1. PLASMA ETCHING OF EXTREMELY HIGH ASPECT RATIO FEATURES:
TWISTING EFFECTS*
Mingmei Wanga), Ankur Agarwalb), Yang Yanga) and
Mark J. Kushnera)
a)Iowa State University, Ames, IA 50011, USA
b)University of Illinois, Urbana, IL 61801, USA
60th Gaseous Electronics Conference, October 2007
*Work supported by Micron Technology Inc., SRC and NSF

2. Optical and Discharge Physics
AGENDA
High Aspect Ratio Contact (HARC) Etching
Approach and Methodology
Charging of features
Fluorocarbon etching of HARC
SiO2-over-Si etching
Potential
Effect of open field
Concluding Remarks
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_AGENDA

3. Optical and Discharge Physics
HARC ETCHING: ISSUES
As aspect ratio (AR) of features increases, complexity of plasma etching increases.
Aspect Ratio Dependent Etching
Etch rate decreases with increasing AR.
Charging of features due to ion and electron bombardment.
Electric field variations affect ion trajectories; deviation from ideal profile.
Non-uniform ion flux despite uniform bulk plasma.
As AR increases, the cross-sectional area of each via is smaller.
Increasingly random nature of incident ions and radicals.
Ref: Micron Technology, Inc.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_01

4. OBJECTIVES AND APPROACH Optical and Discharge Physics
Computationally investigate consequences of charging of high aspect ratio features in SiO2.
Approach
Reactor scale: Hybrid Plasma Equipment Model.
Feature scale: Monte Carlo Feature Profile Model.
Poisson’s equation is solved for electric potentials.
Acceleration of ions and electrons due to electric fields in feature.
Dissipation of charge through material conductivity.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_02

5. HYBRID PLASMA EQUIPMENT MODEL (HPEM) Optical and Discharge Physics
Electromagnetics Module: Antenna generated electric and magnetic fields
Electron Energy Transport Module: Beam and bulk generated sources and transport coefficients.
Fluid Kinetics Module: Electron and Heavy Particle Transport, Poisson’s equation
Plasma Chemistry Monte Carlo Module:
Ion and Neutral Energy and Angular Distributions
Fluxes for feature profile model
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_04

6. MONTE CARLO FEATURE PROFILE MODEL Optical and Discharge Physics
Monte Carlo techniques address plasma surface interactions and evolution of surface morphology and profiles.
Inputs:
Initial material mesh
Surface reaction mechanism
Ion and neutral energy and angular distributions.
Ion and radical fluxes at selected wafer locations.
Maxwellian electron fluxes with Lambertian distribution
Fluxes and distributions from HPEM.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_05

7. MCFPM: CHARGING ALGORITHMS Optical and Discharge Physics
The electric potential is solved using the method of Successive Over Relaxation (SOR).
Large mesh sizes pose computational challenges to solve for potential after launch of each particle.
Electric field is being updated after the launch of every 30 charged particles.
Particles are a few nm on a side.
Total particles launched (ions and radicals): 150, ,000.
The charge of pseudo-particles mesh is adjusted to account for finite sized particles.
Charged particle - - -
Mask - - - - + + - + - + +
SiO2 + + + + + Si
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_03

8. FLUOROCARBON PLASMA ETCHING OF SiO2/Si Optical and Discharge Physics
CFx radicals produce polymeric passivation layers which regulate delivery of precursors and activation energy.
Chemisorption of CFx produces a complex at the oxide-polymer interface
Low energy ion activation of the complex produces polymer.
Polymer complex sputtered by energetic ions  etching.
As SiO2 consumes the polymer, thicker layers on Si slow etch rates enabling selectivity.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_06

9. FLUOROCARBON ETCH OF HARC Optical and Discharge Physics
Dual frequency capacitively-coupled (CCP) reactor geometry.
Base case conditions:
Ar/C4F8/O2 = 80/15/5, 300 sccm
40 mTorr
500 W at 25 MHz
4000 W at 10 MHz
Low frequency: Substrate
High Frequency: Showerhead
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_07

10. Optical and Discharge Physics
REACTANT FLUXES
10 mTorr, HF 500 W, LF 4 kW, Ar/C4F8/O2 = 80/15/5, 300 sccm
Dominant Ions: Ar+, CF2+, C2F4+, CF+
Dominant Neutrals: CF2, C2F4, CF, CF3, F
Polymer clearing fluxes
O = 3  1016 cm-2.s-1
O+ = 3  1014 cm-2.s-1
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_08

11. ION ENERGY ANGULAR DISTRIBUTIONS (IEADs) Optical and Discharge Physics
IEADs for sum of all ions.
Peak in ion energy increase with increasing bias power.
High ion energies required for etching of HAR features.
Narrow angular distribution reduce sidewall impacts.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 10 MHz, HF 500 W.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_09

12. SiO2-over-Si HARC ETCH: NO CHARGING Optical and Discharge Physics
Etch profile evolution without charging.
Etch rate higher at higher bias powers owing to high ion energies.
No charging:
Generally straight profiles.
High ion energies  low polymer coverages.
Some evidence of randomness due to small contact area
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, 10 MHz, HF 500 W.
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_10

13. SiO2-over-Si HARC ETCH: EFFECT OF CHARGING
Charging effects are considered:
Charge buildup on polymer affects plasma potential.
Ion trajectories influenced by electric-field.
Electrons neutralize charge deep in trench.
Lower ion energies (due to buildup of charge)
Lower etch rates.
Deviation from “ideal” anisotropic etch profiles.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, 10 MHz, HF 500 W.
Animation Slide
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_11a

14. SiO2-over-Si HARC ETCH: EFFECT OF CHARGING
Charging effects are considered:
Charge buildup on polymer affects plasma potential.
Ion trajectories influenced by electric-field.
Electrons neutralize charge deep in trench.
Lower ion energies (due to buildup of charge)
Lower etch rates.
Deviation from “ideal” anisotropic etch profiles.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, 10 MHz, HF 500 W.
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_11b

15. SiO2/Si HARC ETCH: PLASMA POTENTIAL Optical and Discharge Physics
116 V
151 V -3 -6 -4
110 V
Max
Min
213 V -5
Charge deposition on polymer affects plasma potential.
Small depths:
Electrons effectively neutralize charge buildup.
Potential essentially maintained at zero.
Large depths:
Trapping of charge in polymer perturbs ion trajectories.
Electrons are “pulled” into bottom of trench by large positive potential and neutralizes. -6
213
AR = 1:10
Iowa State University
Optical and Discharge Physics
Increasing Power
Animation Slide
MINGMEI_GEC07_12a

16. SiO2/Si HARC ETCH: PLASMA POTENTIAL Optical and Discharge Physics
Max
213 V
116 V
151 V
110 V
Charge deposition on polymer affects plasma potential.
Small depths:
Electrons effectively neutralize charge buildup.
Potential essentially maintained at zero.
Large depths:
Trapping of charge in polymer perturbs ion trajectories.
Electrons are “pulled” into bottom of trench by large positive potential and neutralizes.
Min -5 -3 -6 -4 -6
213
AR = 1:10
Increasing Power
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_12b

17. SiO2-over-Si HARC ETCH: RANDOMNESS? Optical and Discharge Physics
Monte Carlo modeling utilizes random number generator to simulate a physical process.
Different seed numbers
All other conditions are same.
Is it reproducible?
No charging effects:
Etch profiles vary little
Anisotropic etch
No anomalies observed
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Different seed numbers
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_13

18. SiO2/Si HARC ETCH: RANDOMNESS OF CHARGING?
Different seed numbers
All other conditions are same.
Is it reproducible?
Charging effects:
Stochastic nature of incident ion fluxes reflected in profiles.
Twisting observed
Etch direction shifts which reinforces anomoly.
Some unphysical behavior also observed (last trench)
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Different seed numbers
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_14

19. SiO2/Si HARC ETCH: RANDOMNESS OF CHARGING?
6 Trenches receiving “same fluxes.
Stochastic nature of fluxes produces random twisting.
Similar behavior observed experimentally.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Ref: Micron Technology, Inc.
Aspect Ratio = 1:10
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_15

20. EFFECT OF OPEN FIELD: NO CHARGING Optical and Discharge Physics
4 trenches followed by a “plasma-only” region with hard mask.
Open field has large sidewall polymerization.
Charging not considered
Trenches have some randomness in profiles owing to non-uniform ion fluxes.
No effect due to plasma-only region.
Aspect Ratio = 1:10
Iowa State University
Optical and Discharge Physics
Animation Slide
MINGMEI_GEC07_16a

21. EFFECT OF OPEN FIELD: NO CHARGING Optical and Discharge Physics
4 trenches followed by a “plasma-only” region with hard mask.
Open field has large sidewall polymerization.
Charging not considered
Trenches have some randomness in profiles owing to non-uniform ion fluxes.
No effect due to plasma-only region. I II
III IV
Aspect Ratio = 1:10
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_16b

22. EFFECT OF OPEN FIELD: EFFECT OF CHARGING Optical and Discharge Physics
Open field can impact etch of adjacent trenches by trapping of charge in polymer.
Transverse electric fields from external charge significantly affects adjacent trenches.
Inner trenches less affected by charging.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Animation Slide
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_17a

23. EFFECT OF OPEN FIELD: EFFECT OF CHARGING Optical and Discharge Physics
Open field can impact etch of adjacent trenches by trapping of charge in polymer.
Transverse electric fields from external charge significantly affects adjacent trenches.
Inner trenches less affected by charging.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W. I II
III IV
Aspect Ratio = 1:10
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_17b

24. OPEN FIELD EFFECT ON CHARGING Optical and Discharge PhysicsII
Open field impacts adjacent trenches by transverse electric field from trapped charged in polymer.
Isolating open field by making spacer of SiO2 thicker reduces transverse fields and perturbation of etch profiles.
Smaller deviation for the adjacent trench.
Note effect of stochastic ion fluxes in second trench.
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_18

25. COMPUTATIONAL ASPECTS: DISSIPATION OF CHARGE
Dissipation of charge accounted for through material conductivity
I: Static charge
II: Only electron charges move
III: Both ion and electron charges move
Positive charges inside materials leads to high potentials inside the trench
Lower ion energies  polymer deposition
Etch stop observed
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_20

26. ELECTRIC FIELDS: BOUNDARY CONDITIONS Optical and Discharge Physics
Boundary conditions for Poisson’s equation: Zero potential at mesh boundaries.
Both electron and ion charges move
Small mesh:
Unphysical high gradients in fields
Leads to etch stops
Wide mesh:
Gradients in fields relaxed
Etch progresses to completion
Higher conductivity  less effect of charging
10 mTorr, Ar/C4F8/O2 = 80/15/5, 300 sccm, LF 4 kW, HF 500 W.
Iowa State University
Optical and Discharge Physics
Aspect Ratio = 1:10
MINGMEI_GEC07_21

27. Optical and Discharge Physics
CONCLUDING REMARKS
Etching of high aspect ratio contacts (HARC) has been computationally investigated in fluorocarbon plasma.
Charging of features has been included to investigate anomalies such as twisting observed during etching of HARCs.
Charge buildup in/on polymer layer decreases etch rates and deviates the etching profile.
Ultimately a stochastic process for small features.
Various factors affect etching profiles:
Special structures like open field.
High energy ions may mitigate the effect of charging.
Charge dissipation due to material conductivity.
Iowa State University
Optical and Discharge Physics
MINGMEI_GEC07_22