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... Force = mass x acceleration. The law that is explained by this equation is _______. ...
... Force = mass x acceleration. The law that is explained by this equation is _______. ...
Conservation of angular momentum
... tower it takes her less than two seconds to hit the water. In flight, the diver’s angular momentum remains constant. Her angular momentum is determined by her rate of spin, her mass, and the distribution of her mass. What causes the diver to spin faster? She tucks and pulls her mass inward (increasi ...
... tower it takes her less than two seconds to hit the water. In flight, the diver’s angular momentum remains constant. Her angular momentum is determined by her rate of spin, her mass, and the distribution of her mass. What causes the diver to spin faster? She tucks and pulls her mass inward (increasi ...
File
... A 0.25 kg ball is traveling 40 m/s to the right when it is hit with a force of 3,000 N for 0.005 seconds. What is its final velocity? ...
... A 0.25 kg ball is traveling 40 m/s to the right when it is hit with a force of 3,000 N for 0.005 seconds. What is its final velocity? ...
Chapter 20 Magnetic Forces and Magnetic Fields
... Since magnets can exert force at a distance like electric charge, in analogy with the electric field surrounding a charge we can associate a magnetic field surrounding a magnet. The direction of the magnetic field at any point in space is the direction indicated by the north pole of a small compass ...
... Since magnets can exert force at a distance like electric charge, in analogy with the electric field surrounding a charge we can associate a magnetic field surrounding a magnet. The direction of the magnetic field at any point in space is the direction indicated by the north pole of a small compass ...
Angular momentum and magnetic moment
... Vectors are non invariant under Galilean and Lorentz transformation, and also non-invariant under rotation. The magnitude of a vector, however, is a scalar and is invariant under Galilean transformation, as well as rotation. ...
... Vectors are non invariant under Galilean and Lorentz transformation, and also non-invariant under rotation. The magnitude of a vector, however, is a scalar and is invariant under Galilean transformation, as well as rotation. ...
Summary of Chapters 1-3 Equations of motion for a uniformly acclerating object
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
... the gravity force pulling the mass down the ramp? As you slowly put the mass on the ramp, the ramp compresses & stretches along the ramp as gravity tries to slide the mass down the ramp. When you let go, the ramp has stretched enough to push on the mass with EXACTLY the right amount of force up the ...
Newton's theorem of revolving orbits
In classical mechanics, Newton's theorem of revolving orbits identifies the type of central force needed to multiply the angular speed of a particle by a factor k without affecting its radial motion (Figures 1 and 2). Newton applied his theorem to understanding the overall rotation of orbits (apsidal precession, Figure 3) that is observed for the Moon and planets. The term ""radial motion"" signifies the motion towards or away from the center of force, whereas the angular motion is perpendicular to the radial motion.Isaac Newton derived this theorem in Propositions 43–45 of Book I of his Philosophiæ Naturalis Principia Mathematica, first published in 1687. In Proposition 43, he showed that the added force must be a central force, one whose magnitude depends only upon the distance r between the particle and a point fixed in space (the center). In Proposition 44, he derived a formula for the force, showing that it was an inverse-cube force, one that varies as the inverse cube of r. In Proposition 45 Newton extended his theorem to arbitrary central forces by assuming that the particle moved in nearly circular orbit.As noted by astrophysicist Subrahmanyan Chandrasekhar in his 1995 commentary on Newton's Principia, this theorem remained largely unknown and undeveloped for over three centuries. Since 1997, the theorem has been studied by Donald Lynden-Bell and collaborators. Its first exact extension came in 2000 with the work of Mahomed and Vawda.