Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 1
Modeling Dye Sensitized Solar Cells Based onNano-Tubes or Nano-Rods - A New Transmission
Line Approach
C. Böhmer a, F. Richter a, C.A. Schiller a,*, P. Schmuki b
a ZAHNER-elektrik, Thüringer Str. 12, 96317 Kronach, Germany* corresponding author: [email protected], phone +49926196211924
a Department of Materials Science and Engineering, WW4-LKO, University ofErlangen-Nürnberg, Martensstraße 7, 91058 Erlangen, Germany
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 2
Outline
A short reminder on the DSSC principle.
Traditional treatment of frequency spectra from DSSCin literature: modeling is based on continuum theory.
The alternative: consideration of the DSSC porousstructure - the approach from K. West and L. Bay.
The homogeneous pores model by H. Göhr and itsrecent photo-electrochemical expansion.
Experimental: EIS-, CIMPS & CIMVS characterizationof thin film DSSC based on TiO2-nanotube electrodes.
The application of the new model to the experimentalresults.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 3
The DSSC Basics In Dye Sensitized Solar Cells, DSSC, the electrons generated by
photon absorption inside the dye molecules appear at the surface ofthe semi-conducting oxide material and mostly not in direct vicinity tothe current collecting photo-anode.
Barrier layer Light
SnO2:F
Glass
TiO2
Pt
Acetonitrile
x
x3
The efficiency of a DSSC suffers from the competition between chargetransport- and loss processes of the photoelectrons on the way fromthe site of generation to the electrical contact.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 4
Highly Ordered Oxides - The Solution?
Photograph of the thinfilm DSSC based onTiO2-nano-tubes builtfor testing.
1 cathode: FTO covered with Pt
2 dye loaded TiO2 nano-tubes ofdifferent length in I-/I3
- containingelectrolyte.
3 Ti-foil as oxide carrier and anode
a) Schematic of the high-E-field (voltage 100V)anodization procedure. Electrolyte was based onethylene glycol, containing 0.5M HF [1].
b) Sketch of the TiO2 nano-tube layer on Ti.
c) Scheme of the self organizing process controlled bythe competition of anodic formation and F--inducedetching of TiO2 [2].
[1] R. Beranek, H. Hildebrand, P. Schmuki, Self-organized porous titanium oxide prepared inH2SO4 / HF electrolytes, Electrochem. Sol. State Lett. 6 (3), B12 (2003).[2] A. Ghicov, P. Schmuki, Self-ordering electrochemistry: a review on growth and functionality ofTiO2 nanotubes and other self-aligned MOx structures, Chem. Commun. 20 (2009) 2791.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 5
The Traditional Modeling Approach
Intensity Modulated Photo Spectroscopy of current, IMPS, and voltage, IMVS,are popular techniques for the investigation of the DSSC dynamic efficiency.They are usually interpreted in terms of electron diffusion- and recombinationtime constants (see for instance [3]).
[3] J. Bisquert, V.S. Vikhrenko, Interpretations of the Time Constants Measured by Kinetic Techniquesin Nanostructured Semiconductor Electrodes and Dye-Sensitized Solar Cells, J. Phys. Chem. B 108(2004) 2313-2322.
For the theoretical derivation, generation, transport and recombination are puttogether in form of a continuity equation. The differential equations are solvedaccording to the actual boundary conditions (see for instance equ. 1-3 [4]).
[4] J. Krüger, R. Plass, M. Grätzel, P. J. Cameron, L. M. Peter, Charge Transport and Back Reaction inSolid-State Dye-Sensitized Solar Cells: A Study Using Intensity-Modulated Photovoltage andPhotocurrent Spectroscopy, J. Phys. Chem. B 107 (2003) 7536-7539.
The porous distributed nature of such systems is not considered explicitly.Instead, „effective“ (due to electron “trapping”) diffusion coefficients are used.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 6
Porous Photo Electrode Models
L. Bay & K. West [5] developed a model which takes into account thedistribution of photocurrent generation and loss along the chainladder, built from the porous network of oxide and electrolyte.
[5] L. Bay, K. West, An equivalent circuit approach to the modeling of the dynamics of dye sensitizedsolar cells, Solar Energy materials and Solar Cells, 87 (2005) 613.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 7
Porous Photo Electrode Model by Bay & West
Expression for the dynamic photo voltage U found by Bay & West [5]
[5] L. Bay, K. West, An equivalent circuit approach to the modeling of the dynamics of dye sensitizedsolar cells, Solar Energy materials and Solar Cells, 87 (2005) 613.
lA
lAi
el
Al
A
l
Al
Ae
A
RABU
)sinh()coth(1
)sinh()coth(1
22
qie ZRR /2
after [5], Equ. 9
(Re, Ri: electronic and ionic resistance [cm], B: quantum efficiency, A: absorption coefficient [cm-1],l : porous system depth [cm], : shortcut using , [] = cm-1) with the photo-electrochemical active surface impedance Zq. In equivalence to the continuum model diffusioncoefficient Dn and recombination time constant n are found to . 1
eiqn RRCD qqn CR
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 8
Application of the Bay & West Model on an IsolatedNanotube Photoanode
[6] C.-A. Schiller, Optimierung der dynamischen Transferfunktionsanalyse für die Impedanzspektroskopie und dieintensitätsmodulierte Photospektroskopie zur Anwendung an instationären und verteilten elektrochemischenSystemen, Dissertation Erlangen, August 2012, cpt. 7.7.2.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 9
Porous Photo Electrode Models Impedance model for a homogeneous pore system [7] and its recent
photo-electrochemical expansion
[7] H. Göhr, Impedance Modeling of Porous Electrodes, Electrochemical Applications, ZAHNER-elektrik, 1,7-9 (1997), www.zahner.de/downloads/ea1997.pdf.
ELE
CT
RO
LY
TE
ME
TA
L
PORES
POROUS
LAYER
mZ
Ze
distributed
connectionsqZ
pZ
sZ
interface
PORES/LAYER
interface
PORES/METAL
interface
ELECTROLYTE
/OUTER
LAYER
SURFACE
6
5
7
41 2 3
1 electrolyte2 TiO2 + Dye3 distributed surface Zq
4 Ti metal5 current paths6 pore ground Zm
7 top area Ze
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 10
The New Porous Photo Electrode Model
Expression for the dynamic photo voltage U derived by Böhmer [8]
[8] C. Böhmer, Equivalent circuit model of the dye sensitized solar cell (DSSC) with top and bottomimpedance, unpublished.
Expression for the case ofoxide rear side illumination
q
sp
Z
ZZd
dAC
Terminology according to H. Göhr, and with B = photocurrent equivalent to the total photon count/s,photon absorption C and layer thickness d of the porous system,photon absorption Aa and layer thickness a of pore ground or mouth
Aa
p
sCp
me
sp
me
sp
m
sp
p
sAaCAae
sp
e
sp
p
sAaAam
sp
P
eZ
Ze
C
ZBC
ZZZZ
ZZ
ZZ
Z
ZZ
Z
Zee
C
Z
ZZC
C
Z
ZZ
Z
Zee
C
Z
ZZC
CZBU
22
2
2
22
22
)cosh(11
)sinh(/
)sinh()cosh(1
)sinh()cosh(1
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 11
Typical Results of the Dynamic Measurements
From left to right: EIS-, CIMPS- and CIMVS spectra (modulus) ofthin film DSSC based on TiO2-nanotubes of different tube length l.Measurement was performed at the maximum power point biasunder 400 W/m2 white light illumination after hours of settling.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 12
A Typical Fitting Result Using the Recent Model
Bode diagrams of a thin film DSSC built from 10m TiO2-nanotubes.Measurement was performed at the maximum power point bias under 400 W/m2
white light illumination. Measurement samples are shown as symbols and theTRIFIT fitting results using the new model are drawn as solid lines.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 13
Modeling & Fit
Left: Equivalent circuit used for the fit of the EIS, CIMPS and CIMVS spectra ofa thin film DSSC built from 10m TiO2-nanotubes at OCP and at the maximumpower point (400 W/m2 white light). Right: Scheme of the TRIFIT fitting errorcalculation.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 14
Discussion of the Results
Problem reproducibility: Still individual preparation differences causestatistical data scatter of a magnitude comparable to the systematicdependency from the tube length.
Problem load dependency: DC- and Dynamic measurements under loadexhibit drift: the photocurrent decreases significantly with time. Thesechanges are mostly reversible.
The initial DC as well as the dynamic efficiency under load are best for thelongest tubes.
But the relative efficiency loss is also maximal for the longest tubes: in thestationary case after hours the efficiency sequence may be even inverted.
A possible explanation could be, that the electrolyte in the pores builds upa concentration profile under load: the number of charged speciesdecreases (3I- + 2h+ I3
-) and the effective resistance of the electrolytechain ladder stringer increases. But the results from the model fittingshowed, that this effect is not sufficient to explain all of the drift:
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 15
Drift of the Equivalent Circuit Parameters vs. Time
Right: time drift of the charge transfer resistance and of the Warburgimpedance low frequency limit resistance of the counter electrode.
[9] A. Tighineanu et al. / Chemical Physics Letters 494 (2010) 260–263
Left: time drift of the pores systems electronic [8] and ionic conductivity.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 16
Significance of the Model: Change of Illumination Direction
Left: Best fit (Bode diagram, solely phase angle) of a thin film 30µm nanotube DSSCat OCP under 400W illumination – correct illumination direction. Right: The samesample but fitted using the model for inverse illumination direction.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 17
Significance of the Model: Assignment of Pore Ground- and Mouth Components
Left: Best fit (Bode diagram, solely phase angle) of a thin film 30µm nanotube DSSCat OCP under 400W illumination – correct assignment of pore mouth and pore groundnetwork. Right: The fit using the model with inverted assignment.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 18
Conclusions
The equivalent circuit model can be confirmed by the TRIFITprocedure fitting three different types of transfer functions, EIS-,CIMPS- and CIMVS, all from the same system state of the sample.
The Pt on FTO counter electrode causes most of the efficiency declinewith time of the TiO2 nanotube based thin film DSSC.
Thank You for Your Attention!
A new equivalent circuit approach allowed a clear assignment.
Generally, a model, fitting EIS-, CIMPS- and CIMVS together avoidsthe ambiguity of isolated EIS measurements and is therefore definitewith high probability.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 19
The Principle of IMPS/IMVS: Light Intensity Modulation.Besides EIS, two additional force-response couples can be used for further transfer function analysis:
n n+p+
Anode
Cathode
h•
IMPS
H*
A m2
W
WV m2
H = 1UP
H = 1IP
CU
IP
H ( ) =UP
U*
H ( ) =IP P*I*
P*
,
,
• IMPS: Dynamic photocurrent vs. intensity atconstant voltage.
The point is:Each transferfunctionemphasizesdifferent partsof the systemunder test !
EIS / IMPS / IMVS
• IMVS: Dynamic photovoltage vs. intensity atconstant current.
• EIS: Dynamic voltage vs. current at constantintensity.
W
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W
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P
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A
VH
I
UH
UPUP
IPIP
UIUI
2
*
*
2
*
*
*
*
1,
1,
11,
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 20
Comparison BetweenConventional IMPS and CIMPS
Conventional IMPS: The LED controlcurrent is used as substitute for theintensity information. The actualintensity and modulation is uncertain.
*
*
)(Intensity
currentCellH IP
*
*
)(Intensity
voltageCellHUP
*
*
)(currentLED
currentCellH IP
*
*
)(currentLED
voltageCellHUP
CIMPS: The measured intensity is used asforce signal information.The actual intensity iscontrolled with a photo-sensor at the site of thecell and regulated by means of an operationalamplifier feedback circuit.
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 21
Photo-Electrochemical Set Up
Function principle of CIMPS/CIMVS
*
*
)(Intensity
currentCellH IP
*
*
)(Intensity
voltageCellHUP
LED lightsource
280nm withphoto-sense
amplifier
PECC intersection
Zennium Electrochemical Workstation
XPOT light sourcecontrol potentiostat
(Photo sensor hiddenbehind the PECC)
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 22
Introduction (2)
Properties of the TiO2 Nano-Tubes Prepared
Böhmer, Richter, Schiller, Schmuki: A new transmission line model tailored for Dye Sensitized Solar Cells 23
The new equivalent circuit model can be confirmed by the TRIFITprocedure fitting three different types of transfer function, EIS-,CIMPS- and CIMVS, all from the same system state of the sample.
The Pt on FTO counter electrode causes most of the efficiency declinewith time of the TiO2 nanotube based thin film DSSC.
The characterization of nanotube based thin film DSSC by dynamicmethods should be continued with higher sample count andsystematic series measurements over time and load.
A new equivalent circuit approach allowed this clear assignment.
A model, which is able to fit EIS-, CIMPS- and CIMVS together avoidsthe ambiguity of isolated EIS measurements and is therefore definitewith high probability.
Thank You for Your Attention!