Lecture 6: Integrated Circuit Resistors

Department of EECS University of California, Berkeley

EECS 105 Fall 2003, Lecture 6

Lecture 6: Integrated Circuit Resistors

Prof. Niknejad


EECS 105 Fall 2003, Lecture 6 Prof. A. Niknejad

Lecture Outline

Semiconductors Si Diamond Structure Bond Model Intrinsic Carrier Concentration Doping by Ion Implantation Drift Velocity Saturation IC Process Flow Resistor Layout Diffusion



Resistivity for a Few Materials

Pure copper, 273K 1.56×10-6 ohm-cm Pure copper, 373 K 2.24×10-6 ohm-cm Pure germanium, 273 K 200 ohm-cm Pure germanium, 500 K .12 ohm-cm Pure water, 291 K 2.5×107 ohm-cm Seawater 25 ohm-cm

What gives rise to this enormous range?

Why are some materials semi-conductive?

Why the strong temp dependence?



Electronic Properties of Silicon

Silicon is in Group IV – Atom electronic structure: 1s22s22p63s23p2

– Crystal electronic structure: 1s22s22p63(sp)4

– Diamond lattice, with 0.235 nm bond length Very poor conductor at room temperature:

why?(1s)2

(2s)2

(2p)6 (3sp)4

Hybridized State



Periodic Table of Elements



The Diamond Structure

3sp tetrahedral bond

A43.5

A35.2



States of an Atom

Quantum Mechanics: The allowed energy levels for an atom are discrete (2 electrons can occupy a state since with opposite spin)

When atoms are brought into close contact, these energy levels split

If there are a large number of atoms, the discrete energy levels form a “continuous” band

Ene

rgy

E1

E2

...E3

Forbidden Band Gap

AllowedEnergyLevels

Lattice ConstantAtomic Spacing



Energy Band Diagram

The gap between the conduction and valence band determines the conductive properties of the material

Metal– negligible band gap or overlap

Insulator – large band gap, ~ 8 eV

Semiconductor– medium sized gap, ~ 1 eV

Valence Band

Conduction Band

Valence Band

Conduction Band

e-

Electrons can gain energy from lattice (phonon) or photon to become “free”

band gap

e-



Model for Good Conductor

The atoms are all ionized and a “sea” of electrons can wander about crystal:

The electrons are the “glue” that holds the solid together Since they are “free”, they respond to applied fields and

give rise to conductions

+ + + + + + + +

+ + + + + + + +

+ + + + + + + +

On time scale of electrons, lattice looks stationary…



Bond Model for Silicon (T=0K)

Silicon Ion (+4 q)

Four Valence ElectronsContributed by each ion (-4 q)

2 electrons in each bond



Bond Model for Silicon (T>0K)

Some bond are broken: free electron Leave behind a positive ion or trap (a hole)

+

-



Holes?

Notice that the vacancy (hole) left behind can be filled by a neighboring electron

It looks like there is a positive charge traveling around! Treat holes as legitimate particles.

+-



Yes, Holes!

The hole represents the void after a bond is broken Since it is energetically favorable for nearby

electrons to fill this void, the hole is quickly filled But this leaves a new void since it is more likely

that a valence band electron fills the void (much larger density that conduction band electrons)

The net motion of many electrons in the valence band can be equivalently represented as the motion of a hole

BandFilled StatesEmpty

iivb

ivb vqvqvqJ )()()(

StatesEmpty

iStatesEmpty

ivb qvvqJ )(



More About Holes

When a conduction band electron encounters a hole, the process is called recombination

The electron and hole annihilate one another thus depleting the supply of carriers

In thermal equilibrium, a generation process counterbalances to produce a steady stream of carriers



Thermal Equilibrium (Pure Si)

Balance between generation and recombination determines no = po

Strong function of temperature: T = 300 oKoptth GTGG )(

)( pnkR

RG )()( TGpnk th

)(/)( 2 TnkTGpn ith

K300atcm10)( 310 Tni



Doping with Group V Elements

P, As (group 5): extra bonding electron … lost to crystal at room temperature

+

ImmobileCharge

Left Behind



Donor Accounting

Each ionized donor will contribute an extra “free” electron

The material is charge neutral, so the total charge concentration must sum to zero:

By Mass-Action Law:

000 dqNqpqn

Free Electrons

Free Holes

Ions(Immobile)

)(2 Tnpn i

00

2

0 di qN

n

nqqn

0022

0 nqNqnqn di



Donor Accounting (cont)

Solve quadratic:

Only positive root is physically valid:

For most practical situations:

2

4

0

22

0

20

20

idd

id

nNNn

nnNn

2

4 22

0idd nNN

n

id nN

ddd

idd

NNNN

nNN

n

222

412

0



Doping with Group III Elements Boron: 3 bonding electrons one bond is unsaturated Only free hole … negative ion is immobile!

-



Mass Action Law

Balance between generation and recombination:

2ioo nnp

• N-type case:

• P-type case:

)cm10,K300( 310 inT

dd NNn 0

aa NNp 0

d

i

N

nn

2

0

a

i

N

np

2

0



Compensation Dope with both donors and acceptors:

– Create free electron and hole!

+

-

-

+



Compensation (cont.)

More donors than acceptors: Nd > Na

iado nNNn

• More acceptors than donors: Na > Nd

ado NN

np i

2

idao nNNp da

o NN

nn i

2



Thermal Equilibrium

Rapid, random motion of holes and electrons at “thermal velocity” vth = 107 cm/s with collisions every c = 10-13 s.

Apply an electric field E and charge carriers accelerate … for c seconds

zero E field

vth

positive E

vth

ac

(hole case)

x

kTvm thn 212*

21

cthv

cm1010/cm10 6137 ss



Drift Velocity and Mobility

Ev pdr

Em

q

m

qE

m

Fav

p

cc

pc

p

ecdr

For electrons:

Em

q

m

qE

m

Fav

p

cc

pc

p

ecdr

For holes:

Ev ndr



“default” values:

Mobility vs. Doping in Silicon at 300 oK

1000n 400p

Lecture 6: Integrated Circuit Resistors

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