mass m and the square of...Kinetic energy related to the forces acting on a body and was referred to as “the energy of motion.” The kinetic energy of a particle is one-half the product of the particle’s mass m and the square of its speed v.
6.8: Further Topics
https://phys.libretexts.org/Bookshelves/University_Physics/Physics_(Boundless)/6%3A_Work_and_Energy/6.8%3A_Further_Topics
Thermal, chemical, electric, radiant, nuclear, magnetic, elastic, sound, mechanical, luminous, and mass are forms that energy can exist in.

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