1Challenge the future

To do list.add extra slide about the coupling, at pressure level.Burn CD

2Challenge the future

Wafer transport and gas separation in a contact-less Spatial Atomic Layer Deposition track.

Candidate: Gonzalo Ramirez Troxler

Committee: Dr. ir. R.A.J van OstayenDr. E.H.A GrannemanProf.ir. R. Munnig SchmidtDr. R. Delfos

3Challenge the future

Outline• Introduction and motivation

• Solar Cells Market and challenges.• Solar cells, recombination velocity and passivation.• Atomic Layer Deposition

• Levitrack System• Working principle• Thesis goals: fine tuning stage.

• Modelling• Thin Film Flow• Concentration of Species

• Results• CFD model• Prototype system to measure position of wafer

• Conclusions and recommendations

4Challenge the future

IntroductionSolar Cells Market

• 1,600% growth of MW installed last decade.

• Resources depletion.

• Ecological impact.

Outlook

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Introduction

Challenge: To position Solar Cells as a major actor in the power generation scenario.

Cost Reduction and Increase efficiency.

Motivation

Surface Passivation using aluminium oxide - Al2O3

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Introduction

Levitrack: • Contact-less transportation track• Substrates levitate and layers of Al2O3 are deposited

(ALD).• High Throughput.• Low cost of construction.

LEVITECH and LEVITRACK

Levitech BV is a Dutch based company that develops novel solutions for the IC and Solar Cells Industry. Spin-off of ASM International.

7Challenge the future

IntroductionSolar cell and passivation

With silver print all rear fingers are short-circuitedand no light is transmitted though the back

With silver print all rear fingers are short-circuitedand no light is transmitted though the back

Front

Rear

Ag contacts

n++

ARC SiNx

Al lines

4444

p-Si

Al2O3

p++Al-BSF

Front Rear

Back-sheet foil

Surface Passivation increase efficiency of solar cell:

• Increase lifetime of charge carriers.

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IntroductionAtomic Layer Deposition (ALD)

Initial surface

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IntroductionAtomic Layer Deposition (ALD)

TMA reacts with hydroxyl groups

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IntroductionAtomic Layer Deposition (ALD)

TMA saturates surface.

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IntroductionAtomic Layer Deposition (ALD)

Purge using N2.

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IntroductionAtomic Layer Deposition (ALD)

H2O reacts with methyl groups and Al.

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IntroductionAtomic Layer Deposition (ALD)

H2O saturates the surface forming Al2O3.

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IntroductionAtomic Layer Deposition (ALD)

Purge using N2.

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IntroductionSpatial Atomic Layer Deposition (1)

Single Reactor Spatial ALD N2

TMAH2O

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IntroductionSpatial Atomic Layer Deposition (2)

Single Reactor 12 meter Spatial ALD

Track

Layer height: 10 nm

Time: 5 min Time: 5

min

X 5

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LEVITRACKWorking principle (1)

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LEVITRACKWorking principle (2)

0.5 mm

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LEVITRACKWorking principle (3) 156 mm

156 mm

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LEVITRACKWorking principle (4)

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LEVITRACKThesis goal: fine tuning stage.

The aim of this thesis is to study and improve this 4-m test setup, in order to demonstrate stable transport, while minimizing the

mixing of precursor gases.

• Stable transport: no damage on wafers.

• Mixing of precursors: TMA and H2O need to be always separated on space.

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Modelling

• Multiphysics• Fluid Flow• Concentration of species• Surface Chemistry• Heat transport• Structural mechanics

CFD Model

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ModellingThin film flow (1)

Navier-Stokes equations + Continuity equation.

Reynolds’ equation

Unknowns: 3 velocities and pressure.

Unknown: pressure

Assumptions:• Lubricant isoviscous.• Low Reynolds number. (Negligible

Inertia force)• Negligible body forces.

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Modelling

• Height average velocity.• N2-O2 model.• Stationary.

Concentration of species

Thin Film Flow

Concentration of Species.

One way coupling.

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Results and discussionCFD Model (1)

OutVolume

Top VolumeGap

Bottom VolumeGap

Exhaust

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Results and discussionFlat surface track: benchmark

Mixing requirement not fulfilled.

Flat surface

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Results and discussionFlat surface track: improvement to geometry

100% groove

70% groove

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Results and discussion100% grooves

Mixing requirement fulfilled.

100% grooves

.

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Results and discussion100% grooves: Flying height

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Results and discussion70% grooves

Mixing requirement not fulfilled.

Fh = 140 μm

70% grooves

.

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Results and discussionFlat surface vs. 100% grooves

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Results and discussionFlat surface vs. 70% grooves

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Results and discussionGrooved surface track (5)

No Groove

70% Groove 100% Groove

Mixing Requirement

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LEVITRACKThesis goal: fine tuning stage.

The aim of this thesis is to study and improve this 4-m test setup, in order to demonstrate stable transport, while minimizing the

mixing of precursor gases.

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Results and discussion

• Design system to measure separation of the of the wafer to the lateral wall.

Lateral gap measurement system (1)

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Results and discussionLateral gap measurement system (2)

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Conclusions and recommendations

It was developed:

• Fast and accurate enough CFD model to predict the pressure profile and spread of precursors inside the track.• As reference 3d NS model takes 2 day per model, while

the thin film flow model 10-20 minutes.

• System to measure the lateral gap.• Submitted to be patented.

It was found:

• Alternative geometry, which fulfils the mixing requirement.

Conclusions

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Conclusions and recommendations

• Include dynamics of the wafer in the model.

• Implement and study lateral stability with proposed measurement system.

• Integration of the deposition process to the model.

Recommendations

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Back Up slides

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Back up slidesSolar cell and passivation (1)

+

-

+ ++ ++ + ++ +

----- ----

1.- N-type and P-type junction together.2.- Creation of the depletion region.3.- Light adsorbed by the silicon.4.- Creation of electron-holes pairs.

-

+5.- Hole->p-type. Electron->n-type Electron-hole pair tries to recombine.6.-Electrones conducted.

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P1 systemWorking principle (4)

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Modelling Analytical model

• A negative pressure difference decrease the wafer velocity.

• 0.1 mbar 20% reduction of expected velocity.

• Analytical model developed in Levitech.

• Simple approach.

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Model ValidationModel validation (1)

7 mbar

3 mbar

5 mbar

10 mbar

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Model ValidationModel validation (2)

1 8 10 12 30

• Velocity: 0 [m/s]:• Row 8: in front of the

wafer.

• Row 10: on the edge of the wafer.

• Row 12: Below the wafer.

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Model ValidationModel validation (3)

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Results and discussion

• Channel effect.• Load asymmetry

• Variation of the flying height (100μm).

• Reduce transportation velocity.• Needs to be further studied in the

functional prototype.

Summary of grooved geometry

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Results and discussionLateral gap measurement system (3)