Difference between revisions of "TF EIM Chapt1"

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: A vector field is the association of each point in space with a direction (vector)
 
: A vector field is the association of each point in space with a direction (vector)
  
:Example: Gravity.  One the surface of the earth you observe that an apple will fall down to the ground.  You can define a vector (<math>\vec{g})</math> which points directly down and tell you the direction that an apple will accelerate if it is released.  If you construct \vec{g} such that
+
:Example: Gravity.  One the surface of the earth you observe that an apple will fall down to the ground.  You can define a vector (<math>\vec{g})</math> which points directly down and tell you the direction that an apple will accelerate if it is released.  If you construct <math>\vec{g}</math> such that
  
 
:<math>\vec{g} = \frac{F_g}{m} = \frac{\frac{GMm\vec{r}}{r^3}}{m} = \frac{GM\hat{r}}{r^2}</math> = acceleration of an apple towards the earth's surface when close to the earth's surface.
 
:<math>\vec{g} = \frac{F_g}{m} = \frac{\frac{GMm\vec{r}}{r^3}}{m} = \frac{GM\hat{r}}{r^2}</math> = acceleration of an apple towards the earth's surface when close to the earth's surface.

Revision as of 17:15, 3 January 2011

Fundamentals

Charge

Every stable and independent object (particle) that has charge has been observed to contain a quantized unit of charge which is a multiple of [math]1.6 \times 10^{-19} Coulombs[/math]

What are the obervations/experiments?

Experiment 1: Matter is composed of Atoms with a positively charged nucleus surround by negatively charged electrons. If we now the charge of one mole of electrons ([math]F[/math]= Faradays constant) and the number of electrons in a mole ([math]N_A[/math] = Avagadros number)then the charge of a single electron is given by

[math]e = \frac{F}{N_A}[/math]

Experiment 2: Oil drop experiment

Experiment 3: The Hall Effect and the Josephson Effect

Coulomb
The amount of charge that flows through any cross section of a wire in 1 second if there is a steady current of 1 ampere in the wire.

Coulomb Force

Two charged object separated by a distance (d) will feel a force between them known as the coulomb force. The magnitude of this force has been experimentally shown to be

[math]\left | \vec{F}_{coul} \right | = \frac{1}{4 \pi \epsilon_0} \frac{q_1 q_2}{r^2}[/math]

where

[math] \varepsilon_0 =\frac {1}{\mu_0 c_0^2}=8.854187817 \times 10^{-12}[/math]F/m = a experimentally measured quantity satisfying the above relationship know as the permittivity of free space.
[math] q_1 =[/math] charge of first object
[math]q_2 =[/math] charge of second object
[math]r =[/math] distance between the charges

(Charles Augustin Coulomb first measured the attract and repulsive force between two charged objects using a torsion balance around 1785)

This force may be described in terms of an electric field E such that

[math]\vec{E} = \frac{\vec{F_q}}{q}[/math]


Where

F= force between the objects

Electric Field

Vector Field

What is a vector field?
A vector field is the association of each point in space with a direction (vector)
Example: Gravity. One the surface of the earth you observe that an apple will fall down to the ground. You can define a vector ([math]\vec{g})[/math] which points directly down and tell you the direction that an apple will accelerate if it is released. If you construct [math]\vec{g}[/math] such that
[math]\vec{g} = \frac{F_g}{m} = \frac{\frac{GMm\vec{r}}{r^3}}{m} = \frac{GM\hat{r}}{r^2}[/math] = acceleration of an apple towards the earth's surface when close to the earth's surface.

Consider what you observe when you place a bar magnet in the vacinity

A separated object of finite charge creates an electric field.

Electric potential

Ohm's Law

resistance is a constant
[math]R = \frac{\Delta V}{I}[/math]= constant


TF EIM Lab1.png

Voltage

The MKS unit for Voltage is a Joule per Coulomb [math]\left ( \frac{\mbox{J}}{\mbox{C}}\right )[/math]

Voltage in circuits is typically defined as the electric potential energy per unit charge relative to ground.

Current

Resistance

Batteries

Power

Kirhcoff's Laws