Download ELECTRIC FIELD ELECTRIC FLUX GAUSS LAW

Survey
yes no Was this document useful for you?
   Thank you for your participation!

* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project

page
1
page
2
page
3
page
4
page
5
page
6
page
7
page
8
page
9
page
10
page
11
page
12
page
13
page
14
page
15
page
16
page
17
page
18
page
19
page
20
page
21
page
22
page
23
page
24
page
25
page
26
page
27
page
28
Document related concepts

History of electromagnetic theory wikipedia , lookup

Magnetic monopole wikipedia , lookup

Field (physics) wikipedia , lookup

Aharonov–Bohm effect wikipedia , lookup

Lorentz force wikipedia , lookup

Maxwell's equations wikipedia , lookup

Metadyne wikipedia , lookup

Electric charge wikipedia , lookup

Electrostatics wikipedia , lookup

Transcript 
ELECTRIC FIELD
ELECTRIC FLUX
GAUSS LAW
Today…..
• More on Electric Field:
– Continuous Charge Distributions
• Electric Flux:
– Definition
– How to think about flux
Summary
Electric Field Lines
Electric Field Patterns
Dipole
Point Charge
Infinite
Line of Charge
Two types of electric charge: opposite charges attract,
like charges repel
1 Q1Q2 ∧
F12 =
2 r12
4πε 0 r12
→
Coulomb’s Law:
Electric Fields
→
Charges respond to electric fields:
Charges produce electric fields:
→
F = qE
q
E=k 2
r
Electric Flux
Flux:
Let’s quantify previous discussion about field-line “counting”
Define: electric flux
ψ
through the closed surface S
ψ = ∫ E • dS
S
“S” is surface
of the box
Electric Flux
ψ = ∫ E • dS
S
•What does this new quantity mean?
• The integral is over a CLOSED SURFACE
→
→
• Since E • dS is a SCALAR product, the electric flux is a SCALAR
quantity
→
• The integration vector dS is normal to the surface and points OUT
→
→
of the surface. E • dS is interpreted as the component of E which is
NORMAL to the SURFACE.
• Therefore, the electric flux through a closed surface is the sum of
the normal components of the electric field all over the surface.
• The sign matters!!
Pay attention to the direction of the normal component as it
penetrates the surface… is it “out of” or “into” the surface?
• “Out of” is “+” “into” is “-”
How to think about flux
• We will be interested in net
flux in or out of a closed
surface like this box
• This is the sum of the flux
through each side of the box
– consider each side separately
• Let E-field point in y-direction
→
– then E and
→
→
→
S
are parallel and
→
E • S = E w2
ELECTRIC FLUX DENSITY
We define electric flux
ψ
D = ε0E
in terms of D
ψ = ∫ D • dS
For example, for an infinite sheet of charge
ρs
E=
an ,
2ε 0
⎛ ρs ⎞
ρs
⎟⎟ a n =
D = ε 0 ⎜⎜
an
2
⎝ 2ε 0 ⎠
For line charge distribution
ρL
ρL
E=
aρ , D =
aρ
2πε 0 ρ
2πρ
For volume charge distribution
ρV dv
ρV dv
E=∫
a
D
=
a
,
R
∫
2
2 R
4πε 0 R
4πR
Example:
Determine D at (4,0,3) if there is a point charge -5π mC at
(4,0,0) and a line charge 3 π mC/m along the y axis.
Let D = DQ +
DL
where DQ and DL are flux densities due to the
point charge and line charge respectively.
Q
Q(r − r )
DQ = ε 0 E =
aR =
2
' 3
4πR
4π r − r
'
Where r – r’ =(4,0,3) –(4,0,0)=(0,0,3).Hence,
− 5π x 10 − 3 (0,0,3 )
mC 2
DQ =
=
−
0
.
138
a
3
z
m
4π 0,0,3
Also,
ρL
DL =
aρ
2πρ
aρ
(
(4,0,3) − (0,0,0) ) (4,0,3)
=
=
(4,0,3) − (0,0,0)
5
3π
(4ax + 3az ) = 0.24ax + 0.18az mC m 2
DL =
2π (5)(5)
Thus,
D = DQ + DL
C
µ
D = 240 a x + 42 a z
m2
GAUSS’S LAW-MAXWELL’S EQUATION
Gauss’s Law states that the total electric flux ψ through any closed
surface is equal to the total charge, Q enclosed by that surface .
ψ = Qenc
That is
ψ = ∫ dψ = ∫ D • dS
S
= Total Charge enclosed , where
Q = ∫ ρ v dv
v
∴ Q = ∫ D • dS = ∫ ρ v dv
S
v
The integration is performed over a closed surface,
i.e. gaussian surface.
By applying Divergence Theorem
∫ D • dS = ∫ ∇ • Ddv
Where,
ρV = ∇ • D
APPLICATION OF GAUSS’S LAW
A. Point Charge
Since D is everywhere normal to gaussian surface, that is
D = Dr ar
From Gauss Law,
ψ = Qenc
Q = ∫ D • dS = Dr ∫ dS = Dr 4πr
Where ∫ D • dS =
2π
∫φ θ
π
2
2
2
r
sin
θ
d
θ
d
φ
=
4
π
r
∫
=0 =0
Q
∴D =
ar
2
4π r
B. Infinite Line of Charge
Suppose the infinite of uniform charge ρ L C m lies along the z-axis.
Determine D at point P?
D = Dρ aρ
Q = ∫ ρ L dl
but , Q = ∫ D • dS = Dρ ∫ dS = Dρ 2πρL
ρL
D=
aρ
2πρ
C. Infinite Sheet of Charge
Consider the infinite sheet of uniform charge is
ρS
C/m2
D = DZ aZ
∫ρ
∫ D • dS
ρ dS = D ( A + A )
ρ A = D (A + A )
Q =
S
dS , Q =
S
Z
S
D =
Z
ρS
2
aZ
ρS
Therefore , E =
=
aZ
ε 0 2ε 0
D
D. Uniformly Charged Sphere
Gaussian surface for a uniformly charged sphere
Q
enc
∫ρ
=
= ρ
v
dv = ρ
2π
v
π
∫
∫
∫
φ
θ
=0
= ρ
r
v
∫
v
dv
r 2 sin θ drd θ d φ
=0 r=0
4
πr
3
3
And
ψ =
∫
D • dS = D
= D
2π
r
π
= D r 4π r
∫
dS
r sin θ d θ d φ
∫
∫
φ
θ
=0
r
2
=0
2
Hence ,
ψ = Qenc gives
4π r
ρv
D r 4π r =
3
Or ..
3
2
r
D = ρ v ar
3
for 0 > r ≤ a
r ≥ a,
For
Q
enc
∫ρ
=
= ρ
v
dv = ρ
2π
v
r
2
dv
sin θ drd θ d φ
=0 r=0
4
πa
3
3
,
While
ψ =
v
a
∫ θ∫ ∫
φ
=0
= ρ
π
∫
v
∫
D • dS
D r 4π r
2
= D r 4π r
4
=
πa 3ρ
3
2
v
Or ..
a3
D =
ρ va r
2
3r
for r ≥ a
D everywhere is given by:
⎧r
a
ρ
⎪3 v r
D=⎨ 3
a
⎪ 2 ρ v ar
⎩ 3r
0<r ≤a
r≥a
Related documents
Gauss` Law Post Entry
Gauss` Law Post Entry
Fall 2006
Fall 2006
PDF of video problems for Ch 22
PDF of video problems for Ch 22
Document
Document
普物甲下 - csie.org
普物甲下 - csie.org
L22
L22
Physics Lecture #25
Physics Lecture #25
Physics 241 Recitation
Physics 241 Recitation
The Electric Field
The Electric Field
Chapter 27
Chapter 27
Gauss`s Law
Gauss`s Law
lecture
lecture
EQUIVALENT Gauss`s Law
EQUIVALENT Gauss`s Law
Path of Least Time - Rutgers University
Path of Least Time - Rutgers University
Lecture 9 File
Lecture 9 File
Chapter 3. Electric Flux Density, Gauss`s Law, and Divergence
Chapter 3. Electric Flux Density, Gauss`s Law, and Divergence