1 day 3: finish electric circuits photocopiers: bloomfield 10.2 photoconductors (blm 12.1...
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Day 3: Finish electric circuitsPhotocopiers: Bloomfield 10.2Photoconductors (Blm 12.1 p.427-433).
Reminders/Updates:
HW 1 due NOW!Phys 1010 notes on website
All info is on web (I think)
Photocopiers
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PhotocopiersStatic electricity and semiconductors
Learning goals1. Explain how you could write on paper with photoconductor, toner,
light, high voltage wire. (basic design of copier)
2. Be able to explain why materials are conductors, insulators, or semiconductors in terms of energy levels and electron motion.
3. Explain how heat or light changes resistance of semiconductor.
Big picture: 1. Coulomb attraction of positively charged ink particles (toner) to
negatively charged surface.
2. Negative charges on surface distributed to match image to be copied.
3. Control charge distribution by shining light on surface, where light hits, negative charges leave, so no ink will stick.
The big challenge- how to get charges to leave when light shines on surface?
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• Chester Carlson says: there must be a way to copy things!– Recopying and photography too expensive and time-consuming.
• 1938 Chester Carlson produces first xerographic image in his lab in Astoria, Queens. 10-22-38 ASTORIA.
– Materials: • Sulfer,
• handkerchief,
• bright light,
• spoors from a club moss: lycopodium powder
• Wax paper and heat
Photocopiers – a brief history
•Turned down by 20 companies
•1959 Launches the Xerox 914, the first automatic, plain-paper office copier--which becomes the top-selling industrial product of all time.
–http://en.wikipedia.org/wiki/Chester_Carlson
–http://en.wikipedia.org/wiki/Xerox_914
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“Photocopying” - step 1:
Overhead Transparencies
(insulator)
When I drag the copper comb across the transparencies: a. Negative charges flow through the transparencies and
into the floor, b. Nothing.c. Negative charges will build up on the transparencies
just in the areas where the comb touchesd. Negative charges will be everywhere on the
transparencies, even the parts I don’t touch with the comb.
----
-
------
-
--
-
-- --
Copper electron comb
--------------------------------------------------
-------------------------------------------------------
- - -
- --
-
-
--
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“Photocopying” step 2:
a. Nothing will happenb. The entire plate will lose it’s negative charge. c. Only the areas of the plate that I touch will lose
their negative charge.
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What will happen if I draw on the plate with my finger?
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“Photocopying” step 3: Toner sticking to charged surface
Chalk only sticks to places with negative charge because the chalk is a. positively charged, b. negatively charged, c. uncharged (neutral), d. both a and c are correcte. both b and c are correct.
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HI
Photocopying expts - summary
We have demonstrated some important steps inside a photocopier:
• Charging an insulating sheet, discharge certain areas– Make a charge image
• Apply chalk/toner– Electrostatic attraction produces visible image
But where does light (the ‘photo’ bit) come in?
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Photocopying 1: Making a Charge Image
Photoconductor
Grounded metal
- - -
- - -
- -
Document Lightreflected off document
+ + + + + + +
+ ++
+
Charge image
+ +
+ +
+ + + + +
+ + + + + + +
+ ++
+
- - -
- - -
- -Corona wire
velocity
+ + + + +
+ ++
+
Charge photoconductor
Selective discharge
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Photocopying 2: Transferring Charge Image to Toner and Paper
+ ++ ++
Black image
+ +
+ +
+ + + + +
++++ +
+++
+
Release toner
+ + +
Light
- - - + ++
+ ++
Charge image
+ +
+ +
+ + + + +
Positive toner particle
toner
Roller and brush
+
++
+ +
Attract toner to charge image
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Straightforward. All just good old physics of attraction between opposite charges, plus photoconductor physics.
- - -
- - -
- -
Charge Paper
++ ++ ++ ++++ ++
Toner attracted to paper
Heat++ ++
Photocopying 2: Transferring Charge Image to Toner and Paper
Copy
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V- -
- -
- - - - -
Photoconductor at heart of photocopier: -
Behaves like an insulator when in the dark
- Where light hits, R low, electrons flow away,
- When add toner, sticks only where charges are left.
Photoconductor:- Very special material – insulator except when light hits. - One type of semiconductor
First have to understand what determines resistance of a material:
a) insulators (wood, ceramic, plastic)- very high resistance.
b) conductors (metals)- very low resistance
c) Semiconductors - in the middle. Resistance depends on temp., light, cleanliness.
Semi-conductor physics
What determines resistance of a material
- Charged particles (almost always electrons) carry current inside materials
- Resistance of material depends on a) Number of charged particles that are free to move and carry current
b) Number of obstacles that charge carriers might bump into
Can be controlled in a semiconductorAt the heart of all modern electronics!
Atomic structure
Nucleus - Protons and neutrons- Positively charged- Very small and dense
Electron cloud- Negatively charged- MUCH larger than nucleus
Quantum Mechanics
- Weird physics of very small things (like electrons)- Electrons behave as both particles and waves- As waves, they can only move in certain ways and have certain amounts of energy- Only 2 electrons per energy level (Pauli Exclusion Principle)
particle wave
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En
erg
y
Electron energy levels get shifted and shared between all atoms and electrons
Atomic structure of solids and energy bands
one atom
many atoms
Discreet energy levels for electrons
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• Levels get shifted and shared for all atoms and electrons• So many individual levels, just talk about bands of levels. • 2 electrons per level until run out of electrons
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2
3
Lower energy levels –mostly full of electrons
Higher energy levels are empty
In solid, billions of atoms, electrons, and energy levels!!
Ele
ctro
n e
ne
rgy
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empty
full
Insulator:Big jump to empties.
Can’t movewithout big boost.
Electron like a ball in pit.
gap- no levels
Conductor: empty levels very close
moves easily
electron like ball rolling on almost flat ground
empty
Microscopic look at different materials
Semiconductor:Half way in between.Small jump to empties
empty
full
- Electron like ball in shallow pit. - Small boost required to move.
Small gap
full
Conduction rule: For electrons to move (when a voltage is applied) there must be an empty energy level immediately above them
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emptyfull
En
erg
y
x y z w
25 eV
0
Which band structure goes with which material?
D=Diamond C=Copper G=Germanium (semi-conductor)
a. D=w, C=x, G=y b. D=z, C=w, G=y c. D=z, C=y, G=xd. D=y, C= w, G=y. e. D=w, C=x, G=y
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empty
full
Review of semiconductors.
Little gap
• Small gap between filled and empty energy levels. • Gap is big enough to stop current (high R).• Gap is small enough so humans can find ways to boost electrons up.• Concept behind all modern electronics! • Use semiconductors to control electric currents.
Q: Which will decrease resistance of a semiconductor? add heat, light, shake, add dirta. T T T Tb T T F Fc T T F Td F T F Fe F T F T
Like ball stuck in shallow pit
e
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empty
full
Photo-conductor: Kick electron to empty levels with light
E = energy of photon = h x frequency (h) = h x c / wavelength (hc/)
Q: If green light has just enough energy to excite electron into emptylevel and allow it to move (conduct electricity)
a. both blue and red light will also make it a conductor
b. blue light will, red light will not
c. neither blue nor red light will make it into a conductor
Little gape
Photocopier summary
• Spread charge on photoconductor• Use light to selectively remove some charge and
make a charge image of original• Electrostatic attraction sticks toner to regions where
charge remains• Use heat to bond toner to new piece of paper• Copying is complete!
We will return to semi-conductors and their use in electronics in a couple of weeks