3.155J/6.152J Lecture 10: Lithography – Part 13.155J/6.152J Lecture 10: Lithography – Part 1 Prof. Martin A. Schmidt Massachusetts Institute of Technology 10/8/2003

3.155J/6.152J Lecture 10: Lithography – Part 1

Prof. Martin A. Schmidt

Massachusetts Institute of Technology

10/8/2003

Outline

The Lithographic Process Basic Process

Definitions

Fundamentals of Exposure

Exposure Systems

Resists

Advanced Lithography

Recommended reading Plummer, Chapter 5

Other: Campbell, Chapter 7,8,9

Fall 2003 – M.A. Schmidt 3.155J/6.152J – Lecture 10 – Slide 2

IC Process

Circuit Design Process Simulation Device Simulation

Layout BOXES

Mask Shop

Design Rules

Wafers Wafer Fab


An idea A file

Wafer Fab - Lithography

Most Common Measure of Complexity # of Masks, Minimum Feature (examples)

Approximately 50% of the Process Steps

Litho Etch Oxidation/Deposition Litho Etch Implant

Anneal Metal DepositionLitho Etch Litho Etch Sinter

Oxidation

Drives Infrastructure Cleanliness

Vibration

Temperature and Humidity


Semiconductor Roadmap


Pattern Transfer Steps

Mask

Coat with photoresist

Develop

Strip resist

Expose

Etch*

*Wet etch


Definitions

Metrics Resolution

Throughtput

Registration (Alignment)

Exposure Systems - UV Projection - Fraunhofer

Proximity - Fresnel

Contact - Fresnel

Advanced

DUV, E-Beam, X-Ray, Nano-imprint

Resists Positive/Negative

Contrast

CMTF


Lithography Systems

Proximity Contact Projection

Mask

Wafer


Contact/Proximity Printing


Contact/Proximity Printing


Applies when < g < W2/

Minimum resolvable feature = ( g)1/2

Proximity Printing Limits

Minimum resolvable feature = ( g)1/2

Gap = 20 m and Source = 436 nm

3.0 m


Projection Printing


Image from a Circular Opening

Note limit of d Fall 2003 – M.A. Schmidt 3.155J/6.152J – Lecture 10 – Slide 13

Resolving Features


: When the peak of one projection lands on the first zero of the other.

Rayleigh Limit

Rayleigh Criterion

S. Wolf, Microchip Manufacturing, Lattice Press


R

n=1 (air)

The Rayleigh Criterion

R = 1.22 f/d = 1.22 f/n(2fsin ) = 0.61 /nsin

NA = nsin Range from 0.16-0.76 )

R = 0.61 /NA = k1 /NA (practical k1 = 0.6-0.8)


Modulation Transfer Function (MTF)


Inte

nsi

ty

Inte

nsi

ty

Modulation Transfer Function (MTF) Mask

MTF =

Imax - Imin

Distance Imax + IminWafer

Imax

Imin

Fall 2003 – M.A. Schmidt Distance 3.155J/6.152J – Lecture 10 – Slide 18

MTF vs Feature Size


Depth of Focus

f

d

/4 = - cos

Small : /4 = 2/2

= sin = d/2f = NA

Depth of Focus = = /2(NA)2

= k2 /(NA)2

R = 0.61 /NA = k1 /NA


Resist Contrast Dose = Intensity (W/cm-2) x time (s)

Positive Negative

Develo

ped T

hic

kness

Q0

Qf

Develo

ped T

hic

kness

Q0

Qf

Exposure Dose (log scale) Exposure Dose (log scale) mJ cm-2 mJ cm-2

= 1 / log10(Qf/Q0)


Ideal Exposure – Ideal Resist

Dose

Distance

Resi

st T

hic

kness

Distance


Dose

Qf

Real Exposure – Ideal Resist

Distance

Resi

st T

hic

kness

Increase Time


Dose Qf

Q0

Real Exposure – Real Resist

Distance

Resi

st T

hic

kness

Increase Time

Decrease Contrast


Decreasing ‘Pitch’ D

ose

Qf

Q0

Dose

Distance Distance

Resi

st T

hic

kness

Resi

st T

hic

kness

Distance


Critical Modulation Transfer Function (CMTF) D

evelo

ped T

hic

kness

Q0

Qf

Q

CMTF =

f – Q0 10 – 1 =

Qf + Q0 10 + 1

If = 3, CMTF = 0.37= 1 / log10(Qf/Q0)

If = 2, CMTF = 0.52


Effect of Coherence on MTF

CMTF

CMTF


Documents

3.155J/6.152J Lecture 10: Lithography – Part 13.155J/6.152J Lecture 10: Lithography – Part 1 Prof. Martin A. Schmidt Massachusetts Institute of Technology 10/8/2003