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Course schedule

(Preliminary schedule -- subject to frequent adjustment.)

	Date	F&W Reading	Topic	Assignment
1	Wed, 8/29/2012	Chap. 1	Review of basic principles;Scattering theory	#1
2	Fri, 8/31/2012	Chap. 1	Scattering theory continued	#2
3	Mon, 9/03/2012	Chap. 1	Scattering theory continued	#3
4	Wed, 9/05/2012	Chap. 1 & 2	Scattering theory/Accelerated coordinate frame	#4
5	Fri, 9/07/2012	Chap. 2	Accelerated coordinate frame	#5
6	Mon, 9/10/2012	Chap. 3	Calculus of Variation	#6
7	Wed, 9/12/2012	Chap. 3	Calculus of Variation continued
8	Fri, 9/14/2012	Chap. 3	Lagrangian	#7
9	Mon, 9/17/2012	Chap. 3 & 6	Lagrangian	#8
10	Wed, 9/19/2012	Chap. 3 & 6	Lagrangian	#9
11	Fri, 9/21/2012	Chap. 3 & 6	Lagrangian	#10
12	Mon, 9/24/2012	Chap. 3 & 6	Lagrangian and Hamiltonian	#11
13	Wed, 9/26/2012	Chap. 6	Lagrangian and Hamiltonian	#12
14	Fri, 9/28/2012	Chap. 6	Lagrangian and Hamiltonian	#13
15	Mon, 10/01/2012	Chap. 4	Small oscillations	#14
16	Wed, 10/03/2012	Chap. 4	Small oscillations	#15
17	Fri, 10/05/2012	Chap. 4	Small oscillations
18	Mon, 10/08/2012	Chap. 7	Wave equation	Take Home Exam
19	Wed, 10/10/2012	Chap. 7	Wave equation	Take Home Exam
20	Fri, 10/12/2012	Chap. 7	Wave equation	Take Home Exam
21	Mon, 10/15/2012	Chap. 7	Wave equation	Exam due
22	Wed, 10/17/2012	Chap. 7, 5	Moment of inertia
	Fri, 10/19/2012		Fall break
23	Mon, 10/22/2012	Chap. 5	Rigid body rotation	#16
24	Wed, 10/24/2012	Chap. 5	Rigid body rotation	#17
25	Fri, 10/26/2012	Chap. 5	Rigid body rotation	#18
26	Mon, 10/29/2012	Chap. 8	Waves in elastic membranes	#19
27	Wed, 10/31/2012	Chap. 9	Introduction to hydrodynamics
28	Fri, 11/01/2012	Chap. 9	Introduction to hydrodynamics
29	Mon, 11/05/2012	Chap. 9	Introduction to hydrodynamics	#20
30	Wed, 11/07/2012	Chap. 9	Sound waves
31	Fri, 11/09/2012	Chap. 9	Linear sound waves	#21
32	Mon, 11/12/2012	Chap. 9	Green's function for linear sound
33	Wed, 11/14/2012	Chap. 9	Non-linear sound
34	Fri, 11/16/2012	Chap. 9	Non-linear sound	Take Home Exam
35	Mon, 11/19/2012	Chap. 10	Surface waves	Take Home Exam
	Wed, 11/21/2012		Thanksgiving Holiday
	Fri, 11/23/2012		Thanksgiving Holiday
36	Mon, 11/26/2012	Chap. 10	Surface waves	Exam due
37	Wed, 11/28/2012	Chap. 10	Surface waves
38	Fri, 11/30/2012	Chap. 10	Surface waves
39	Mon, 12/03/2012		Student presentations I
40	Wed, 12/05/2012		Student presentations II

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PHY 711 - Assignment #1

08/29/2012

PDF file

In evaluating the differential cross section for Rutherford scattering, it is necessary to evaluate the following relationship involving the scattering angle θ, the impact parameter b, and a length parameter κ which involves the ratio of the interaction strength to the system energy:

π
2
− θ
2
= ⌠
⌡ ∞

κ+√{κ²+b²}
b
r
1

√

r²−2 κr −b²

dr.

Use Maple or other algebraic manipulation software to evaluate the integral to show that

b= κ
tan(θ/2)
.

File translated from T_EX by T_TH, version 4.03.
On 28 Aug 2012, 17:56.

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PHY 711 - Assignment #2

8/31/2012

In class, we showed that the relationship between the impact parameter b and the scattering angle χ for elastic scattering between two hard spheres has the form:

b = D cos ⎛
⎝ χ
2
⎞
⎠ .

Using the above diagram which shows the geometry of two hard spheres at the moment of impact, derive this formula.

File translated from T_EX by T_TH, version 4.03.
On 28 Aug 2012, 18:33.

PHY 711 -- Assignment #3

Sept. 3, 2012

Continue reading Chapter 1 in Fetter & Walecka.

In the last lecture, we derived the differential cross section for the elastic scattering of two hard spheres -- dσ/dΩ|_CM( θ) = D²/4, where D is the sum of the radii of the two spheres. Now suppose that in lab frame of reference, the incident mass (m₁) has an initial velocity v₁ and the target mass (m₂) is at rest.
- Find the relationship between the center of mass scattering angle θ to the lab frame scattering angle χ.
- Find the relationship between the lab and CM differential cross sections.
- Evaluate these expressions for the case that m₁=m₂. Check your results to make sure that the total scattering cross section is the same in the two frames of reference.

PHY 711 -- Assignment #4

Sept. 5, 2012

Finish reading Chapter 1 and start reading Chapter 2 in Fetter & Walecka.

Work Problem 1.16 in Fetter and Walecka

PHY 711 -- Assignment #5

Sept. 7, 2012

Finish reading Chapter 2 in Fetter & Walecka.

Complete the analysis of the Foucault pendulum, using either the method used in the lecture notes or the method used in the text. Estimate the pendulum period for Winston-Salem.

PHY 711 -- Assignment #6

Sept. 10, 2012

Start reading Chapter 3 in Fetter & Walecka.

Work problem 3.10 at the end of Chapter 3 of Fetter & Walecka.

PHY 711 -- Assignment #7

Sept. 14, 2012

Continue reading Chapter 3 in Fetter & Walecka.

Work problem 3.5 at the end of Chapter 3 of Fetter & Walecka.

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PHY 711 - Assignment #8

9/17/2012
PDF version

The figure above shows a box of mass m sliding on the frictionless surface of an inclined plane (angle θ). The inclinded plane itself has a mass M and is supported on a horizontal frictionless surface. Write down the Lagrangian for this system in terms of the generalized coordinates X and s and solve for the equations of motion, assuming that the system is initially at rest.

File translated from T_EX by T_TH, version 4.03.
On 16 Sep 2012, 16:08.

PHY 711 -- Assignment #9

Sept. 19, 2012

Continue reading Chapters 3 and 6 in Fetter & Walecka.

Work problem 6.5 at the end of Chapter 6 of Fetter & Walecka.

PHY 711 -- Assignment #10

Sept. 21, 2012

Continue reading Chapters 3 and 6 in Fetter & Walecka.

Work problem 3.13 at the end of Chapter 3 of Fetter & Walecka. Note: For part d, it is not necessary to solve the full equation. Setting up the equations and showing that they are consistent with the known solution is sufficient.

PHY 711 -- Assignment #11

Sept. 24, 2012

Continue reading Chapters 3 and 6 in Fetter & Walecka.

Consider the motion of the particle in the magnetic field given in problem 6.5 part c at the end of Chapter 6 in Fetter and Walekca. Write down the form of the Lagrangian and then determine the Hamiltonian. Determine the canonical equations of motion for the Hamiltonian and show that they lead to the same result you obtained previously.

PHY 711 -- Assignment #12

Sept. 26, 2012

Continue reading Chapter 6 in Fetter & Walecka.
Read parts of the paper by Hans C. Andersen "Molecular dynamics simulations at constant pressure and/or temperature" in which he constructs a Lagrangian function to represent a system of particles held at constant pressure α.

Starting with the Lagrangian function (3.2), derive the Hamiltonian function (3.6).
Derive the equations of motion (3.7).

PHY 711 -- Assignment #13

Sept. 28, 2012

Finish reading Chapter 6 in Fetter & Walecka.

Verify the Hamilton-Jacobi solution to the harmonic oscillator problem we covered in class.
Simplify the expression for the action S(q,t) to show that it is consistent with the action calculated directly from the Lagrangian.

PHY 711 -- Assignment #14

Oct. 01, 2012

Start reading Chapter 4 in Fetter & Walecka.

Work problem 4.2 at the end of Chapter 4 in Fetter & Walecka.

PHY 711 -- Assignment #15

Oct. 03, 2012

Continue reading Chapter 4 in Fetter & Walecka.

Work problem 4.14 at the end of Chapter 4 in Fetter & Walecka.

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Oct 22, 2012

PHY 711 - Problem Set # 16
PDF File
Continue reading Chapter 5 in Fetter and Walecka.

The above figure shows an object with four particles held together with massless bonds at the coordinates shown. The masses of the particles are m₁=m₂ ≡ 2m and m₃=m₄ ≡ m.

Evaluate the moment of inertia tensor for this object in the given coordinate system.

Find the principle moments of inertia and the corresponding principle axes. Sketch the location of the axes.

File translated from T_EX by T_TH, version 4.03.
On 22 Oct 2012, 12:32.
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Oct 24, 2012

PHY 711 - Problem Set # 17
PDF file
Finish reading Chapter 5 in Fetter and Walecka.
In most Classsical Mechanics texts (besides Fetter and Walecka), the Euler angles are defined with a different convention as shown below. (This figure was slightly modified from one available on the website http://en.wikipedia.org/wiki/Euler_angles.)

In this case, the first rotation is about the original ∧z axis by ϕ corresponding to the rotation matrix

ℜ_ϕ = ⎛
⎜
⎜
⎜
⎝

cosϕ
sinϕ
0

−sinϕ
cosϕ
0

0
0
1
⎞
⎟
⎟
⎟
⎠ .
(1)
The second rotation is about the new ∧x axis by θ corresponding to the rotation matrix

ℜ_θ = ⎛
⎜
⎜
⎜
⎝

1
0
0

0
cosθ
sinθ

0
−sinθ
cosθ
⎞
⎟
⎟
⎟
⎠ .
(2)
In this case, the last rotation is about the new ∧z axis by ψ corresponding to the rotation matrix

ℜ_ψ = ⎛
⎜
⎜
⎜
⎝

cosψ
sinψ
0

−sinψ
cosψ
0

0
0
1
⎞
⎟
⎟
⎟
⎠ .
(3)
For this convention, write a general expression for the angular velocity vector ω in terms of the time rate of change of these Euler angles - · ϕ, · θ, and · ψ corresponding to the 29.7 of your text.

File translated from T_EX by T_TH, version 4.03.
On 24 Oct 2012, 12:50.

PHY 711 -- Assignment #18

Oct. 26, 2012

Finish reading Chapter 5 in Fetter & Walecka.

Work either problem 5.9 or problem 5.10 at the end of Chapter 5 in Fetter & Walecka.

PHY 711 -- Assignment #19

Oct. 29, 2012

Start reading Chapter 8 in Fetter & Walecka.

Work problem 8.5 at the end of Chapter 8 in Fetter & Walecka.

PHY 711 -- Assignment #20

Nov. 05, 2012

Continue reading Chapter 9 in Fetter & Walecka.

Determine the form of the velocity potential for an incompressible fluid representing uniform velocity in the z direction at large distances from a spherical obstruction of radius a. Find the form of the velocity potential and the velocity field for all r > a. Assume that the velocity in the radial direction is 0 for r = a and assume that the velocity is uniform in the azimuthal direction.

PHY 711 -- Assignment #21

Nov. 09, 2012

Continue reading Chapter 9 in Fetter & Walecka.

Work problem 9.3 at the end of Chapter 9 in Fetter & Walecka.

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Last modfied: Wednesday, 28-Nov-2012 14:19:30 EST