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PNV @ Lyonimec for WP3
confidential
2
Cells structures and process flows
confidential
1. Epifree
2. PolySi
3. Epifoils
3
Material
EpifreeMicron-thin mono c-Si on foreign substrate
Formation of macropores
Annealing at high temperature
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A simple solar-cell process
1. Film formation by annealing
2. (Surface passivation)
3. Aluminium deposition: rear-contact
4. Bonding and detachment: anodic bonding
5. Heterojunction emitter formation:
i/n+ a-Si and Indium Tin Oxide deposition
6. Ti/Pd/Ag top contacts evaporation
7. Si etching for cell definition
Fragile material!
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EpifreeHeterojunction cell
Substrate
Alc-Si / p-type
i/n+ a-Si / ITOAg
ITO - 75 nmn+ a-Si - 12 nm
i a-Si - 12 nm
p c-Si - 1.1 µm
p++ c-Si - 25 nm
Emitter:
Base:
BSF:
5 cm x 5 cm glass substrate
1 cm x 1 cm cell
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Substrate
Thin film c-Si solar cell
~ 100 nm
Substrate
Seed layer formation(crystalline)
Substrate
Non-Si substrate
Epitaxial growth
Substrate
3-10 µm
PolySiThin-film c-Si layers on non-Si substrates
(here) By: Al induced crystallisation
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PolySiHeterojunction cell
ITO - 75 nmn+ a-Si - 12 nm
i a-Si - 12 nm
p c-Si - 3 µm
p+ c-Si - 500 nmp++ c-Si - 250 nm
Emitter:
Base:
5 cm x 5 cm
alumina substrate
1.1 cm x 1.1 cm cell
aluminaFOx - 100 nm Rear:
Ag
Substrate
p++ c-Sic-Si
a-Si/ITOAl
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PolySi on alumina substrateCross section view
FOxSi seed for epi (actual layer is thicker)
Alumina
1 µm
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Roughness of poly
1 µm 2 µm
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10© IMEC 2013/ CONFIDENTIAL
Epi on porous Si for transfer to glass
epitaxial n-type base
(in-situ)
epi p emitter
parent substrate
epi p+
Low-porosity layer
Separation layer(high porosity layer)
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Epifoils – Final targetInterdigitated back-contacts, epi rear-emitt er
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silicone
Ti/Al
EPI c-Si: n
SiNx ARC
EPI c-Si: n+
EPI c-Si: p+
a-Si: iSiOx
a-Si: n+
glass
SiO2
Ti/Al
Front-side: High temperature processes
Rear-side: Low temperature processes
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Epifoils – Current workTwo-side contacted cell - easier
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Front-side: High temperature processes= our IBC 23% cells
silicone
EPI c-Si: n
SiNx ARC
DIFFUSED c-Si: n+
EPI c-Si: p+
glass
SiO2
Metal
Metal (Al or Ti)
a-Si: iSiOx
Rear-side: • a-Si passivation of emitter• PECVD SiO2 reflector• Metal contact
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n base
Current epifoils: another (textured) view
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p+ emitter passivation
passivationARC
Now:Random pyramids
Future:Nanopatterning!
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1st Cell results
1 µm epifreeTrends
3.5 µm polySi
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Cell results: 1 µm c-Si
Texturing Jsc (mA/cm2)
Voc(mV)
η(%)
No 12.6 471 4.3
NIL 15.3 435 4.8
• 22% increase in current
• Voc decreased due to passivation and plasma damage
• Increased efficiency
The nanopattern was integrated
successfullyC. Trompoukis et al., Appl. Phys. Lett. 101, 103901 (2012)
Non optimized pattern
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PNV final aim: 30
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Trends – 4 runs statistics
RUN Jsc Voc FF Eta4 13.3 325 57 2.454 NIL 14.8 260 66 2.543 14.1 282 56 2.23 NIL 14.5 247 64 2.32 12.5 281 60 2.12 NIL 16.2 246 59 2.31 7.4 489 56 2.01 NIL 12.3 492 67 4.1
Increase in current due to better light trapping Decrease in voltage due to plasma damage Overall increase in efficiency
Same trends for all 4 runs so far when adding nanopattern
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Cell results: 3-5 um polySi
Texturing Jsc (mA/cm2)
Voc(mV)
η(%)
No 18.1 411 4.5
NIL 21.0 406 5.1
• 15% increase in current
• Voc reduced
• Increased efficiency
Glass
1 μm c-Si (p-type)Al
Ag i/n+ a-Si / ITOAl
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PNV final aim: >30
nanophotonics for ultra-thin crystalline silicon photovoltaics
project 309127
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Epifree
ITO
Silicon
Al contact
Substrate
a-Si
Cell techno: Substrate + mesa + no optical spacer on the back, Si on Al directly. Heteroj.Ref: what exists (PiPV Valerie)During the project: optimise structure, supertrate, spacer...
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PolySi
Alumina (granular, looks like white paint, 1mm thick) + a flowable oxide (Fox)
Or Si\SiO2
3 μm c-Si (p-type)
Al
Ti\Pd\Ag
i/n+ a-Si (10+10nm)/ ITO (75nm?)
Al
Interdigitated (every ~500microns)200nm c-Si (p++type)
Techno: substrate is Alumina+ Fox or Si/SiO2 + Poly (high and low dopings) + HeteroJRef: CSG, see paper attached.During the project: probably no structure change.
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n-type Si
p+
+n
SiO2
Silicone~70nm PECVD SiNx~10nm thermal oxideFSF
Emitter~120nm thermal oxideMEtal
BSF i/n+ a-SiMEtal
Epifoils: goal, ibc like
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n-type Si
Front: FSF diffused on n-type epilayer, random pyramids covered with ~10nm thermal oxide, ~70nm PECVD SiNxcontactsSilicone
Rear side: a-Si passivation with oxide reflector and contacts through holes.Al (either Pfeiffer or Leybold), or Ti/Al (Pfeiffer)
Epifoils: presently
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PNV @ LyonLPICM for WP3
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Outline
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1. Epifree
2. PolySi
3. Epifoils
4. PECVD epitaxy
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Process Flow and cell architecture
• PECVD epitaxy
• Stress induced lift off
• Final stack
(i)+(p) or (n) aSi:H
Epi-Si (~ 3µm)
(i)+(n) or (p) aSi:H
Metal mirror
Glass
(i)+(p) or (n) aSi:H
Epi-Si (~ 3µm)
(p) Or (n) Epi-Si
Metal mirror
Glass
a) Metal evap. on epi-si
b) Glued to transfer substrate
c) Mechanical and thermal stress (~ 400-500°C)
- HF or in situ c-Si (100) wafer surface cleaning- SiH4/H2 PECVD epitaxy 175°C
C-Si wafer
Epi-SiFragile interface
26
Material Characterization
FWHM 5,3 cm-1 by Raman for 2,5 µm ELO layer
RMS ~ 1,1 nm
1,1 nm RMS roughness for6 µm ELO Si 6µm epi-Si
(i)aSi:H/(n)aSi:H
Kapton
• Low roughness and good crystal quality is kept through the lift off process
27confidential
Electrical properties under study
First life time confirms material quality
Effective life time by Time Resolved Microwave Conductivity
Setup
epi-Si (~3,2µm)
N+ asi:H
Kapton tape
Few tens of µs decay time
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Transferred epi-PECVD diode: preliminary results
ITO
(i)aSi:H/(n+)a-Si:H
2,5 µm (i)epi-Si
Al
PDMS/Glass• Jo ~ 1e-9 mA/cm2
• n ~ 4
0,03 cm2