Physics 1201 Electricity, Magnetism and Modern …humanic/p1201lecture1.pdfThe Origin of Electricity...
Transcript of Physics 1201 Electricity, Magnetism and Modern …humanic/p1201lecture1.pdfThe Origin of Electricity...
Physics 1201 Electricity, Magnetism and Modern
Physics • Lecturer: Tom Humanic • Contact info:
Office: Physics Research Building, Rm. 2144 Email: [email protected] Phone: 614 247 8950 • Office hours: Wednesday 11:30 am & Thursday 11:00 am and by appointment • My lecture slides will be posted before my lecture on my website at http://www.physics.ohio-state.edu/~humanic/
Course Overview • Electricity
electric force electric field and potential electric currents, DC circuits and circuit devices
• Magnetism magnetic force magnetic field
• Electricity and Magnetism combined magnetic fields <---> electric currents electromagnetic waves --> light optics --> mirrors and lenses
• Modern Physics Special Relativity Wave nature of matter Model of the Atom Nuclear Physics
Chapter 16
Electric charge and Coulomb’s law
The Origin of Electricity
The electrical nature of matter is inherent in atomic structure.
kg10673.1 27−×=pm
kg10675.1 27−×=nm
kg1011.9 31−×=em
C1060.1 19−×=e
Coulomb -- SI unit of charge Charge of electron and proton, smallest non-zero charge possible
The Origin of Electricity
In nature, atoms are normally found with equal numbers of protons and electrons, so they are electrically neutral. By adding or removing electrons from matter it will acquire a net electric charge with magnitude equal to e times the number of electrons added or removed, N.
Neq =
The Origin of Electricity
Example 1 A Lot of Electrons How many electrons are there in one coulomb of negative charge?
Neq =
1819- 1025.6
C101.60C 00.1
×=×
==eqN
a lot!
Charged Objects and the Electric Force
It is possible to transfer electric charge from one object to another by moving around electrons, which move easier than positive charges. The body that loses electrons has an excess of positive charge, while the body that gains electrons has an excess of negative charge.
(ebonite is hard rubber)
Charged Objects and the Electric Force
LAW OF CONSERVATION OF ELECTRIC CHARGE During any process, the net electric charge of an isolated system Remains constant (is conserved).
Charged Objects and the Electric Force
Like charges repel and unlike charges attract each other.
Conductors and Insulators
Not only can electric charge exist on an object, but it can also move through an object. Substances that readily conduct electric charge are called electrical conductors. Materials that conduct electric charge poorly are called electrical insulators.
Charging by Contact and by Induction
Charging by contact.
Charging by Contact and by Induction
Charging by induction.
Charging by Contact and by Induction
The negatively charged rod induces a slight positive surface charge on the plastic by polarizing the plastic molecules.
Coulomb’s Law
Coulomb’s Law
COULOMB’S LAW The magnitude of the electrostatic force exerted by one point charge on another point charge is directly proportional to the magnitude of the charges and inversely proportional to the square of the distance between them.
221
rqq
kF =
( ) 229 CmN1099.841 ⋅×== ok πε
( )2212 mNC1085.8 ⋅×= −οε
permittivity of free space
analogous to Newton’s law of Gravitation!
Coulomb’s Law
Example 3 A Model of the Hydrogen Atom In the Bohr model of the hydrogen atom, the electron is in orbit about the nuclear proton at a radius of 5.29x10-11m. Determine the speed of the electron, assuming the orbit to be circular.
221
rqq
kF =
Coulomb’s Law
( )( )( )
N1022.8m1029.5
C1060.1CmN1099.8 8211
219229
221 −
−
−
×=×
×⋅×==
rqq
kF
rmvmaF c2==
( )( ) sm1018.2kg109.11
m1029.5N1022.8 631-
118
×=×
××==
−−
mFrv
Coulomb’s Law
Example 4 Three Charges on a Line Determine the magnitude and direction of the net force on q1.
Coulomb’s Law
( )( )( )( )
N7.2m20.0
C100.4C100.3CmN1099.82
66229
221
12 =××⋅×
==−−
rqq
kF
( )( )( )( )
N4.8m15.0
C100.7C100.3CmN1099.82
66229
231
13 =××⋅×
==−−
rqq
kF
5.7NN4.8N7.21312 +=+−=+= FFF
Coulomb’s Law
Example 5 Three Charges in 2-dimensions Determine the magnitude and direction of the net force on q1.