 
									
								
									CHAPTER 7: The Hydrogen Atom
									
... The radial equation is called the associated Laguerre equation and the solutions R are called associated Laguerre functions. There are infinitely many of them, for values of n = 1, 2, 3, … Assume that the ground state has n = 1 and ℓ = 0. Let’s find this solution. The radial equation becomes: ...
                        	... The radial equation is called the associated Laguerre equation and the solutions R are called associated Laguerre functions. There are infinitely many of them, for values of n = 1, 2, 3, … Assume that the ground state has n = 1 and ℓ = 0. Let’s find this solution. The radial equation becomes: ...
									Unit 1
									
... values must change to maintain the same value of momentum – As a spinning figure skater pulls her arms inward, she changes her value of r in angular momentum. – Mass cannot increase, so her rotational speed must increase to maintain a constant angular momentum ...
                        	... values must change to maintain the same value of momentum – As a spinning figure skater pulls her arms inward, she changes her value of r in angular momentum. – Mass cannot increase, so her rotational speed must increase to maintain a constant angular momentum ...
									CHAPTER 3: The Experimental Basis of Quantum Theory
									
... So light shows wave – particle duality properties, but is neither a classical wave nor a classical particle, it’s a quantum mechanical entity, Light is a stream of “mass less” particles, which are allowed by special relativity, that possess total energy E = h f, which is all kinetic, rushing around ...
                        	... So light shows wave – particle duality properties, but is neither a classical wave nor a classical particle, it’s a quantum mechanical entity, Light is a stream of “mass less” particles, which are allowed by special relativity, that possess total energy E = h f, which is all kinetic, rushing around ...
									Charged Particle in an Electromagnetic Field
									
... P~ (although there is a subtlety concerning the meaning of momentum, to be mentioned later). To describe the electromagnetic field we need to use the electromagnetic scalar and ~ x, t). They are related to the familiar electric and magnetic vector potentials φ(~x, t), A(~ ~ B) ~ by fields (E, ...
                        	... P~ (although there is a subtlety concerning the meaning of momentum, to be mentioned later). To describe the electromagnetic field we need to use the electromagnetic scalar and ~ x, t). They are related to the familiar electric and magnetic vector potentials φ(~x, t), A(~ ~ B) ~ by fields (E, ...
									Problem set for the lecture Particle Detectors, WS 2015/16 Prof. Dr
									
... The main program provided describes a detector consisting of 30 layers of plastic scintillator, each with a width of 5 mm, and the option to insert lead absorber layers in between the scintillators. A ”particle gun” can shoot a single particle with a fixed energy into the detector, by default an ele ...
                        	... The main program provided describes a detector consisting of 30 layers of plastic scintillator, each with a width of 5 mm, and the option to insert lead absorber layers in between the scintillators. A ”particle gun” can shoot a single particle with a fixed energy into the detector, by default an ele ...
									Physics Oral Exam Questions: What are some elements of good
									
... elastic or perfectly inelastic. a. Key terms: momentum, impulse, impulse momentum change theorem, conservation of momentum, force, vector, free body diagram, etc. b. M1V1+M2V2(pre-collision)= M1V1+M2V2(post-collision) 5. Analyze the energy transfer of a pendulum, falling body, or roller coaster. a. ...
                        	... elastic or perfectly inelastic. a. Key terms: momentum, impulse, impulse momentum change theorem, conservation of momentum, force, vector, free body diagram, etc. b. M1V1+M2V2(pre-collision)= M1V1+M2V2(post-collision) 5. Analyze the energy transfer of a pendulum, falling body, or roller coaster. a. ...
									5.11 Harmonic Oscillator
									
... regions. For example, a pendulum oscillating with an amplitude A cannot have a displacement greater than A. Could there be a nonzero probability of finding the system in "forbidden" regions. I wonder what that means for our ...
                        	... regions. For example, a pendulum oscillating with an amplitude A cannot have a displacement greater than A. Could there be a nonzero probability of finding the system in "forbidden" regions. I wonder what that means for our ...
									EOC_chapter28
									
... radiation, the subject with which quantum mechanics began. For a very simple model, consider a solid iron sphere 2.00 cm in radius. Assume that its temperature is always uniform throughout its volume. (a) Find the mass of the sphere. (b) Assume that it is at 20°C and has emissivity 0.860. Find the p ...
                        	... radiation, the subject with which quantum mechanics began. For a very simple model, consider a solid iron sphere 2.00 cm in radius. Assume that its temperature is always uniform throughout its volume. (a) Find the mass of the sphere. (b) Assume that it is at 20°C and has emissivity 0.860. Find the p ...
									IB Phys..
									
... potential difference across it causing it to heat up. – 2. The hot gas emits light energy only at certain well-defined frequencies, as seen through a diffraction grating (spectroscope) or prism. ...
                        	... potential difference across it causing it to heat up. – 2. The hot gas emits light energy only at certain well-defined frequencies, as seen through a diffraction grating (spectroscope) or prism. ...
									Physics 43 Ch 42 HW# Key
									
... The energy difference between these two states is equal to the energy that is absorbed. ...
                        	... The energy difference between these two states is equal to the energy that is absorbed. ...
									PPT
									
... Assume a spherical wave. At a distance of 1km from the antenna, find the amplitude of the electric and magnetic field strengths, and the energy incident normally on a square plate of side 10cm in 5 minutes. ...
                        	... Assume a spherical wave. At a distance of 1km from the antenna, find the amplitude of the electric and magnetic field strengths, and the energy incident normally on a square plate of side 10cm in 5 minutes. ...
 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									 
									