ARTICLE

Received 2 Feb 2015 | Accepted 4 Jun 2015 | Published 16 Jul 2015

Fei Guo1,*, Ning Li1,*, Frank W. Fecher2, Nicola Gasparini1, Cesar Omar Ramirez Quiroz1, Carina Bronnbauer1,3, Yi Hou1,3, Vuk V. Radmilovi4,5, Velimir R. Radmilovi4,6, Erdmann Spiecker4, Karen Forberich1& Christoph J. Brabec1,2,3

The multi-junction concept is the most relevant approach to overcome the ShockleyQueisser limit for single-junction photovoltaic cells. The record efciencies of several types of solar technologies are held by series-connected tandem congurations. However, the stringent current-matching criterion presents primarily a material challenge and permanently requires developing and processing novel semiconductors with desired bandgaps and thicknesses. Here we report a generic concept to alleviate this limitation. By integrating series- and parallel-interconnections into a triple-junction conguration, we nd signicantly relaxed material selection and current-matching constraints. To illustrate the versatile applicability of the proposed triple-junction concept, organic and organic-inorganic hybrid triple-junction solar cells are constructed by printing methods. High ll factors up to 68% without resistive losses are achieved for both organic and hybrid triple-junction devices. Series/parallel triple-junction cells with organic, as well as perovskite-based subcells may become a key technology to further advance the efciency roadmap of the existing photovoltaic technologies.

1 Institute of Materials for Electronics and Energy Technology (i-MEET), Friedrich-Alexander University Erlangen-Nrnberg, Martensstrasse 7, 91058 Erlangen, Germany. 2 Bavarian Center for Applied Energy Research (ZAE Bayern), Haberstrasse 2a, 91058 Erlangen, Germany. 3 Erlangen Graduate School in Advanced Optical Technologies (SAOT), Friedrich-Alexander-University Erlangen-Nrnberg, Paul-Gordan-Str. 6, 91052 Erlangen, Germany. 4 Center for Nanoanalysis and Electron Microscopy (CENEM), Friedrich-Alexander University Erlangen-Nrnberg, Cauerstrasse 6, 91058 Erlangen, Germany. 5 Innovation Center, Faculty of Technology and Metallurgy, University of Belgrade, Karnegijeva 4, 11120 Belgrade, Serbia. 6 Nanotechnology and Functional Materials Center, Faculty of Technology and Metallurgy, University of Belgrade, Karnegijeva 4, 11120 Belgrade, Serbia. * These authors contributed equally to this work. Correspondence and requests for materials should be addressed to C.J.B. (email: mailto:[email protected]

Web End [email protected] ).

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DOI: 10.1038/ncomms8730 OPEN

A generic concept to overcome bandgap limitations for designing highly efcient multi-junction photovoltaic cells

ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms8730

The power conversion efciency (PCE) of a single-junction photovoltaic cell is fundamentally constrained by the ShockleyQueisser limit1. The record efciencies of few

solar technologies, such as single-crystal silicon, CuInGaSe2,

CdTe and GaAs solar cells are constantly shrinking the gap to their fundamental efciency limits2. To push the performances of these solar technologies beyond the ShockleyQueisser limit, several approaches have been proposed, for instance, up-conversion3, multi-junction conguration46, multiple exciton generation7,8 and concentrator cells, and so on. Among them, the multi-junction concept is one of the most promising candidates that allows to simultaneously address the two dominant loss mechanisms4, namely, sub-bandgap transmission and thermalization losses, which account for 455% of the total energy of the solar radiation9.

The conventional series-connected multi-junction cells are most successful in permanently enhancing the record efciencies of the respective solar technologies2. However, one distinct drawback of the series-connected conguration is the stringent current-matching criterion, which requires careful bandgap engineering in combination with an excellent control of the thicknesses of the respective subcells. Therefore, many high-performance semiconductors with high external quantum efciency (EQE) in the NIR absorption range exhibit limited applicability for multi-junction operation, as the perfectly matching semiconductor for the front or back subcells is missing. In contrast to the series-connection, a parallel-connection does not require current matching but instead voltage matching. The principle of voltage matching also constrains a semiconductors applicability with respect to its bandgap, as well as inherently bears potential performance losses with respect to non-ideal open circuit voltages (VOC). However, the parallel-connection is more difcult to adapt and optimize for the high-performance semiconductors with non-tunable bandgaps, such as single-crystal silicon or CdTe.

In this manuscript, we present an interconnection approach as a technologically attractive solution to address all these challenges. We propose to deposit a transparent counter electrode and parallel-connect these semitransparent high-efciency cells with one or more deep NIR sensitizers as back subcells. This is a feasible approach as there are indeed several types of far NIR semiconductors like organic donors10,11 and quantum dots12,13 with an extended absorption beyond 1,000 nm. The benet of this series/parallel (SP) multi-junction design is based on the fact thatrst, the absorber layer of the front semitransparent hero cell can be made arbitrarily thick (as there is no requirement for current matching), so that this subcell can achieve almost the same efciency as the opaque single-junction reference. Second, the VOC of the back cell, which is consisting of a series-connection of deep NIR absorbers, can be custom fabricated by stacking an arbitrary sequence of semiconductors with different bandgaps in series. This strategy dramatically reduces the material requirements for voltage matching when parallel-connected to the front subcell. As a consequence, the net photocurrent gain contributed by the deep NIR subcells ultimately adds up to the overall photocurrent of the multi-junction photovoltaic cell.

In the following, we start with the demonstration of the integrated SP triple-junction cells for solution-processed organic solar cells. Optical simulations are performed to predict the efciency potential of different types of triple-junction congurations. Based on rational interface engineering, two fully solution-processed intermediate layers are successively developed, allowing effectively coupling the three cells into a SP interconnected triple-junction conguration. We then extend the concept to the recently emerging perovskite solar cells. A series-connected organic tandem solar cell absorbing photons in the NIR range is stacked in a four-terminal conguration behind a semitransparent perovskite cell. Due to the well-matched VOC

between the perovskite cell and the series-connected tandem cell,

a c

Eg,3

Eg,3

Eg,2

Eg,1

Eg,2

Eg,1

h[afii9840] h[afii9840]

PCE (%) PCE (%)

b d

16

14

3

3

14

12

2.5

12

2.5

10

E g,3(eV)

E g,3(eV)

10

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1

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1

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2

2

1

1 2

3

1

1 2

3

Eg,2 (eV)

Eg,1 (eV)

Eg,2 (eV)

Eg,1 (eV)

Figure 1 | Comparison of efciency limit for the two types of triple-junction organic solar cells. (a) Equivalent electronic circuit of the series/series (SS) triple-junction organic solar cells. (b) Three-dimensional efciency map of the SS triple-junction devices as a function of the absorbers bandgaps (Eg)

of the three subcells. (c) Equivalent electronic circuit of the series/parallel (SP) triple-junction devices. (d) Three-dimensional efciency map of the SP triple-junction organic solar cells as a function of the absorbers bandgaps of the three subcells.

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the photocurrent delivered by the organic tandem cell, up to 2 mA cm 2, directly contributes to the performance enhancement of the perovskite cell. Thus, the novel triple-junction concept demonstrated in this work provides an easy but elegant way to manufacture highly efcient photovoltaic cells, not only for conventional but also for the emerging solar technologies.

ResultsEfciency limits of triple-junction organic solar cells. There are in total four types of device congurations for a triple-junction solar cell, designated as series/series (SS, Fig. 1a), series/parallel (SP, Fig. 1c), parallel/series (PS, Supplementary Fig. 1a) and parallel/parallel (PP, Supplementary Fig. 1b). The SP and PS congurations are distinguished by the stacking sequence of the two interconnections (parallel and series) depending on which interconnection the light passes through rst. For organic solar cells, we followed the model proposed by Dennler et al.14,15 to calculate the efciency potential for the four types of triple-junction architectures as a function of the bandgaps of three absorbers. Detailed assumptions and calculation procedure are presented in the Supplementary Note 1. The outcome of the calculations showed that maximum efciencies of 17.29%,17.89%, 15.41% and 13.95% are achievable for SS, PS, SP and PP congurations, respectively. Comparing the four possible interconnections, although the SS and PS congurations demonstrate higher maximum efciencies, it is apparent that the SP and PP interconnections could offer a wider range of material combinations to reach their highest efciencies. From a practical point of view, however, the PP interconnection is too complex to process due to the necessity of introducing two transparent intermediate electrodes. Accordingly, the SP interconnection provides a more feasible approach to reach its theoretical efciency limit. Hereafter, we shall experimentally show that the SP triple-junction conguration can be fabricated with the intermediate electrode and all the semiconducting layers solution-processed.

Fabrication of bottom DPPDPP subcell. We began the fabrication of the SP triple-junction devices by designing and processing a semitransparent series-connected double-junction solar cell, as shown in Fig. 2a. We chose a diketopyrrolopyrrole-based low bandgap polymer pDPP5T-2 (abbreviated as DPP) blended with [6,6]-phenyl-C61-butyric acid methyl ester (PC60BM) as the photoactive layer of the two front subcells16,17, because the main absorption of this heterojunction extends to the near-infrared range with an absorption minimum between

450 and 650 nm (Supplementary Fig. 2). This absorption characteristic allows the transmitted photons to be absorbed by a wider bandgap top subcell. For series-connected tandem solar cells, the essential component is to construct an efcient intermediate layer serving as charge recombination zone for electrons and holes generated from subcells6,1825. Herein, we chose ZnO and neutral PEDOT:PSS (N-PEDOT) as the N- and P-type charge extraction materials, respectively, because the work functions of the two materials match well with the energy levels of the donor DPP and acceptor PC60BM20,23. The transmittance spectrum of ZnO/N-PEDOT, the rst intermediate layer, is depicted in Fig. 2b. The average transmittance of 94.2% in the range of 350850 nm ensures minimal optical losses from these interface layers. To evaluate the as-designed recombination contacts, series-connected reference tandem cells using DPP:PC60BM as two identical active layers (denoted as

DPPDPP) were rst constructed. As shown in Fig. 2c, the as-prepared opaque tandem device with evaporated Ca/Ag top electrode (15 nm/100 nm) shows a ll factor (FF) of 64.3% along with a VOC of 1.1 V being the sum of two single-junction reference cells (Table 1). These results demonstrated the excellent functionality of the ZnO/N-PEDOT intermediate layer in the series-connected tandem architecture.

Now, the challenge remains to replace the vacuum-deposited metal electrode with a solution-processed, highly transparent electrode without deteriorating the performance of the established subcells beneath. We chose silver nanowires (AgNWs) as the intermediate electrode for our triple-junction devices because of their high transparency and low sheet resistance as well as the facile solution processability2630. Our recent work demonstrated that a thin layer of ZnO nanoparticles can effectively conduct electrons to the AgNW electrode and, more importantly, enable the deposition of the AgNW electrode by doctor blading from water-based solution.16,17 However, both ZnO and AgNW layers are obviously not compact enough to protect the underlying subcells from solvent inltration during the top subcell deposition. We have, therefore, additionally introduced a thin N-PEDOT layer between the ZnO and AgNWs to realize the second intermediate layer consisting of ZnO/N-PEDOT/AgNWs (second intermediate layer). Optical transmittance spectra of this intermediate layer and the entire semitransparent tandem DPPDPP solar cell are shown in Fig. 2b. It is worth mentioning that our second intermediate layer with incorporated AgNWs exhibits an average transmittance of 84.5% (400800 nm), which is a distinct advantage over evaporated thin metal lms with low transmittance of B3050% as middle electrode in realizing parallel-connection.31,32 Noticeably, the semitransparent tandem

a b c

100

4

Transmittance (%)

Current density(mA cm2 )

AgNW

80

0

N-PEDOT

1st intermediate layer

AgNWs film

2nd intermediate layer

ST tandem DPPDPP

ZnO

60

4

DPP:PC BM

DPP:PC BM

N-PEDOT

40

8

ZnO

20

PEDOT:PSS

12

Ref. single DPP cell

Ref. tandem DPPDPP cell

Semitransparent DPPDPP cell

ITO/Glass

0 400 500 600 700 800

0.0 0.4 0.8 1.2

Wavelength (nm)

Voltage (V)

Figure 2 | Semitransparent tandem device structure and performance. (a) Schematic architecture of the semitransparent series-tandem solar cells (DPPDPP) with AgNWs top electrode. (b) Transmittance spectra of the two intermediate layers used in the SP triple-junction solar cells. (c) Typical JV curves of the single-junction DPP reference cell, tandem DPPDPP reference cell and the semitransparent tandem DPPDPP cell with AgNW top electrode. The device structure of the single and tandem reference cells are: Glass/ITO/PEDOT:PSS/DPP:PC60BM/Ca/Ag and Glass/ITO/PEDOT:PSS/

DPP:PC60BM/ZnO/N-PEDOT/DPP:PC60BM/Ca/Ag.

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Table 1 | Photovoltaic parameters of the single-junction devices (DPP, PCDTBT and OPV12) and the tandem DPPDPP solar cells.

Device Electrode bottom/top

VOC

(V)

FF (%)

JSC

(mA cm 2)

PCE (%)

DPP:PC60BM ITO/Ag 0.56 62.1 13.5 4.69 Tandem ITO/Ag 1.10 64.5 7.06 5.01

DPPDPP cells ITO/AgNWs 1.10 63.0 5.16 3.58 PCDTBT:PC70BM ITO/Ag 0.89 57.1 9.03 4.59

AgNWs/Ag 0.88 55.5 8.93 4.36 OPV12:PC60BM ITO/Ag 0.81 67.8 9.12 5.01

AgNWs/Ag 0.80 66.4 9.04 4.80

AgNW, silver nanowire; DPP, pDPP5T-2; PCE, power conversion efciency.

DPPDPP cell shows an average transmittance of 35.6% in the range of 450650 nm, which ensures for most wide bandgap materials to be applicable as top subcell to effectively harvest the transmitted photons.

A typical current density versus voltage (JV) characteristic of the as-prepared semitransparent tandem solar cells (Fig. 2c) exhibits a VOC of 1.10 V, which is identical to the reference tandem cell, suggesting the effective incorporation of AgNWs as the top electrode. Due to the lack of the back reective electrode, the semitransparent tandem device shows a relatively low short circuit current (JSC) of 5.16 mA cm 2. In combination with the still high FF of 63.0%, these results provide sufcient evidence that the solution-deposited AgNW meshes are highly compatible with the underlying layers without compromising the device performance. In combination with our previous ndings that the as-designed intermediate layer was able to resist high boiling-point solvent rinsing (chlorobenzene and dichlorobenzene)16, we expect that the successively established two intermediate layers are capable of coupling the series- and parallel-connected three cells into a monolithically deposited triple-junction stack.

Top subcell fabrication. In our SP triple-junction devices, the top cell is connected in parallel with the bottom series-tandem cell which gives a VOC of 1.1 V. To match the voltage between the parallel-connected components and thereby maximize the overall efciency, a top cell with a VOC value identical or close to the VOC of the bottom series-tandem cell is desired. Here to demonstrate the general application of our SP triple-junction architecture, we studied two wide bandgap polymers, poly[N-900-hepta-decanyl-2,7-carbazole-alt-5,5-(40,70-di-2-thienyl-20,10,30-benzothiadiazole)] (PCDTBT, Eg, 1.87 eV) and OPV12 (Eg, 1.73 eV)33, as the top subcells, which give VOC values of B0.9 V and 0.8 V when mixed with phenyl-C71-butyric acid methyl ester (PC70BM) and PC60BM, respectively. In addition, as indicated in Supplementary Fig. 2, the absorption proles of the two active layers are complementary with that of DPP:PC60BM, suggesting they are appropriate material combinations for manufacturing multi-junction devices.

To verify the compatibility of the two wide bandgap donors with the AgNW electrode, single-junction reference cells of PCDTBT:PC70BM and OPV12:PC60BM were rst processed on both indium tin oxide (ITO) and AgNWs-coated glass substrates for comparison (Fig. 3a). Typical JV characteristics of the as-prepared single-junction devices are displayed in Fig. 3b,c and the key photovoltaic parameters are summarized in Table 1. Comparable device performances in terms of VOC, JSC and PCE

were observed for the two photoactive blends independent of

bottom electrode. The slightly lower FFs for the devices fabricated on AgNWs as compared with the ITO counterparts can be ascribed to the higher series resistance (RS), probably resulting from the contact resistance between the AgNWs and ZnO. Nevertheless, these results suggest the excellent optoelectronic properties of the AgNWs that are compatible with different polymer donors. Indeed, independent measurement of the AgNW electrode employed in the current study shows an average visible transmittance of B90% (Fig. 2b) and a sheet resistance of B10 O sq 1, which is comparable to commonly used ITO electrodes.

Organic triple-junction solar cells. Having successfully constructed the individual bottom semitransparent tandem subcells and top subcell, in combination with the veried robust intermediate layers we now complete the fabrication of the entire SP triple-junction solar cells. Figure 4a shows the schematic illustration of the SP triple-junction cell design, where the bottom series-connected tandem subcells in a normal structure are electrically connected in parallel with the top inverted subcell. The middle AgNW layer in this triple-junction device serves as a common cathode to collect electrons created by the subcells. It is worth mentioning that we have employed a simple modied doctor blading technique to coat the AgNW electrode16, which enables the deposition of the NW lm in a stripe and thereby eliminates any subsequent patterning steps. Detailed description of the device fabrication procedure is presented in the Methods section and schematically illustrated in Supplementary Fig. 3.

A cross-sectional transmission electron microscopy (TEM) image of a SP triple-junction solar cell is shown in Fig. 4b. The liftout sample was prepared using a focused ion beam (FIB, FEI Helios NanoLab 660) and imaged subsequently with the TITAN3 aberration-corrected TEM. All the individual layers of the solar cell can be clearly distinguished in the scanning TEM (STEM) image without any physical damage. It should be noted that, even though interlayer mixing between the AgNWs and the underlying N-PEDOT layer is observed, it does not negatively affect the device performance since the N-PEDOT in the stack purely acts as a solvent protection layer. On contrary, the fact that the AgNWs partially sink into N-PEDOT can reduce the roughness of the NW networks, which is benecial for building the upper few layers and further reduces the possibility of shunts in the top subcell. The STEM energy dispersive X-ray spectrometry (EDS) elemental maps (Ag, Zn and S) of the cross-section shown in Fig. 4c conrms a well-organized layer stack.

Simultaneously, optical simulations based on the transfer matrix formalism were carried out to calculate the current generation in the individual subcells34,35, which can provide valuable guidance for optimization of our SP triple-junction devices. Taking advantage of the fact that parallel-connection does not require current matching, and therefore balancing the current ow in the bottom series-tandem DPPDPP cells is of critical signicance. In the case of DPPDPP/PCDTBT triple-junction devices, for the purpose of simplicity we xed the thickness of the top PCDTBT:PC70BM to be 80 nm

corresponding to the thickness of optimized single-junction reference cells. Detailed assumption and calculation procedure are presented in the Supplementary Note 2. The outcome of the simulations is shown in Fig. 5a, illustrating the interplay of the photocurrent generation in the three subcells. It is obvious that to maximize the use of incident photons, the thicknesses of the two DPP:PC60BM active layers should follow the red dashed line where the photocurrents generated in the two subcells are identical. Taking the photocurrent of the top subcell PCDTBT:PC70BM into consideration, the resulting contour plot

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a b c

Current density (mA cm2 )

6

6

OPV12:PC BM

Voltage (V)

3

PCDTBT:PC BM ITO

AgNWs

Voltage (V)

3

MoOx

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Current density (mA cm2 )

ITO

AgNWs

Ag

0

0

3

Photoactive layer

6

6

ZnO

ITO or AgNWs

9

9

Glass

0.2 0.0 0.2 0.4 0.6 0.8 1.0

0.2 0.0 0.2 0.4 0.6 0.8 1.0

Figure 3 | Device structure and photovoltaic performance of single-junction cells. (a) Device architecture of inverted solar cells with AgNW bottom electrode. (b,c) Typical JV curves of single-junction reference cells of PCDTBT:PC70BM (b) and OPV12:PC60BM (c) deposited on ITO and AgNWs-coated glass substrates.

a

b

Ag

MoOX

AgNWs & N-PEDOT

PCDTBT:PC70BM

ZnO

Ag

AgNWs

g N-PEDOT

ZnO

MoOx

Top Subcell

DPP:PC60BM

ZnO

N-PEDOT

ZnO

DPP:PC60BM

ZnO

PEDOT:PSS

DPP:PC60BM

N-PEDOT

ZnO

ITO

DPP:PC60BM

PEDOT:PSS

ITO/Glass

Glass

c

STEM

STEM

Ag Zn S

Figure 4 | Microstructure of the triple-junction solar cell. (a) Device architecture of the SP triple-junction solar cell. (b) A cross-sectional TEM image of the as-prepared triple-junction solar cell. The scale bar, 200 nm. (c) STEM image of the cross-section and EDS elemental (Ag, Zn, S) maps. Note that the strongest top band (indicated by arrow) in the sulphur map belongs to molybdenum because of overlapping of S-Ka (2.307 keV) and Mo-La(2.293 keV) lines. The scale bar, 400 nm.

of the current density distribution of the entire triple-junction solar cells as a function of the thicknesses of two DPP:PC60BM

layers is depicted in Fig. 5b. One can see that maximum photocurrents of B10 mA cm 2 are achievable for our

DPPDPP/PCDTBT triple-junction devices when the thicknesses of the bottom and top DPP:PC60BM subcells are in the range of 3060 nm and 3580 nm, respectively. Similar simulation results for the triple-junction DPPDPP/OPV12 devices are presented in Supplementary Fig. 4.

Experimentally, to evaluate the photovoltaic performances of the subcells, we designed a three-terminal layout to prepare our SP triple-junction solar cells, which allows us to detect the JV characteristics of both the bottom series-tandem subcell and the top subcell within their connected state (Supplementary Fig. 3). Figure 5c,d show the typical JV curves of the constructed triple-

junction solar cells, DPPDPP/PCDTBT and DPPDPP/OPV12, along with the constituent subcells, respectively. The key photovoltaic parameters are listed in Table 2. It can be seen that the two triple-junction cells achieved JSC of 9.67 mA cm 2 (DPPDPP/PCDTBT) and 9.55 mA cm 2 (DPPDPP/OPV12)

which is in good agreement with the optical simulations. Noticeably, from Table 2 we can see that the measured photocurrents of the triple-junction cells are more or less identical to the sum JSC values extracted from the respective bottom DPPDPP subcells and top PCDTBT or OPV12 subcells. The JSC values of the top subcells were veried with EQE measurement (Supplementary Fig. 5) and the values calculated by integrating the EQE curve with standard AM1.5 G spectrum show a good agreement with the measured JSC values. Moreover, as depicted in Fig. 5c,d, if we mathematically add the JV curves

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a b

JSC (mA cm2)

10.5

200 5.50 6.50

50 100 150 200

10.0

Current density (mA cm2 )

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Top DPP thick (nm)

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8.50

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200

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100

Bottom DPP thick (nm)

0

0 Top DPP thick (nm)

Bottom DPP thick (nm)

c d

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Bottom DPPDPP subcell

Top PCDTBT subcell

Measured triple-junction cell

Addition of the three subcells

4 Bottom DPPDPP subcell

Top OPV12 subcell

Measured triple-junction cell

Addition of the three subcells

Voltage (V)

Current density (mA cm2 )

Current density (mA cm2 )

2

2

0

0

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2

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4

6

6

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8

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Voltage (V)

Figure 5 | Optical simulations and photovoltaic characteristics of the SP triple-junction solar cells. (a) Simulated current density distribution of the three subcells as a function of the thicknesses of bottom two DPP:PC60BM layers. (b) Contour plot of current density distribution of the entire triple-junction devices (DPPDPP/PCDTBT) as a function of the thicknesses of bottom DPP:PC60BM layers. Note that in these two simulations the top PCDTBT:PC70BM layer thickness is xed to 80 nm, corresponding to the optimized thickness in their single-junction state. (c,d) JV characteristics of the investigated triple-junction cells and the constituent bottom series-tandem subcells and top subcell, (c) DPPDPP/PCDTBT, (d) DPPDPP/OPV12. The light grey dashed lines indicate the numerical addition of the bottom series-tandem subcells and the top subcell.

Table 2 | Photovoltaic parameters of the triple-junction cells and the constituent subcells.

Material combination

Devices VOC

(V)

FF (%)

JSC

(mA cm 2)

PCE (%)

RS (X cm2)

DPPDPP/ PCDTBT

Bottom DPPDPP subcell

1.08 64.2 6.00 4.16 8.03

Top PCDTBT subcell

0.82 54.9 3.70 1.66 1.15

Triple connection

0.89 63.1 9.67 5.43 1.04

DPPDPP/ OPV12

Bottom DPPDPP subcell

1.07 60.7 5.95 3.86 7.14

Top OPV12 subcell

0.77 67.8 3.58 1.87 0.82

Triple connection

0.82 68.4 9.55 5.35 0.71

DPP, pDPP5T-2; PCE, power conversion efciency.

R of the cells were calculated at B2 V of the JV curves measured in dark.

of the DPPDPP subcells with the top PCDTBT or OPV12 subcell at each voltage bias (Vbias), a perfect tting of the

constructed JV curve with the experimentally measured JV curve of the triple-junction device is observed, which is consistent with Kirchhoffs law. These observations provide sufcient evidence that there are no resistive losses for the intermediate AgNW electrode in terms of collecting charge carriers.

For both triple-junction solar cells, the bottom series-connected DPPDPP subcells showed VOC values of

1.071.08 V, indicating that the solution-processing of the upper layers imposes no negative effect on the established bottom subcells. Compared with the reference DPPDPP tandem cell, the slightly reduced VOC of 0.020.03 V can be attributed to shadow effect36, because a mask with an aperture smaller than either electrode was adopted to dene the active area during the JV measurement. While the reduced light intensity ltered by the front DPPDPP subcells further slightly decreased the VOC of the

back PCDTBT:PC70BM or OPV12:PC60BM subcells by a value of0.030.05 V.

For solar cells with ideal diode characteristics, the VOC of the

parallel-connected tandem cells would be strictly restricted by the subcell, which delivers low VOC. In real parallel-connected solar cells, however, the VOC of the tandem cells can be close either to the subcell with high VOC or to the subcell with low VOC depending on the series resistance of the subcells37. In our parallel-connected constituent subcells, the two top subcells showed series resistance of B1 O cm2 which is almost eight times lower than those of bottom DPPDPP subcells (Table 2). This is due to the fact that the charge injections in the top subcells are higher than in the bottom subcells at Vbias4VOC. Consequently,

the top subcells showed steeper slopes at Vbias4VOC compared

with the bottom subcells. Taking Kirchhoffs law into consideration, these circumstances lead to the VOC values of our triple-junction cells close to the top subcells which exhibited lower VOC.

Moreover, it should be noted that although our triple-junction cells have achieved PCEs of 5.35 and 5.43%, which are higher than either one of the single-junction reference devices, those values are still B0.4% lower than the sum PCEs of the incorporated subcells. These PCE losses are mainly attributed to the relatively low VOC of triple-junction that is close to the top

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subcells, and this suppression can be readily eliminated by employing high-performance top subcells with VOC matched to the bottom series-connected subcells. Nevertheless, these results in combination with the high FFs of up to 68% eventually suggest that the engineered intermediate layers have efciently coupled the three cells into triple-junction with an integrated SP interconnection.

Hybrid triple-junction solar cells. Organometal halide perovskites have emerged as promising materials that enable fabrication of highly efcient solar cells by solution deposition3840. Although efciencies exceeding 15% have been frequently reported, it is widely acknowledged that the moderate bandgap of 1.55 eV offers enormous potential to further enhance the device efciency by using multi-junction congurations39,40. Given that the perovskite single cell (mixed halide CH3NH3PbI3 xClx) provides a high VOC of B1 V, which is

comparable to our series-connected DPPDPP cells, it is straightforward to fabricate a PS connected triple-junction device by placing a DPPDPP cell behind a semitransparent perovskite cell, and thereby adding up the total current density for the hybrid triple-junction device.

Figure 6a shows the calculated JSC distribution of the three subcells of the hybrid triple-junction device as a function of the thicknesses of the back two DPP cells. We used an internal quantum efciency of 100% for our simulation41. The front 200-nm-thick perovskite cell exhibits a JSC of B16 mA cm 2, which is slightly affected by the interference of the device. The

EQE measurement of a prepared semitransparent perovskite cell (Supplementary Fig. 6) gives a current density of 15.98 mA cm 2 which is in good agreement with the simulation values (Supplementary Methods for fabrication details). A current density of up to 3 mA cm 2 is calculated for the series-connected DPPDPP tandem cell, as a benet of the average53.4% transmittance (650 and 850 nm) of the semitransparent perovksite cell (Supplementary Fig. 7). Figure 6b shows the measured JV curves of the experimentally constructed hybrid triple-junction solar cell and the corresponding subcells. The semitransparent perovskite device shows a JSC 16.28 mA cm 2,

VOC 0.94 V and FF 65.6%, yielding a PCE of 10.04%. The

hybrid triple-junction device perovskite/DPPDPP exhibits a high current density of 18.51 mA cm 2 with about 2 mA cm 2 contributed from the back DPPDPP subcells. Together with the high FF of 64.5% and VOC of 0.95 V, the hybrid triple-junction device shows a PCE value of 11.34%, corresponding to a PCE enhancement by 12.5%.

To illustrate the benet of the hybrid triple-junction device, we further theoretically compared the current generation between the single opaque perovskite cells and the hybrid triple-junction devices using the same material combinations. As presented in Fig. 6c, the JSC value of the triple-junction device reaches to the

JSC value of the opaque single-junction perovskite cell, for perovskite cells with a layer thickness of 4300 nm. It should be noted that the absorption of the DPP polymer donor shows a red-shift of only B50 nm compared with the perovskite and, therefore, we expect a signicant enhancement when deeper NIR sensitizers are used as back series-connected tandem cells.

DiscussionWe have experimentally demonstrated in this work, for the rst time, solution-processed organic and hybrid triple-junction solar cells with integrated series- and parallel-interconnection. The optical simulations reveal that the as-proposed SP triple-junction organic solar cells hold the potential to achieve high efciencies close to those of the fully series-connected counterparts, but allowing a much wider choice of material combinations. Through a rational interface layer design, triple-junction devices with all solution-processed intermediate layers achieved PCEs of B5.4%

with FFs of up to 68%. Currently, the efciency of our SP triple-junction devices is mainly limited by the mismatch of the VOC of

the top subcell with the VOC of the bottom series-connected tandem subcells. Based on the convenient solution-processing along with the impressive high FFs, we expect that signicant enhancement in efciency can be achieved by exploiting high-performance wide bandgap materials with matched VOC in

the back subcell. Alternatively, our results predict a signicantly growing interest in ultra-low bandgap semiconductors allowing for more efcient light-harvesting for these SP triple-junction solar cells.

The general applicability of the proposed triple-junction congurations has also been veried in organic-inorganic hybrid triple-junction devices. By combining a semitransparent perovskite cell with series-connected DPPDPP cells in parallel, the fabricated hybrid triple-junction devices showed an efciency improvement by 12.5% compared with the corresponding reference cells. Further, we believe that the novel, but generic, concept demonstrated in this work potentially provides a promising avenue to approach or exceed the ShockleyQueisser limit of many of the currently available high-performance semiconductors such as crystalline silicon, CdTe and perovskite solar cells4244.

b c

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Figure 6 | Simulation and experimental demonstration of hybrid triple-junction solar cells with a parallel/series interconnection. (a) Calculated JSC

distribution of the three subcells as a function of the back two DPP:PC60BM lm thicknesses. The thickness of the front perovskite layer is xed to 200 nm which corresponds to the thickness of the optimized reference cells. (b) Measured JV curves of the two constituent subcells and the triple-connected device. (c) Calculated JSC values of the semitransparent, opaque perovskite cells and the proposed triple-junction devices (perovskite/DPPDPP) as a function of layer thickness of the perovskite.

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Methods

Materials. ITO-coated glass substrates (2.5 2.5) cm2 with a sheet resistance of

15 O sq 1 were purchased from Weidner Glas and patterned with laser before use. Light absorbers DPP, OPV12 and PCDTBT were purchased from BASF, Polyera and 1-Materials, respectively. PEDOT:PSS (Clevios, P VP AI 4083) and N-PEDOT (NT5-3417286/2) were obtained from Heraeus and Agfa, respectively. ZnO nanoparticles dispersed in isopropanol (Product N-10) and AgNW dispersion (ClearOhm Ink) were supplied by Nanograde AG and Cambrios Technologies Corporation, respectively. PC60BM (99.5%) and PC70BM (99%) were purchased from Solenne BV. All the materials were used as received without further purication.

Fabrication of triple-junction devices. For our SP triple-junction organic solar cells, with the exception of bottom ITO-coated glass substrate and top evaporated MoOX/Ag electrode, all the layers were sequentially deposited using a doctor blade in ambient atmosphere. Prior to device fabrication, the laser-patterned ITO substrates were cleaned by ultra-sonication in acetone and isopropanol for 10 min each.

On the cleaned substrates, PEDOT:PSS (Clevious P VP Al 4083, 1:3 vol.% diluted in isopropanol) was rstly bladed and annealed at 140 C for 5 min to obtain a layer thickness of B40 nm. On top of the dried PEDOT:PSS, the rst photoactive layer consisting of DPP and PC60BM (1:2 wt.% dissolved in a mixed solvent of chloroform and o-dichlorobenzene (9:1 vol.%)) was deposited at 45 C to obtain a thickness of B50 nm. The rst intermediate layers, ZnO and N-PEDOT:PSS, were sequentially bladed at 50 C and annealed at 80 C for 5 min in air and the obtained layer thickness for both layers is B35 nm. The second active layer DPP:PC60BM with thickness of B80 nm was then coated on top of N-PEDOT at 55 C. Afterwards, ZnO and N-PEDOT were again deposited onto the second DPP:PC60BM layer using the same coating parameters as for the rst deposition. To deposit the intermediate electrode, B80-nm-thick AgNWs was bladed onto N-PEDOT at 45 C and the resulting NW lm showed a sheet resistance of B8 O sq 1. Successively, an electron extraction layer of ZnO was deposited on top of AgNWs using the same parameters, followed by blading the third active blend of PCDTBT:PC70BM at 60 C. After all the solution-processed

layers were completed, Q-tips dipped with toluene were used to clean the edges of the substrate to expose the bottom ITO and middle AgNW contacts. Finally, to complete the device fabrication, a 15-nm-thick MoOX and 100-nm-thick Ag were thermally evaporated on top of PCDTBT:PC70BM through a shadow mask with an opening of 10.4 mm2.

Triple-junction solar cells DPPDPP/OPV12 were prepared with the same processing procedure as device DPPDPP/PCDTBT. To achieve a reliable contact between the middle AgNW electrode and probes of the measurement set-ups (JV and EQE measurements), silver paste or evaporated silver was applied to the exposed AgNWs (Supplementary Fig. 3). Semitransparent DPPDPP reference tandem cells with top AgNW electrode and the single-junction reference devices (PCDTBT:PC70BM and OPV12:PC60BM) with bottom AgNW electrode were fabricated using the same procedure as these subcells in the SP triple-junction cells.

The semitransparent perovskite (mixed halide CH3NH3PbI3 xClx) solar cells

with a device structure of ITO/PEDOT:PSS/Perovskite/PC60BM/ZnO/AgNWs (Supplementary Fig. 5a) was fabricated using a procedure as described in the Supplementary Methods45. The hybrid triple-junction solar cell was assembled by stacking a series-connected opaque DPPDPP as back subcell with a semitransparent perovskite device as front subcell. The parallel-connection between the semitransparent perovskite and series-connected DPPDPP subcells was realized by external coupling using Ag paste.

Characterization. Transmittance spectra of the intermediate layers and semitransparent devices were measured using a UVvis-NIR spectrometer (Lambda 950, from Perkin Elmer). JV curves of all the devices were recorded using a source measurement unit from BoTest. Illumination was provided by a solar simulator (Oriel Sol 1 A from Newport) with AM1.5G spectrum and light intensity of 100 mW cm 2, which was calibrated by a certied silicon solar cell. To guarantee the incident light to be able to illuminate on all the three electrodes with an overlapped active area, during the JV measurement a mask with an aperture of4.5 mm2 was used to dene the cell area. The EQE spectra were recorded with an EQE measurement system (QE-R) from Enli Technology (Taiwan). The light intensity at each wavelength was calibrated with a standard single-crystal Si solar cell. Liftout sample for TEM was prepared with FEI Helios Nanolab 660 DualBeam FIB, from the area-of-interest containing all layers of the solar cell. A lamella containing a cross-section of the solar cell was then attached to a TEM half grid for nal thinning. The nal thickness of the liftout sample was kept o100 nm, to enable high quality conventional transmission electron microscopy (CTEM)

imaging at an acceleration voltage of 200 kV. TEM was performed on the FEI TITAN3 Themis 60300 double aberration-corrected microscope at the Center for Nanoanalysis and Electron Microscopy (CENEM), the University of Erlangen, equipped with the super-X energy dispersive spectrometer.

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Acknowledgements

The work was supported by the Cluster of Excellence Engineering of Advanced Materials (EAM) and the SFB 953 at the University of Erlangen-Nuremberg. We would like to thank Cambrios Technology Corporation, Dr Mathieu Turbiez from BASF and Dr Norman Lchinger from Nanograde for the supply of AgNWs, DPP and ZnO dispersion, respectively. V.R.R. and V.V.R. acknowledge nancial support from the

Ministry of Education, Science and Technological Development of the Republic of Serbia (Grants No. 172054 and No. III45019, respectively.) and from the DFG research training group GRK 1896 at the Erlangen University. F.G. and N.L. would like to acknowledge the funding from the China Scholarship Council and the Joint Project Helmholtz-Institute Erlangen Nrnberg (HI-ERN) under project number DBF01253, respectively. K.F. and C.J.B. gratefully acknowledge the nancial support through the Aufbruch Bayern initiative of the state of Bavaria.

Author contributions

F.G. and C.J.B. conceived the device concept. F.G., N.L. and N.G. fabricated and characterized the organic solar cells. C.O.R.Q., C.B. and Y.H. prepared the semi-transparent perovskite cells. F.W.F. carried out the semi-empirical modelling. F.G. and K.F. performed the optical simulations. V.V.R., V.R.R. and E.S. prepared the FIB sample and performed the TEM imaging. C.J.B., F.G. and N.L. contributed to project planning and manuscript preparation. All the authors commented on the manuscript.

Additional information

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How to cite this article: Guo, F. et al. A generic concept to overcome bandgap limitations for designing highly efcient multi-junction photovoltaic cells. Nat. Commun. 6:7730 doi: 10.1038/ncomms8730 (2015).

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