Harmonic notes
... maximum value. This is because the velocity of the system is zero. This will occur when the displacement is equal to the amplitude. Once the mass is moving away from maximum displacement, some of the potential energy is converted to kinetic energy. The kinetic energy increases and the potential ener ...
... maximum value. This is because the velocity of the system is zero. This will occur when the displacement is equal to the amplitude. Once the mass is moving away from maximum displacement, some of the potential energy is converted to kinetic energy. The kinetic energy increases and the potential ener ...
Investigating the Conservation of Energy
... 1. Place 2 text books under the bottom of one end of the track and leave the other end resting on the lab table. Determine the mass of the cart being used in the lab. 2. Turn on the computer and start the Logger Pro program. 3. Place the motion detector to the end of the raised section of track. 4. ...
... 1. Place 2 text books under the bottom of one end of the track and leave the other end resting on the lab table. Determine the mass of the cart being used in the lab. 2. Turn on the computer and start the Logger Pro program. 3. Place the motion detector to the end of the raised section of track. 4. ...
AP1 WEP - APlusPhysics
... converted into internal energy through friction. If this were a frictionless incline, the block would accelerate as the gravitational potential energy became kinetic energy. EK: 4.C.1 The energy of a system includes its kinetic energy, potential energy, and microscopic internal energy. Examples shou ...
... converted into internal energy through friction. If this were a frictionless incline, the block would accelerate as the gravitational potential energy became kinetic energy. EK: 4.C.1 The energy of a system includes its kinetic energy, potential energy, and microscopic internal energy. Examples shou ...
EnergyandWork - University of Colorado Boulder
... “heat added plus work done equals change in energy” or Q + W = U . (Q is the symbol for heat). In this chapter we won’t consider adding heat to a system (like holding a flame under it), so Q = 0 and we have just W = U As we'll see later, energy is an extremely useful concept because energy is cons ...
... “heat added plus work done equals change in energy” or Q + W = U . (Q is the symbol for heat). In this chapter we won’t consider adding heat to a system (like holding a flame under it), so Q = 0 and we have just W = U As we'll see later, energy is an extremely useful concept because energy is cons ...
Mechanics - The University of Sydney
... Understand the concepts of impulse, average force. Apply the impulse-linear momentum theorem. Understand the difference between an elastic and inelastic collision, and apply the relevant conservation laws in each case. ...
... Understand the concepts of impulse, average force. Apply the impulse-linear momentum theorem. Understand the difference between an elastic and inelastic collision, and apply the relevant conservation laws in each case. ...
click - Uplift Education
... What is necessary to change an object’s velocity? ____________________________________ Changes in momentum are produced by the action of _______________________________________. Force applied over time _________________________ is an called an________________________. ...
... What is necessary to change an object’s velocity? ____________________________________ Changes in momentum are produced by the action of _______________________________________. Force applied over time _________________________ is an called an________________________. ...
Cp physics - Fall final review (part II)
... a. the product of the mass of the object and the time interval. b. the product of the force applied to the object and the time interval. c. the time interval divided by the net external force. d. the net external force divided by the time interval. 32. A 0.2 kg baseball is pitched with a velocity of ...
... a. the product of the mass of the object and the time interval. b. the product of the force applied to the object and the time interval. c. the time interval divided by the net external force. d. the net external force divided by the time interval. 32. A 0.2 kg baseball is pitched with a velocity of ...
Section 7.2
... If released, the force of gravity moves the block down to a position of lower energy. The term gravitational potential energy describes the energy of ...
... If released, the force of gravity moves the block down to a position of lower energy. The term gravitational potential energy describes the energy of ...
Work and Energy - University of Colorado Boulder
... “heat added plus work done equals change in energy” or Q + W = U . (Q is the symbol for heat). In this chapter we won’t consider adding heat to a system (like holding a flame under it), so Q = 0 and we have just W = U As we'll see later, energy is an extremely useful concept because energy is cons ...
... “heat added plus work done equals change in energy” or Q + W = U . (Q is the symbol for heat). In this chapter we won’t consider adding heat to a system (like holding a flame under it), so Q = 0 and we have just W = U As we'll see later, energy is an extremely useful concept because energy is cons ...
Power point 2
... frequency. This is simplified the orbitals also have different energies inside energy levels All the electrons can move around. ...
... frequency. This is simplified the orbitals also have different energies inside energy levels All the electrons can move around. ...
Morphed Gravitational Potential Energy, Nuclear Energy Levels
... of gravitation G is changed through an exponential factor. Th is exponential factor is independent of distance and it is quite small. The negligible exponential factor does not alter the law of universal gravitation for large interacting masses. For interacting masses of the order of nucleon masses ...
... of gravitation G is changed through an exponential factor. Th is exponential factor is independent of distance and it is quite small. The negligible exponential factor does not alter the law of universal gravitation for large interacting masses. For interacting masses of the order of nucleon masses ...
Chapter 7 notes physics 2
... 7.2 – The Principle of Conservation of Linear Momentum Comparing the impulse-momentum theorem to the work-energy theorem, we see that the impulse-momentum theorem states that the impulse produced by a net force is equal to the change in the object’s momentum, while the work –energy theorem states t ...
... 7.2 – The Principle of Conservation of Linear Momentum Comparing the impulse-momentum theorem to the work-energy theorem, we see that the impulse-momentum theorem states that the impulse produced by a net force is equal to the change in the object’s momentum, while the work –energy theorem states t ...
Chapter 4 – Arrangement of Electrons in Atoms
... o Scientists, like Max Planck (a German physicist), concluded that energy is found in packets or clusters, which are called ________________. o All attempts to explain “quanta” and how it affects electrons and atoms are what we consider “Quantum Mechanics.” o And thus the field of Quantum Mechanics ...
... o Scientists, like Max Planck (a German physicist), concluded that energy is found in packets or clusters, which are called ________________. o All attempts to explain “quanta” and how it affects electrons and atoms are what we consider “Quantum Mechanics.” o And thus the field of Quantum Mechanics ...
Problem Set 7 - Cabrillo College
... 6000 J (here, S stands for sprinter and G for greyhound). (b) We have PS KS / t (3500 J)/(3.0 s) 1200 W, and PG KG / t (6000 J)/(3.0 s) 2000 W. Assess: Although the greyhound has less than half the mass of the human, its final speed is twice as great. And since kinetic energy depen ...
... 6000 J (here, S stands for sprinter and G for greyhound). (b) We have PS KS / t (3500 J)/(3.0 s) 1200 W, and PG KG / t (6000 J)/(3.0 s) 2000 W. Assess: Although the greyhound has less than half the mass of the human, its final speed is twice as great. And since kinetic energy depen ...
Poisson Statistics and Gamma Ray Absorption
... Gamma rays are simply photons with very short wavelengths. Light interacts with matter primarily through interactions with the electrons. The three processes that can occur are 1. The photoelectric effect: A photon is absorbed and all of its energy is transferred to ...
... Gamma rays are simply photons with very short wavelengths. Light interacts with matter primarily through interactions with the electrons. The three processes that can occur are 1. The photoelectric effect: A photon is absorbed and all of its energy is transferred to ...
Chapter 5 Work and Friction
... Work and Friction We have been looking at systems without friction—that bounce and swing without losing energy. The energy may change from kinetic (motion) to potential (gravity and springs) and back again, but it stays the same—it’s conserved. Friction causes things to slow down, and the energy is ...
... Work and Friction We have been looking at systems without friction—that bounce and swing without losing energy. The energy may change from kinetic (motion) to potential (gravity and springs) and back again, but it stays the same—it’s conserved. Friction causes things to slow down, and the energy is ...
Physics 200 Class #1 Outline
... We discussed force, and energy... Now what about a force acting for a given length of time, independent of distance (great examples at http://www.kungfuscience.org ) Momentum Descartes and Huygens defined momentum in order to “quantify motion”. Collision problems lead to the following definition: Li ...
... We discussed force, and energy... Now what about a force acting for a given length of time, independent of distance (great examples at http://www.kungfuscience.org ) Momentum Descartes and Huygens defined momentum in order to “quantify motion”. Collision problems lead to the following definition: Li ...