Angular momentum
... I will start rotating in the opposite direction. Initial angular momentum is 0 and no external torque is applied so final angular momentum must also be 0. Bicycle wheel has angular momentum pointing down (clockwise with vertical axis upward) Something else in the system must have angular momentum po ...
... I will start rotating in the opposite direction. Initial angular momentum is 0 and no external torque is applied so final angular momentum must also be 0. Bicycle wheel has angular momentum pointing down (clockwise with vertical axis upward) Something else in the system must have angular momentum po ...
Lectures in physics Part 1: Mechanics Przemysław Borys 7.11.2013
... is insufficient! This becomes even more evident in the component notation, where on the left hand side the vector is represented by three numbers in an Euclidean space, while on the right hand side we have only one number! . The vector addition in terms of components can be easily understood. It sim ...
... is insufficient! This becomes even more evident in the component notation, where on the left hand side the vector is represented by three numbers in an Euclidean space, while on the right hand side we have only one number! . The vector addition in terms of components can be easily understood. It sim ...
Simple pendulum - Teaching Advanced Physics
... example of the Principle of Equivalence – something still not understood today and being tested by very sophisticated experiments involving astronomical measurements on the one hand and how single atoms fall due to gravity on the other. The basic puzzle is why the m in F = ma (where m is the inertia ...
... example of the Principle of Equivalence – something still not understood today and being tested by very sophisticated experiments involving astronomical measurements on the one hand and how single atoms fall due to gravity on the other. The basic puzzle is why the m in F = ma (where m is the inertia ...
Chapter 12: Electrostatic Phenomena 1. An electron situated near
... 1. An electron situated near another electron would feel A. a repulsive electrical force. B. an attractive electrical force. C. a repulsive magnetic force. D. an attractive magnetic force. E. no forces from the other electron. Answer: A 2. Consider a proton and an electron placed near one another wi ...
... 1. An electron situated near another electron would feel A. a repulsive electrical force. B. an attractive electrical force. C. a repulsive magnetic force. D. an attractive magnetic force. E. no forces from the other electron. Answer: A 2. Consider a proton and an electron placed near one another wi ...
momentum
... either the mass or velocity (or both) of an object. A second way to decrease momentum is to decrease either the mass or velocity (or both) of an object. ...
... either the mass or velocity (or both) of an object. A second way to decrease momentum is to decrease either the mass or velocity (or both) of an object. ...
simple harmonic motion and oscilation
... extended by 2.00 cm. If the mass is oscillating in vertical plane, a) Prove that the mass is in simple harmonic motion, and b) Find i) the period of the motion. ii) the frequency of its oscillation. iii) the maximum velocity of the particle iv) the maximum kinetic energy of the particle. ...
... extended by 2.00 cm. If the mass is oscillating in vertical plane, a) Prove that the mass is in simple harmonic motion, and b) Find i) the period of the motion. ii) the frequency of its oscillation. iii) the maximum velocity of the particle iv) the maximum kinetic energy of the particle. ...