Download wbm-physics

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

Document related concepts

Fundamental interaction wikipedia , lookup

History of quantum field theory wikipedia , lookup

T-symmetry wikipedia , lookup

Electromagnetism wikipedia , lookup

Lepton wikipedia , lookup

Aharonov–Bohm effect wikipedia , lookup

Elementary particle wikipedia , lookup

Potential energy wikipedia , lookup

Electric charge wikipedia , lookup

Introduction to gauge theory wikipedia , lookup

Renormalization wikipedia , lookup

History of physics wikipedia , lookup

History of subatomic physics wikipedia , lookup

Anti-gravity wikipedia , lookup

Nuclear physics wikipedia , lookup

Condensed matter physics wikipedia , lookup

Electrostatics wikipedia , lookup

Atomic theory wikipedia , lookup

Time in physics wikipedia , lookup

Chien-Shiung Wu wikipedia , lookup

Transcript
Electric Potential
Chapter 26
physics chapter 26
1
Review from ch 7
W12  U1  U 2

When positive work is done, the potential
energy decreases.
K1  U1  K2  U 2

Total energy is conserved.
physics chapter 26
2
Work done by E field
Wab  Fd  qEd

Using calculus and the coulomb force
equation, we can come up with
Wab
q1q2  1 1 
  

40  ra rb 
physics chapter 26
3
Work done by E field

We can write using potential energy
Wab  U a  U b

Thus
1
q1q2
U
40 r
physics chapter 26
4
Example


A small plastic ball with a mass of 2.0 g and
an electric charge of 0.10 mC moves in the
vicinity of a stationary metal ball with a
charge of 2.0 mC. When the plastic ball is
0.10 m from the metal one, the plastic ball is
moving directly away from the metal one with
a speed of 5.0 m/s.
What is the speed of the plastic ball when the
two balls are 0.20 m apart?
physics chapter 26
5
You try

What if the plastic ball had a charge of
-0.10 mC?
physics chapter 26
6
Potential

Potential energy per unit charge
U
V
q

U  qV
Measured in volts
J
1V  1
C
physics chapter 26
7
Potential from a group of
charges
qi
V

40
ri
1
physics chapter 26
8
Example

Pages 583-584
physics chapter 26
9
Equipotential surfaces


A surface such that every point on the
surface has the same potential.
Since the potential is the same, E does no
work as a charge moves along an
equipotential surface.
physics chapter 26
10
Millikan oil-drop experiment




1909-1913 in Chicago by Robert Millikan
Very small electrically charged oil drops
sprayed into electric field
Field adjusted until the gravitational force
down balanced the electric force up.
Figured out charge on the oil drops.
physics chapter 26
11
Millikan oil-drop experiment




Figured out that the charge was always a
whole number multiple of 1.6 x 10-19
“discovered” the charge on the electron
Validation of atomic theory
Combined with earlier research of J.J.
Thomson to determine mass of electron
physics chapter 26
12
Mass of oil drops
mg
q
E
mgd
q
V
4 r gd
q
3 V
3 3
d  vt
q  18
V 2 g
3
physics chapter 26
13
Electronvolt




Unit of energy (like J)
Useful in atomic and nuclear calculations
1 eV = 1.6 x 10-19 J
The change in energy as 1 electron moves
through a potential difference of 1 V
physics chapter 26
14
Rest energy
E0 = mc2
 For an electron, 81.87 x 10-15 J or 0.511 MeV
 Mass of subatomic particles is often
expressed in MeV/c2 to make the numbers
easier to work with
 Mass of electron = 0.511 MeV/c2
physics chapter 26
15
Cathode ray tubes





Found in computer monitors and
oscilloscopes
Similar to TV picture tubes
Use an electron beam – historically called a
cathode ray
A near vacuum
Electrons sent through two sets of electrically
charged plates


One to aim it horizontally
One to aim it vertically
physics chapter 26
16
Equations


We did this kind of problem last chapter
There are more equations on pages 594 595
physics chapter 26
17