Linear and angular concepts
... 3. Angular displacement () 4. Linear velocity (V)= d/t 4. Angular velocity ()=/t 5. Linear acceleration (A)= V/t 5. Angular acceleration ()=/t 6. Force = mass x acceleration 6. Torque ()= force x perpendicular ...
... 3. Angular displacement () 4. Linear velocity (V)= d/t 4. Angular velocity ()=/t 5. Linear acceleration (A)= V/t 5. Angular acceleration ()=/t 6. Force = mass x acceleration 6. Torque ()= force x perpendicular ...
Quantum
... Hund's rule states that when there are several MO's with equal energy the electrons fill one MO at a time. Orbital- a specific region of an atom where there is a high likeliness that an electron will actually be s orbitals are sphere like p are dumbbell like d,f, and so on have more complicated stru ...
... Hund's rule states that when there are several MO's with equal energy the electrons fill one MO at a time. Orbital- a specific region of an atom where there is a high likeliness that an electron will actually be s orbitals are sphere like p are dumbbell like d,f, and so on have more complicated stru ...
Homework No. 01 (Fall 2013) PHYS 530B: Quantum Mechanics II
... Milton’s notes and discussion of Eq. (3.26) there.) Compare this diffraction angle with the deflection angle produced in a Stern-Gerlach experiment. 4. (Ref: Milton’s notes.) Using the notation for the probability for a measurement in the Stern-Gerlach experiment, introduced in the class, show that ...
... Milton’s notes and discussion of Eq. (3.26) there.) Compare this diffraction angle with the deflection angle produced in a Stern-Gerlach experiment. 4. (Ref: Milton’s notes.) Using the notation for the probability for a measurement in the Stern-Gerlach experiment, introduced in the class, show that ...
SPH4U: Course Outline
... Impulse-Momentum Theorem: the momentum for an object can be changed by an impulse (a force applied over time). Conservation of Momentum: the momentum of a system (e.g. 2 colliding objects) is conserved in all collisions where Fnet=0, but Ek and total mechanical energy (Ek + Eg) is conserved only in ...
... Impulse-Momentum Theorem: the momentum for an object can be changed by an impulse (a force applied over time). Conservation of Momentum: the momentum of a system (e.g. 2 colliding objects) is conserved in all collisions where Fnet=0, but Ek and total mechanical energy (Ek + Eg) is conserved only in ...
On the incompatibility of relations P=hk and ∆M=E/c2 with wave
... There are two possible approaches for calculating distribution of P0 between P1 and P2. 1. Following the law of conservation of center mass of full system (mechanical approach). 2. Following the validity of the relation P=hk for electromagnetic momentum inside the media P2 (quantum approach) ...
... There are two possible approaches for calculating distribution of P0 between P1 and P2. 1. Following the law of conservation of center mass of full system (mechanical approach). 2. Following the validity of the relation P=hk for electromagnetic momentum inside the media P2 (quantum approach) ...
The Klein-Gordon equation
... Goal: to determine the fundamental equation of motion for a field Φ(R,t) . Φ(R,t) is a scalar field for relativistic, spinless particles of nonzero mass m = meson field. To determine the fundamental equation of motion, one starts from the requirement that for the Fourier components Φ(q, ) - in the p ...
... Goal: to determine the fundamental equation of motion for a field Φ(R,t) . Φ(R,t) is a scalar field for relativistic, spinless particles of nonzero mass m = meson field. To determine the fundamental equation of motion, one starts from the requirement that for the Fourier components Φ(q, ) - in the p ...
Playing Tricks with Waves
... situation that the eigenmode equation has the “real k solution”) and “stop bands” (also called forbidden bands or band gaps, in which the eigenmode equation has no “real k solution”). ...
... situation that the eigenmode equation has the “real k solution”) and “stop bands” (also called forbidden bands or band gaps, in which the eigenmode equation has no “real k solution”). ...
The Zero-Point Field and the NASA Challenge to Create the Space
... The classical equipartition theorem states that each quadratic term in position or momentum contributes kT/2 to the mean energy (e.g. Peebles, 1992). The mean energy of each mode of the electromagnetic field is then < E >= kT. The number of modes per unit volume is (87rv2/c3)duleading to the Rayleig ...
... The classical equipartition theorem states that each quadratic term in position or momentum contributes kT/2 to the mean energy (e.g. Peebles, 1992). The mean energy of each mode of the electromagnetic field is then < E >= kT. The number of modes per unit volume is (87rv2/c3)duleading to the Rayleig ...
Electromagnetic Radiation and Polarization
... varies in magnitude in a direction perpendicular to the direction in which the radiation is traveling, and a magnetic field (M) oriented at right angles to the electrical field. Both these fields travel at the speed of light (c). ...
... varies in magnitude in a direction perpendicular to the direction in which the radiation is traveling, and a magnetic field (M) oriented at right angles to the electrical field. Both these fields travel at the speed of light (c). ...
An Electrostatic Wave
... potential V (E = −∇V ) and hence obey ∇ × E = 0. The latter condition is sometimes considered to be a requirement for electrostatic fields. Show, however, that there can exist time-dependent electric fields for which ∇ × E = 0, which have been given the name “electrostatic waves”. In particular, sho ...
... potential V (E = −∇V ) and hence obey ∇ × E = 0. The latter condition is sometimes considered to be a requirement for electrostatic fields. Show, however, that there can exist time-dependent electric fields for which ∇ × E = 0, which have been given the name “electrostatic waves”. In particular, sho ...
The Quantization of Wave Fields
... The theory of quantum mechanics presented thus far in this book has dealt with systems that, in the classical limit, consist of material particles. We wish now to extend the theory so that it can be applied to the � � � � � � � � � magnetic field and thus provide a consistent ba.9is for the quantum ...
... The theory of quantum mechanics presented thus far in this book has dealt with systems that, in the classical limit, consist of material particles. We wish now to extend the theory so that it can be applied to the � � � � � � � � � magnetic field and thus provide a consistent ba.9is for the quantum ...
Neutron Number (N = AZ) = # Neutrons
... etc. This resulted in the Wave Mechanical Model of the Atom. Electrons were not jumping from energy levels as Bohr had surmised, rather they were changing wavelength when bombarded by photons. Heisenberg: Uncertainty Principle you cannot know both the position and the momentum of a particle. You c ...
... etc. This resulted in the Wave Mechanical Model of the Atom. Electrons were not jumping from energy levels as Bohr had surmised, rather they were changing wavelength when bombarded by photons. Heisenberg: Uncertainty Principle you cannot know both the position and the momentum of a particle. You c ...
Anecdotes in the Lives of Some Prominent Physicists behind The
... this type of routine, I realized that I was teaching the concepts and theory in a “vacuum,” that is, the knowledge was being presented but without regards to who discovered it, how, why, and under what circumstances in a social context. In recent years, I have introduced new concepts and theory with ...
... this type of routine, I realized that I was teaching the concepts and theory in a “vacuum,” that is, the knowledge was being presented but without regards to who discovered it, how, why, and under what circumstances in a social context. In recent years, I have introduced new concepts and theory with ...
