Magnetism Review and tid-bits. Properties of magnets A magnet has polarity - it has a north and a south pole; you cannot isolate the north or the south.

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Presentation transcript:

Magnetism Review and tid-bits

Properties of magnets A magnet has polarity - it has a north and a south pole; you cannot isolate the north or the south pole (there is no magnetic monopole) Like poles repel; unlike poles attract A compass is a suspended magnet (its north pole is attracted to a magnetic south pole); the earth’s magnetic south pole is within 200 miles of the earth’s geographic north pole (that is why a compass points "north") Some metals can be turned in to temporary magnets by bringing them close to a magnet; magnetism is induced by aligning areas called domains within a magnetic field Permanent magnets are formed of metallic alloys or metals such as iron, nickel, or cobalt. Every spinning electron is a tiny magnet. Electrons spin about their axis like a top spins around its axis. Thus, the electron is a moving charge. Moving charges create a magnetic field. A pair of electrons spinning in the same direction create a stronger magnetic field; a pair of electrons spinning in opposite directions create a weaker magnetic field. The magnetic fields produced by spinning electrons in ferromagnetic materials do not all cancel each other out.

Magnetic field (symbol is B and SI unit is the Tesla or T) –the environment around a magnet in which the magnetic forces act. Another common unit for magnetic field strength is the gauss (G); 1 G = 1 x Magnetic field lines –they represent the area around a magnet; magnetic field lines outside of the magnet flow from the north to the south pole Domain –Atoms of ferromagnetic materials act in groups called domains; atomic magnets in each domain are aligned so that each domain is a microscopic bar magnet; the domains align themselves with an external magnetic field. Each domain behaves like a tiny magnet and has a north and a south pole. In unmagnetized materials, the domains are randomly arranged. In magnetized materials, the domains are aligned. Anything that randomizes the alignment of the domains destroys the magnetic properties of a material (dropping a magnet or heating it)

Comparing electricity and magnetism ElectricityMagnetism + and - chargesN and S poles like charges repellike poles repel unlike charges attractunlike poles attract electric monopole existsno magnetic monopole electric field lines flow from + to -magnetic field lines flow from N to S density of lines equals strength of Edensity of lines equals strength of B SI unit: ampere, 1 A = 1 C/secSI unit: Tesla, 1 T = 1 N/Amp meter E exerts force on a charge, or E = F/qField exerts force on a moving charge, or B = F/(qvsin  )

Electric and Magnetic Field ElectricMagnetic Source: ChargesMoving Charges Act on: Charges Moving Charges Magnitude: F=Eq F = q v B sin(  ) Direction: Parallel EPerpendicular to v,B Direction: Opposites Charges AttractCurrents Repel

Curie temperature Important constants to know for this section: The charge of an electron (or proton) is 1.6 x 10-19C and one Volt is equivalent to 1.6 x J of energy. Curie temperature temperature above which a material loses all magnetic properties Oersted (1820) found that an electric current in a wire produces a magnetic field around it; a stationary charge does not create a magnetic field

Right Hand Rules Right-hand rules predict the direction of magnetic fields produced by a current. They are used for conventional current flow. Use your left hand to predict the direction an electron or negative charge would follow.

Curl the fingers of the right hand into the shape of a circle. Point the thumb in the direction of the current and the tips of the fingers will point in the direction of the magnetic field. RHR #1 Straight Wire Conductor

RHR #2 - Solenoid Curl the fingers of the right hand in the direction of the current. Your thumb is the north pole of the electromagnet.

RHR #3 - Magnetic Force Extend the right hand so that the fingers point in the direction of the magnetic field and the thumb points in the direction of the current. The palm of the hand then pushes in the direction of the magnetic force.

Forces Due to Magnetic Fields –Ampere found that a force is exerted on a current-carrying wire in a magnetic field –F = B I L sin  –where B is the magnetic field in Teslas (T), I is the curent, L is the length of wire in meters, and  is the angle. Only the perpendicular component of B exerts a force on the wire. If the direction of the current is perpendicular to the field (  =90), then the force is given by F = B I L

–We know how to measure force, current, and length. Thus B can be calculated by using –The force produced by a magnetic field on a single charge depends upon the speed of the charge, the strength of the field, and the magnitude of the charge. –F = q v B sin  –where q is the charge in Coulombs and v is the velocity of the charge. If  =90, then F = q v B –How speed affects the force on a charged particle moving in a magnetic field. –Effects of speed of particle in a Magnetic FieldEffects of speed of particle in a Magnetic Field

–The magnetic field near a long straight wire is directly proportional to the current I in the wire and inversely proportional to the distance r from the wire. The magnetic field at any point a distance R away from a straight-wire conductor can be calculated using, –or, it can be written in its true form (This is an important formula for the AP B exam.) –where  o is a constant called the permeability of free space and has a value of 4  x T m/A –Since a wire carrying a current produces a magnetic field and the wire experiences a force when placed in a magnetic field, two current-carrying wires exert a force on each other. The force exerted on the second wire is only due to the magnetic field exerted by the first wire. Parallel currents in the same directions attract each other and parallel currents in opposite directions repel each other.

Force on a Loop of Wire (represented by multiple choice questions on the AP B exam in which you predict the direction of current, etc.) At the center of the loop, the magnetic field is perpendicular to the plane of the loop. If there are N loops, the strength of the magnetic field at the center of the loop is given by multiplying the following by N. The direction of the magnetic field at the center of the loop can be determined using a RHR (the thumb is pointed in the direction of the current and the curled fingers are placed at the center of the loop, then the palm pushes in the direction of the magnetic field.)

Motion of charged particles in B The magnetic force is always perpendicular to the velocity of the particle B Heavier particle has a larger R of the orbit than a lighter one. Mass-spectrometers use that!

Mass Spectrometer Heavier particle has a larger R of the orbit than a lighter one. Mass- spectrometers use that!

A charged particle inside the magnetic field can move: Along a straight line Along a circular path Or along a helical path Motion of Charged Particles in B

Magnetic Force on Current Carrying Wire F depends on the magnitude of the B, on the magnitude of the I, on the orientation of the magnetic field relative to the wire and on its length. The force is always perpendicular to the wire.

Magnetic Field and Electric Current: Reciprocal relationship!  Charged particle is affected by a magnetic field.  Wire carrying electric current is affected by a magnetic field.  Wire carrying electric current creates magnetic field! Moving charged particles! External magnetic fields! Magnetic fields created by the moving charged particles

Ampere’s Law: Magnetic Field Created by Electric Current  o is the permeability of free space: it is a constant.

Magnetic field created by a Long Straight Wire  o is the permeability of free space: it is a constant.

Forces Between Current Carrying Wires