Nonplanar Metallization - University of California, Berkeleyee143/sp06/lectures/Lec_18.pdf ·...

Professor N Cheung, U.C. Berkeley

Lecture 18EE143 S06

Nonplanar Metallization

PlanarMetallization

Lecture 18EE143 S06

“Caps” and “Plugs”

The plug material can be same as interconnect material (e.g. Cu)or different material (e.g. W)

oxide oxide

Lecture 18EE143 S06

Non-Optimized Planarization example

Lecture 18EE143 S06

Five Level Metallization for Company CW plugs for contacts and viasW for metal 1, Al/Ti metal 2,3, 4; Al metal 3CMP for all dielectrics.

Good Planarization Example

Lecture 18EE143 S06

Benefits for Lithography Processes: • Lower Depth-of-Focus requirement• Reduced optical reflection effects on resist profiles • Reduced resist thickness variation over steps

Benefit for Etching Processes:• Reduced over-etch time required due to steps

Benefit for Deposition Processes:• Improved step coverage for

subsequent layer deposition

topview

Surface Planarization

Lecture 18EE143 S06

β = 1- (final step height/initial step height)

Planarization Factor β

Lecture 18EE143 S06

• Topography managementmust start at lower layers!

Planarization: A bad example

Lecture 18EE143 S06

1. Spin-on glass or polyimide

2. Deposit and Etchback

3. Chemical-Mechanical Polishing (CMP)

Planarization Techniques

Lecture 18EE143 S06

Spin-On Glass (SOG)

Lecture 18EE143 S06

SOG Annealing

• Cure:• 400-500oC -> inorganic backbone polymer

– exact composition depends on SOG type

• 800-1100oC -> densified glass (inorganic SOGs)• can be performed in N2, O2 or steam

– steam allows densification to occur at lower – temperatures

Lecture 18EE143 S06

Polymers:

• excellent thermal stability (up to 450oC)

• good dielectric properties (εr=3.3, ρ=1016 Ω-cm)

• superior chemical resistance

Polyimides

Lecture 18EE143 S06

1. Deposit thick oxide layer (600 - 1000nm)

2. Spin on resist or polymer to planarize surface

3. Etch back with a process that has equal oxide andresist/polymer etch rates(e.g. CF4 + O2 dry etch)

(4. Deposit second oxide layer)

• Simple process, requiring equipment and materialsalready available in the lab

Deposit and Etchback

Lecture 18EE143 S06

Wafer is polished using a slurry containing• silica abrasives (10-90 nm particle size)• etching agents (e.g. dilute HF)

• Backing film provides elasticity between carrier and wafer

• Polishing pad made of polyure-thane, with 1 mm perforations

– rough surface to hold slurry

Chemical Mechanical Polishing (CMP)

Lecture 18EE143 S06

CMP Configurations

Rotating waferRotating pad

Rotating WaferLinear track pad

Lecture 18EE143 S06

CMP Process Control

For reference only

Lecture 18EE143 S06

Preston Model:

Local Removal rate R = Kp P v

where P = local applied pressure v = relative pad-wafer velocity

Kp = Preston coefficient [unit in pressure-1]function of film hardness, Young’s modulus,

slurry, pad composition and structure

CMP Rate

Lecture 18EE143 S06

CMP of Selectivity to Si3N4

SiO2 6:1

poly-Si 280:1

W 75:1

Al 40:1

CMP Selectivity

Lecture 18EE143 S06

Pattern dependenceProblems encountered in CMP

Lecture 18EE143 S06

• High isolated features polish fast• Increased pressure at corners of features creates rounding

*Note :Y-axis highly magnified !!!

Pattern Dependence of CMP

Lecture 18EE143 S06

CMP Endpoint Detection - (1) PolisherMotor Current

Lecture 18EE143 S06

CMP Endpoint Detection - (2) Optical Interference

Lecture 18EE143 S06

RIE of Cu difficult due to low vapor pressure of by-products=> Cu lines formed by CMP

Cu has to be encapsulatedby a liner (e.g. TiN) to prevent out-diffusion into SiO2 and Si

CMP Application Example

Lecture 18EE143 S06

ILD = Inter-Level Dielectric

Single Damascene Process

Lecture 18EE143 S06

Dual Damascene Cu Metallization with Diffusion Barrier

Lecture 18EE143 S06

Dual Damascene Process Sequence

Lecture 18EE143 S06

Nonplanar Metallization - University of California, Berkeleyee143/sp06/lectures/Lec_18.pdf ·...

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