dicovered electron in 1897
J.J. Thomson
named electron
G.J. Stoney
measured charge on electron (oil drop expt.)
Robert Millikan
thermionic emission
release of electrons from the surface of a hot metal
cathode ray tube
uses thermionic emission to create beam of electrons (know how to draw)
invented by Karl Ferdinand Braun
CRT process
- low voltage heats up filament which heats cathode (-) causing thermionic emission
- high voltage placed across anode and cathode (anode voltage) causing released electrons to accelerate towards anode
- end of tube coated in phosphors (fluorescent) so when electrons strike it light is produced
cathode ray
streams of high speed electrons moving from cathode
properties of cathode rays
- travel in straight lines
- cause certain materials to emit light when struck
- have kinetic energy
- can be deflected in magnetic/electric fields
- can produce x-rays when they strike metal target
conservation of energy in electric field
loss in potential = gain in kinetic
eV = 1/2mv^2 // qV = 1/2mv^2
q = e = charge
e = charge on electron V = voltage
–> W = qV
electronvolt
amount of energy gained/lost by 1 electron when it moves through a p.d. of 1V
1eV = 1.6x10^-19J
uses of CRT
- tv/computer monitor
- cathode ray oscilloscope (CRO) - displays elec. signal
Electrocardiogram (ECG)
displays the hearts elec. signals
electroencephalogram (EEG)
displays brains elec. signals
photoelectric effect
emission of electrons from the surface of a metal by electromagnetic radiation of a suitable frequency
Heinrich Hertz
1887 discovered elec. spark occurred more readily when U.V. light fell on one of the electrodes
Hallwachs
1888 discovered if UV light fell on neg. zinc plate it lost its charge rapidly
photocell
device that conducts when light of a suitable freq falls on the cathode
- current ∝ intensity
(be able to draw)
photons
packets of electromagnetic energy
energy of a photon
E = hf
h = planck’s constant
-energy depends on freq. of light
-no. of photons per sec ∝ intensity of light
-energy of 1 photon only passed to 1 electron
threshold frequency
definite frequency below which no photoemission occurs no matter how intense the light is
e.g. threshold f for zinc is UV light
work function ϕ
minimum energy needed to remove the loosest electron from the surface of that metal
einstein’s photoelectric law
hf = ϕ + 1/2mv^2(max)
- energy of 1 photon passed onto 1 electron = min energy required to remove electron + kinetic energy gained when released
- max kinetic energy increases with freq. but not intensity
uses of photoelectric cells
- burglar alarms
- automatic doors
- counting items on conveyor belt
- monitoring + controlling flame in central heating burner
- reproduce soundtrack in film projector
- scintillation counter
x-rays
high freq. electromagnetic radiation. produced when high speed electrons in CRT strike a metal target with high melting point.
- penetrating power ∝ freq.
- freq. ∝ V across tube
Hard xrays - high penetrating power
soft xrays - low p.p.
