Introduction to Physical SystemsDr. E.J. Zita, The Evergreen State College, 30.Sept.02Lab II Rm 2272, zita@evergreen.edu, 360-867-6853

Program syllabus, schedule, and details online at http://academic.evergreen.edu/curricular/physys2002/home.htm

Monday: E&M in homeroom = Lab II Rm 2242

Tuesday: DiffEq with Math Methods and Math Seminar (workshop on WebX in CAL tomorrow at 5:00 - photos today)

Wed: office hours

Thus: Mechanics and Physics Seminar in homeroom

TA = Noah Heller (nonoah@hotmail.com)

Time budget

E&M DiffEq Mechanics Total time5 hrs class 5 hrs class 5 hrs class 154 hrs reading 4 hrs reading 4 hrs reading 126 hrs homework 6 hrs homework 6 hrs homework 18

46 minimum

Plus your presentations in fall, library research in winter, and advanced research

in spring.

Introduction to ElectromagnetismDr. E.J. Zita, The Evergreen State College, 30.Sept.02

• 4 realms of physics• 4 fundamental forces• 4 laws of EM• statics and dynamics• conservation laws• EM waves• potentials• Ch.1: Vector analysis• Ch.2: Electrostatics

Four realms of physics

Classical Mechanics(big and slow:

everyday experience)

Quantum Mechanics(small: particles, waves)

Special relativity(fast: light, fast particles)

Quantum field theory(small and fast: quarks)

Four fundamental forces

Four laws of electromagnetism

Electric Magnetic

Gauss' Law

Charges make E fields

Gauss' Law

No magnetic monopoles

Ampere's Law

Currents make B fields(so does changing E)

Faraday's Law

Changing B make E fields

Electrostatics

• Charges make E fields and forces

• charges make scalar potential differences dV

• E can be found from V• Electric forces move

charges• Electric fields store

energy (capacitance)

Magnetostatics

• Currents make B fields• currents make magnetic

vector potential A• B can be found from A

• Magnetic forces move charges and currents

• Magnetic fields store energy (inductance)

Electrodynamics

• Changing E(t) make B(x)• Changing B(t) make E(x)• Wave equations for E and B

• Electromagnetic waves• Motors and generators• Dynamic Sun

Advanced topics

• Conservation laws

• Radiation

• waves in plasmas

• Potentials and Fields

• Special relativity

Ch.1: Vector Analysis

Dot product: A.B = Ax Bx + Ay By + Az Bz = A B cos

Cross product: |AxB| = A B sin zyx

zyx

BBB

AAA

zyx

zB y B x B ,zA yA xA zyxzyx BA

Examples of vector products

Dot product: work done by variable force

Cross product:

angular momentum

L = r x mv

dlFW cos

Differential operator “del”

Del differentiates each component of a vector.

Gradient of a scalar function = slope in each direction

Divergence of vector = dot product = what flows out

Curl of vector = cross product = circulation

yz

yy

xx

ˆˆ

y

fz

y

fy

x

fxf

ˆˆ

y

Vz

y

Vy

x

Vx zyx

ˆˆV

zyx

VVVzyx

zyx

zyx

ˆˆV

Practice: 1.15: Calculate the divergence and

curl of v = x2 x + 3xz2 y - 2xz z

...)2(

ˆ)3(

ˆ22

y

xzz

y

xzy

x

xx

V

zyx

xzxzxzyx

zyx

ˆˆ

222

V

Ex: If v = E, then div E = charge; if v = B, then curl B = current.

Separation vector differs from position vector:

Position vector = location of a point with respect to the origin.

Separation vector: from SOURCE (e.g. a charge at position r’) TO POINT of interest (e.g. the place where you want to find the field, at r).

222ˆˆˆ zyxrzzyyxx r

222 )'()'()'('

ˆ)'(ˆ)'(ˆ)'('

zzyyxx

zzzyyyxxx

rr

rr

Sign up for your 20-minute presentations:

7 Oct: 1.1.1 Vector Operations

1.1.2 Vector Algebra

1.1.3 Triple Products

14.Oct: 1.1.4 Position, Displacement, and Separation Vectors

1.2.1 + 1.2.2 Ordinary derivatives + Gradient

1.2.3 The Del Operator

Ch.2: Electrostatics: charges make electric fields

• Charges make E fields and forces

• charges make scalar potential differences dV

• E can be found from V• Electric forces move

charges• Electric fields store

energy (capacitance)

Gauss’ Law practice:

2.21 (p.82) Find the potential V(r) inside and outside this sphere with total radius R and total charge q. Use infinity as your reference point. Compute the gradient of V in each region, and check that it yields the correct field. Sketch V(r).

What surface charge density does it take to make Earth’s field of 100V/m? (RE=6.4 x 106 m)

2.12 (p.75) Find (and sketch) the electric field E(r) inside a uniformly charged sphere of charge density .