Physics 200 Class #1 Outline
... Now with the conservation of energy too! Total energy is conserved: E = KE + PE = constant Elastic collisions, kinetic energy is conserved on it's own - things bounce. Inelastic - energy goes out of the system into the environment, or into smashing things - but momentum still stays in the system. ...
... Now with the conservation of energy too! Total energy is conserved: E = KE + PE = constant Elastic collisions, kinetic energy is conserved on it's own - things bounce. Inelastic - energy goes out of the system into the environment, or into smashing things - but momentum still stays in the system. ...
Slide 1
... Billiard ball A moving with speed va = 3.0 m/sin the +x direction strikes an equal-mass ball B initially at rest. The two balls are observed to move off at 450 to the x axis, ball A above the x axis and ball B below. What are the speeds of the two balls after colliding ? ...
... Billiard ball A moving with speed va = 3.0 m/sin the +x direction strikes an equal-mass ball B initially at rest. The two balls are observed to move off at 450 to the x axis, ball A above the x axis and ball B below. What are the speeds of the two balls after colliding ? ...
Assumed Knowledge and Skills
... Familiarity with and use of the SI unit for each quantity listed below are assumed throughout the curriculum statement. ...
... Familiarity with and use of the SI unit for each quantity listed below are assumed throughout the curriculum statement. ...
02-4-conservation-of-momentum-with
... The total momentum of a binary star system is zero. Star A has a mass of 8e30 kg. Star B has a mass of 4e30 kg. At a certain instant Star B has a velocity <0,2.4e4,0> m/s. What is the momentum and velocity of Star A? ...
... The total momentum of a binary star system is zero. Star A has a mass of 8e30 kg. Star B has a mass of 4e30 kg. At a certain instant Star B has a velocity <0,2.4e4,0> m/s. What is the momentum and velocity of Star A? ...
Atomic Structure
... The theories of atomic and molecular structure depend on quantum mechanics to describe atoms and molecules in mathematical terms. ...
... The theories of atomic and molecular structure depend on quantum mechanics to describe atoms and molecules in mathematical terms. ...
X-ray polarimetry in Xenon gas filled detectors
... including 1st order non-dipole corrections δ and γ to the dipole approximation (θ is the polar angle relative to the x-ray propagation direction, θ and φ are the polar and azimuthal angles relative to the polarization direction, β is the dipole asymmetry parameter and P2 is the 2nd Legendre polynomi ...
... including 1st order non-dipole corrections δ and γ to the dipole approximation (θ is the polar angle relative to the x-ray propagation direction, θ and φ are the polar and azimuthal angles relative to the polarization direction, β is the dipole asymmetry parameter and P2 is the 2nd Legendre polynomi ...
Rotational Inertia and Angular Momentum
... Rotational Inertia • The resistance of an object to change its state of rotation • Depends on the distribution of mass: the further the mass is from the axis of rotation, the more rotational inertia ...
... Rotational Inertia • The resistance of an object to change its state of rotation • Depends on the distribution of mass: the further the mass is from the axis of rotation, the more rotational inertia ...
PHYS2101: General Physics I
... On successful completion of the course, the student will be able to explain physical phenomena based on the general concepts and to use general principles of physics in solving problems in electricity, magnetism and thermal physics. The student will also develop skills to use experimental apparatus ...
... On successful completion of the course, the student will be able to explain physical phenomena based on the general concepts and to use general principles of physics in solving problems in electricity, magnetism and thermal physics. The student will also develop skills to use experimental apparatus ...
PPT
... As the electromagnetic wave moves rightward past the rectangle, the magnetic flux B through the rectangle changes and— according to Faraday’s law of induction— induced electric fields appear throughout the region of the rectangle. We take E and E + dE to be the induced fields along the two long side ...
... As the electromagnetic wave moves rightward past the rectangle, the magnetic flux B through the rectangle changes and— according to Faraday’s law of induction— induced electric fields appear throughout the region of the rectangle. We take E and E + dE to be the induced fields along the two long side ...
