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PHYS 1443 – Section 501 Lecture #14

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1 PHYS 1443 – Section 501 Lecture #14
Wednesday, Mar. 10, 2004 Dr. Andrew Brandt Conservative and non-conservative forces General Energy Conservation Gravitational Potential Energy and Escape Speed Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

2 Announcements HW#6 on Ch. 7+part of Ch. 8 is due Weds 3/24 at midnight (note HW#7 will be due 3/29) Interim grades posted on website UTA men’s bball 2nd game tonight at 7pm (Stephen F. Austin). Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

3 Conservative Forces and Potential Energy
The work done on an object by a conservative force is equal to the decrease in the potential energy of the system What else does this statement tell you? The work done by a conservative force is equal to the negative of the change of the potential energy associated with that force. Only the changes in potential energy of a system is physically meaningful!! We can rewrite the above equation in terms of potential energy U So the potential energy associated with a conservative force at any given position becomes Potential energy function Since Ui is a constant, it only shifts the resulting Uf(x) by a constant amount. One can always change the initial potential so that Ui can be 0. What can you tell from the potential energy function above? Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

4 Conservation of Mechanical Energy
Total mechanical energy is the sum of kinetic and potential energies Let’s consider a brick of mass m at a height h from the ground What is its potential energy? m mg h What happens to the energy as the brick falls to the ground? m h1 The brick gains speed By how much? So what? The brick’s kinetic energy increased And? The lost potential energy is converted to kinetic energy The total mechanical energy of a system remains constant in any isolated system of objects that interacts only through conservative forces: Principle of mechanical energy conservation What does this mean? Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

5 Example A ball of mass m is dropped from a height h above the ground. Neglecting air resistance determine the speed of the ball when it is at a height y above the ground. PE KE Using the principle of mechanical energy conservation mg h m mgh mvi2/2 mgy mv2/2 mvf2/2 y m b) Determine the speed of the ball at y if it had initial speed vi at the time of release at the original height h. Again using the principle of mechanical energy conservation but with non-zero initial kinetic energy!!! This result look very similar to a kinematic expression, doesn’t it? Which one is it? Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

6 Example A ball of mass m is attached to a light cord of length L, making up a pendulum. The ball is released from rest when the cord makes an angle qA with the vertical, and the pivoting point P is frictionless. Find the speed of the ball when it is at the lowest point, B. Compute the potential energy at the maximum height, h. Remember where 0 is. mg m qA L T PE KE mgh h{ Using the principle of mechanical energy conservation B mv2/2 b) Determine tension T at the point B. Using Newton’s 2nd law of motion and recalling the centripetal acceleration of a circular motion Cross check the result in a simple situation. What happens when the initial angle qA is 0? Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

7 Work Done by non-conservative Forces
Mechanical energy of a system is not conserved when any one of the forces in the system is a non-conservative force. Two kinds of non-conservative forces: Applied forces: Forces that are external to the system. These forces can take away or add energy to the system. So the mechanical energy of the system is no longer conserved. If you were to carry around a ball, the force you apply to the ball is external to the system of ball and the Earth. Therefore, you add kinetic energy to the ball-Earth system. Kinetic Friction: Internal non-conservative force that causes irreversible transformation of energy. The friction force causes the kinetic and potential energy to transfer to internal energy Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

8 Example of Non-Conservative Force
A skier starts from rest at the top of a frictionless hill with vertical height 20.0m and an inclination angle of 20o. Determine how far the skier can go horizontally after he reaches the bottom of the hill if the coefficient of kinetic friction between the skis and the snow is Compute the speed at the bottom of the hill, using mechanical energy conservation on the hill before friction starts working at the bottom Don’t we need to know mass? h=20.0m q=20o The change of kinetic energy is the same as the work done by kinetic friction. Since we are interested in the distance the skier can get to before stopping, the friction must do as much work as the available kinetic energy. What does this mean in this problem? Since Well, it turns out we don’t need to know mass. What does this mean? No matter how heavy the skier is he will get as far as anyone else has gotten. Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

9 How are Conservative Forces Related to Potential Energy?
Work done by a force component on an object through a displacement Dx is For an infinitesimal displacement Dx Results in the conservative force-potential relationship This relationship says that any conservative force acting on an object within a given system is the same as the negative derivative of the potential energy of the system with respect to position. 1. spring-ball system: Does this statement make sense? 2. Earth-ball system: The relationship works in both the conservative force cases we have learned!!! Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

10 Energy Diagram and the Equilibrium of a System
One can draw potential energy as a function of position  Energy Diagram Let’s consider potential energy of a spring-ball system What shape would this diagram be? A Parabola Us What does this energy diagram tell you? Potential energy for this system is the same independent of the sign of the position. The force is 0 when the slope of the potential energy curve is 0 at the position. x=0 is a stable equilibrium of this system. Minimum Stable equilibrium -xm xm x Maximum unstable equilibrium Position of a stable equilibrium corresponds to points where potential energy is at a minimum. Position of an unstable equilibrium corresponds to points where potential energy is a maximum. Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

11 General Energy Conservation and Mass-Energy Equivalence
General Principle of Energy Conservation The total energy of an isolated system is conserved as long as all forms of energy are taken into account. Friction is a non-conservative force and causes mechanical energy to change to other forms of energy. What about friction? However, if you add the new form of energy altogether, the system as a whole did not lose any energy, as long as it is self-contained or isolated. In the grand scale of the universe, no energy can be destroyed or created but just transformed or transferred from one place to another. Total energy of universe is constant. Principle of Conservation of Mass In any physical or chemical process, mass is neither created nor destroyed. Mass before a process is identical to the mass after the process. Einstein’s Mass-Energy equality. How many joules does your body correspond to? Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

12 The Gravitational Field
The gravitational force is a field force. The force exists every where in space. If one were to place a test object of mass m at any point in space in the existence of another object of mass M, the test object will feel the gravitational force, , exerted by M. Therefore the gravitational field g is defined as In other words, the gravitational field at a point in space is the gravitational force experienced by a test particle placed at the point divided by the mass of the test particle. So how do we write the Earth’s gravitational field? Where is the unit vector pointing outward from the center of the Earth E Far away from the Earth’s surface Close to the Earth’s surface Wednesday, Mar. 10, 2004 PHYS , Spring 2004 Dr. Andrew Brandt

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