Microsoft Word - 12.800 Chapter 10 `06
... exhausted its kinetic energy in climbing the pressure hill between θ = π/2 and θ =0. The pressure has acted as a potential field for the fluid motion and with the conservation of this potential and kinetic energy the fluid element is just able to traverse the rim of the cylinder. Although we have a ...
... exhausted its kinetic energy in climbing the pressure hill between θ = π/2 and θ =0. The pressure has acted as a potential field for the fluid motion and with the conservation of this potential and kinetic energy the fluid element is just able to traverse the rim of the cylinder. Although we have a ...
PHYS 1443 – Section 501 Lecture #1
... What is a system that has such characteristics? A system consists of a mass and a spring When a spring is stretched from its equilibrium position by a length x, the force acting on the mass is ...
... What is a system that has such characteristics? A system consists of a mass and a spring When a spring is stretched from its equilibrium position by a length x, the force acting on the mass is ...
Semiclassical motion in a perpendicular uniform electric
... The last line is possible since w × H = wH By definition w is perpendicular to H. Thus the equation of motion can be written in a fashion such that it is the equation of motion an electron would have if only the magentic field H is present and if the band structure is given by Ē(k) = E(k) − ~k · w ...
... The last line is possible since w × H = wH By definition w is perpendicular to H. Thus the equation of motion can be written in a fashion such that it is the equation of motion an electron would have if only the magentic field H is present and if the band structure is given by Ē(k) = E(k) − ~k · w ...
Chapter 11
... through a horizontal constricted pipe Speed changes as diameter changes Can be used to measure the speed of the fluid flow Swiftly moving fluids exert less pressure than do slowly moving fluids ...
... through a horizontal constricted pipe Speed changes as diameter changes Can be used to measure the speed of the fluid flow Swiftly moving fluids exert less pressure than do slowly moving fluids ...
Springs in Series
... According to legend, the following challenge led Archimedes to the discovery of his famous principle: Hieron, king of Syracuse, was suspicious that a new crown that he had received from the royal goldsmith was not pure gold, as claimed. Archimedes was ordered to determine whether the crown was in fa ...
... According to legend, the following challenge led Archimedes to the discovery of his famous principle: Hieron, king of Syracuse, was suspicious that a new crown that he had received from the royal goldsmith was not pure gold, as claimed. Archimedes was ordered to determine whether the crown was in fa ...
MOTION OF BODIES IN FLUIDS
... fluids so we must include the forces exerted by the extremely large number of fluid molecules. In some situations the effect of these forces can be ignored, in others they play a crucial role in determining the motion. We have seen in chapter FE3 that, in the special case where a large object is at ...
... fluids so we must include the forces exerted by the extremely large number of fluid molecules. In some situations the effect of these forces can be ignored, in others they play a crucial role in determining the motion. We have seen in chapter FE3 that, in the special case where a large object is at ...
FE4
... through fluids so we must include the forces exerted by the extremely large number of fluid molecules. In some situations the effect of these forces can be ignored, in others they play a crucial role in determining the motion. We have seen in chapter FE3 that, in the special case where a large objec ...
... through fluids so we must include the forces exerted by the extremely large number of fluid molecules. In some situations the effect of these forces can be ignored, in others they play a crucial role in determining the motion. We have seen in chapter FE3 that, in the special case where a large objec ...
Physics 207: Lecture 2 Notes
... Why is this so? Why does the pressure below the surface depend only on depth if it is in equilibrium? ...
... Why is this so? Why does the pressure below the surface depend only on depth if it is in equilibrium? ...
Solids and Fluids
... • However, the stretching, squeezing, and twisting of real objects when forces are applied are often too important to ignore (causing deformations) • Stress characterizes the strength of the forces causing the deformation (force per unit area) • Strain describes the resulting deformation • When the ...
... • However, the stretching, squeezing, and twisting of real objects when forces are applied are often too important to ignore (causing deformations) • Stress characterizes the strength of the forces causing the deformation (force per unit area) • Strain describes the resulting deformation • When the ...
Lecture-20-11
... Waves of small amplitude traveling through the same medium combine, or superpose, by simple addition. If two pulses combine to give a larger pulse, this is constructive interference (left). If they combine to give a smaller pulse, this is destructive interference (right). ...
... Waves of small amplitude traveling through the same medium combine, or superpose, by simple addition. If two pulses combine to give a larger pulse, this is constructive interference (left). If they combine to give a smaller pulse, this is destructive interference (right). ...
Assignment 1
... where k and a are positive constants. (a) Sketch the potential V (x) corresponding to the Force F (x). (b) Find the equilibrium points and sketch the phase portrait of the particle. (c) Find the time period T of oscillation of the particle about an equilibrium position for any given amplitude of the ...
... where k and a are positive constants. (a) Sketch the potential V (x) corresponding to the Force F (x). (b) Find the equilibrium points and sketch the phase portrait of the particle. (c) Find the time period T of oscillation of the particle about an equilibrium position for any given amplitude of the ...
AT Physics II. Air Resistance The motion of
... where L is a characteristic length for the object moving through a fluid (say the radius or the diameter of a sphere), v its speed, ρ the density of the liquid and η its viscosity. Generally, high Reynolds number (anything much bigger than 1) means that viscosity is negligible; low Reynolds number ( ...
... where L is a characteristic length for the object moving through a fluid (say the radius or the diameter of a sphere), v its speed, ρ the density of the liquid and η its viscosity. Generally, high Reynolds number (anything much bigger than 1) means that viscosity is negligible; low Reynolds number ( ...
May 1998
... Consider a system of two particles, each of mass m, in a constant gravitational field g. Particle P1 moves without friction on the vertical circle of radius R. P2 moves without friction along the horizontal line. The two particles are connected by a perfect spring whose elastic constant is k. The sp ...
... Consider a system of two particles, each of mass m, in a constant gravitational field g. Particle P1 moves without friction on the vertical circle of radius R. P2 moves without friction along the horizontal line. The two particles are connected by a perfect spring whose elastic constant is k. The sp ...
Chapter 9
... through a horizontal constricted pipe Speed changes as diameter changes Can be used to measure the speed of the fluid flow Swiftly moving fluids exert less pressure than do slowly moving fluids ...
... through a horizontal constricted pipe Speed changes as diameter changes Can be used to measure the speed of the fluid flow Swiftly moving fluids exert less pressure than do slowly moving fluids ...
Phy_103_-3
... the fluid. For example, a large rock at the bottom of a stream would be easily lifted compare to lifting it from the ground. As the rock breaks through the surface of the water, it becomes heavier. This phenomenon is as a result of upward force called the buoyant force (upthrust) acting on the rock ...
... the fluid. For example, a large rock at the bottom of a stream would be easily lifted compare to lifting it from the ground. As the rock breaks through the surface of the water, it becomes heavier. This phenomenon is as a result of upward force called the buoyant force (upthrust) acting on the rock ...
Chapter 3 Fluid dynamics
... where p = P1 – P2 is the difference of the pressures at the two inlets of the pipe and R = 8l/(p r04). Equation (3.15) is called Poiseuille’s law. It is similar to the Ohm’s law. So R is called flow resistance (流阻). The volume flow rate is inversely proportional to the flow resistance as we expect ...
... where p = P1 – P2 is the difference of the pressures at the two inlets of the pipe and R = 8l/(p r04). Equation (3.15) is called Poiseuille’s law. It is similar to the Ohm’s law. So R is called flow resistance (流阻). The volume flow rate is inversely proportional to the flow resistance as we expect ...
