The Influence of the Work Function of Hybrid Carbon Electrodes on

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The Influence of Work Function of Hybrid Carbon Electrodes on Printable Mesoscopic Perovskite Solar Cells Pei Jiang, Yuli Xiong, Mi Xu, Anyi Mei, Yusong Sheng, Li Hong, Timothy William Jones, Gregory J Wilson, Sixing Xiong, Daiyu Li, Yue Hu, Yaoguang Rong, and Hongwei Han J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.8b02163 • Publication Date (Web): 02 Jul 2018 Downloaded from http://pubs.acs.org on July 3, 2018

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The Journal of Physical Chemistry

The Influence of Work Function of Hybrid Carbon Electrodes on Printable Mesoscopic Perovskite Solar Cells Pei Jiang†#, Yuli Xiong†#, Mi Xu†#,Anyi Mei†, Yusong Sheng†, Li Hong†, Tim. W. Jones‡, Gregory. J. Wilson‡, Sixing Xiong†, Daiyu Li†, Yue Hu†, Yaoguang Rong*†, Hongwei Han*† †

Michael Grätzel Center for Mesoscopic Solar Cells, Wuhan National Laboratory for Optoelectronics, School of Optical and Electronic Information, Huazhong University of Science and Technology, Wuhan 430074, Hubei, P. R. China ‡ CSIRO Energy, Mayfield West, NSW 2304, Australia

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ABSTRACT In printable mesoscopic perovskite solar cells (PSCs), carbon electrodes play a significant role in charge extraction and transport, influencing the overall device performance. The work function and electrical conductivity of the carbon electrodes mainly affect the open-circuit voltage (VOC) and series resistance (Rs) of the device. In this paper, we propose a hybrid carbon electrode based on a high-temperature mesoporous carbon (m-C) layer and a low-temperature highly conductive carbon (c-C) layer. The m-C layer owns high work function and large surface area, and is mainly responsible for charge extraction. The c-C layer owns high conductivity, and is responsible for charge transport. The work function of the m-C layer was tuned by adding different amounts of NiO, and at the same time, the conductivity of the hybrid carbon electrodes were maintained by the c-C layer. It was supposed that the increase of the work function of carbon electrode can enhance the VOC of printable mesoscopic PSCs. Here, we found the VOC of the device based on hybrid carbon electrodes can be enhanced remarkably when the insulating layer has a relatively small thickness (500 ~1000 nm). An optimal improvement in VOC of up to 90 mV can be achieved when the work function of the m-C increased from 4.94 eV to 5.04 eV. When the thickness of the insulating layer increased to ~3000 nm, the variation of VOC as the work function of m-C increased became less distinct.

KEYWORDS hybrid carbon electrodes, work function, highly conductive, open-circuit voltage, perovskite solar cells

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Organic-inorganic hybrid perovskite solar cells (PSCs) have garnered recent interest in the scientific community due to their low-cost of production via solution-processed fabrication techniques.1-5 In the past few years, the certified power conversion efficiency (PCE) of PSCs has reached 22.7%6 and is comparable to traditional commercialized solar cells (e.g., crystalline Si, CuInGaSe and CdTe). The high performance of PSCs can be attributed to the outstanding optoelectronic properties of the hybrid perovskite materials (ABX3: A = CH3NH3+, HC(NH2)2+, Cs+; B = Pb2+, Sn2+, Ge2+; X = Cl-, Br-, I-), including high absorption coefficient7,8, high charge mobility9,10, long balanced carrier diffusion length and low exciton binding energy.10,11 As a photovoltaic technology, which needs to meet the requirements for working under outdoor conditions, PSCs currently suffer stability concerns for both materials and devices.12,13 Particularly, for the typical metal electrodes in PSCs, either Au, Ag or Al may react with the perovskite absorber, leading to severe degradation of the device performance.14,15 Among different architectures for PSCs, printable mesoscopic PSCs based on carbon electrodes seem to be one of the most promising technical route.17-18 In such devices, no hole transport materials (HTMs) is needed, and carbon materials are employed to replace the traditional metal electrodes. Thus, the material cost is much lower than traditional PSCs. Besides, the inorganic mesoporous scaffolds of TiO2/ZrO2/Carbon for hosting the perovskite absorber, especially the hydrophobic carbon layer, have enabled such devices remarkable stability.19,20 The screen printing technique based fabrication process provides a prospect for upscaling and further mass-production.21,22 In printable mesoscopic PSCs, the carbon electrode which is cheap and stable extracts holes from the perovskite absorber and collects electrons from the external circuit.23,24 However, the Femi Levels (EF) of pristine carbon materials such as carbon black and graphite is usually far above the valence band (VB) of perovskite. The mismatched energy level alignment leads to inefficient hole extraction and low open-circuit voltage (VOC).25 Previously, we have investigated the effect of the morphology and corresponding electric properties of carbon electrodes on printable mesoscopic PSCs.26 Then, we attempted to increase the work function of the carbon electrode and improve the device performance.27 At the same time, other groups inserted an extra layer of NiO between the ZrO2 and carbon layer, constructing a p-i-n configuration.28 It was proposed that the NiO interlayer can enhance the device performance by extracting hole efficiently and enlarge the difference between electron/hole EF of selective materials.

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Herein, we designed a hybrid carbon electrode based on a mesoporous carbon (m-C) layer and a compact and highly conductive carbon (c-C) layer, and investigated the effect of their properties on the performance, especially the VOC, of printable mesoscopic PSCs. The m-C layer was modified with p-type metal oxides and possessed high work function. Due to the mesoporous microstructure, the m-C layer has quite large surface area and thus can further facilitate the contact and charge extraction between the perovskite absorber and the carbon counter electrode. The c-C layer owns high conductivity,29 and can minimize the influence of the variation of the conductivity of the carbon electrodes after mixing with the metal oxides. It was found that the work function of the m-C layer can be effectively enhanced from 4.94 eV to 5.04 eV by incorporating NiO. When the ZrO2 layer is relatively thin (500 ~ 1000 nm), through varying the ratio of NiO in the m-C layer and the thickness of the ZrO2 layer, the enhancement in VOC of the devices can be up to 90 mV. When the thickness of the ZrO2 layer increased to ~3000 nm, the enhancement in the VOC as the work function increased became less distinct.

Figure 1. Schematic configuration and energy band diagram of printable mesoscopic PSCs with a single m-C layer (a, c) and a hybrid m-C/c-C layer (b, d) as the counter electrode. Efn and Efp are the electron and hole quasi-Fermi levels, respectively.

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Figure 1a and b show the schematic configurations of printable mesoscopic PSCs based on typical a single m-C layer and a hybrid m-C/c-C layer as the counter electrode. For the device based on a single m-C layer, the compact TiO2 layer, mesoporous TiO2 layer, ZrO2 layer and carbon layer are used as the hole blocking layer, the electron transport layer (ETL), the insulating layer and the counter electrode, respectively. The perovskite is infiltrated in the mesoporous triple-layer of TiO2/ZrO2/carbon. For the device based on a hybrid carbon layer, after the infiltration of the perovskite absorber in the m-C layer, a c-C layer is screen printed on the top of m-C/perovskite. Due to the ambipolar perovskite and energy-level alignment, the electrons can efficiently inject into the conductive band (CB) of the TiO2, and the holes can be collected by the carbon electrode and arrive at the external circuit. The working principles of such printable mesoscopic PSCs are shown in Figure 1c and d.30 The VOC is mainly determined by the difference between the Efn (electron quasi-fermi level) and Efp (hole quasi-fermi level).31 In printable mesoscopic PSCs, Efn is determined by the interaction between electron transfer layer (eg. TiO2) and perovskite layer, while Efp is determined by the interaction between the perovskite layer and the carbon electrode. Lower EF for the carbon electrode can help increase the VOC and PCE. When the single carbon layer was replaced by a hybrid carbon layer, the Efp position may drop due to the lower EF of p-type metal oxides modified m-C than the pristine carbon layer. As a result, the VOC may increase. Table S1 presents the work function of m-C layers with NiO, MoO3, Co2O3 and CuO. When p-type metal oxides were mixed with the m-C layer, the work function of the m-C layer from 4.94 eV to 4.97 eV for m-C/10%NiO, 5.15 eV for m-C/10%MoO3, and 4.98 eV for m-C/10%Co2O3. Table S2 summarizes the photovoltaic performance of printable mesoscopic PSCs based on different hybrid carbon electrodes. Unfortunately, only the devices using NiO modified m-C electrode showed tiny enhancement in performance, while the devices using and Co2O3 and CuO showed much decreased efficiencies. Figure 2a-c show the photograph, cross-sectional scanning electron microscope (SEM) images and energy dispersive X-ray (EDX) Spectroscopy of the devices. It can be observed that the printable mesoscopic PSC based on carbon electrode with MoO3 has very poor pore filling (marked with pink), which is the cause of the extremely low short-circuit current density (JSC) of 1.54 ± 0.02 mA cm-2. For the devices Co2O3 and CuO as the modifiers, it was found that the elements of Co and Cu also existed in the TiO2/perovskite and ZrO2/perovskite layers (Figure S2). This indicates that Co2O3 and CuO may

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react or interact with the perovskite absorber, and thus cause negative effect on the device performance.

Figure 2. (a) The photograph of printable mesoscopic PSCs based on hybrid carbon electrodes with NiO, MoO3, Co2O3 and CuO, respectively; (b-c) The SEM cross-section images and EDX elements mapping of printable mesoscopic PSCs based on hybrid carbon electrode with NiO and MoO3. Since the devices based on m-C/10% NiO showed slightly improved performance with JSC of 23.43 mA cm-2, VOC of 0.92 V, fill factor (FF) of 0.65 and PCE of 13.94%. The ratio of in the m-C layer was further increased to 30% and 50% for comparison. Figure 3a shows the diffraction (XRD) spectra of m-C modified with different amount of NiO. The peak at 2θ = can be indexed as the (004) crystal planes of carbon black and graphite. The peaks at 2θ = 37.14°, 43.29° and 62.80° can be indexed as the (111), (200), (220) crystal planes of NiO.32 As the ratio NiO increased from 10%, 30% to 50%, the intensity of these peaks correspondingly increased. increased ratio of NiO in the m-C layer was also confirmed by X-ray photoelectron spectroscopy (XPS) measurements (Figure S3). As the ratio of NiO in the m-C layer increased, the peak of Ni 2p at 532 eV continuously enhanced, while the peak of C 1s at 284 eV decreased, which is consistent with the results of XRD.

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Figure 3b shows the variation of the conductivity of the m-C layer with different amount of NiO. As the ratio of NiO increased, the sheet resistance (R□) increased from 26.76 Ω □-1 for the pristine m-C layer to 114.78 Ω □-1 for the m-C/10%NiO layer. When the ratio of NiO further increased to 30% and 50%, the sheet resistance of the modified m-C layer increased to 141.74 Ω □-1 and 617.00 Ω □-1. To avoid the negative effect caused by the increased resistance on device performance, we employed a c-C layer on the top of the m-C layer. The sheet resistance of the m-C/c-C hybrid carbon electrodes are only around 8 Ω □-1, and stayed almost unchanged when they were modified with NiO (Table S3). The work function of the NiO modified m-C layers was characterized by Kelvin probe measurements, and the values are summarized in Table S4. As shown in Figure 3c, the work function of the m-C layers continuously increased from 4.94 eV to 5.04 eV, as the ratio of NiO increased from 10% to 50%.

Figure 3. (a) XRD patterns of the pristine m-C layer and m-C layers with 10%, 30%, and 50% NiO; (b) Sheet resistance of the pristine m-C layer and m-C layers with 10%, 30%, and 50% NiO (the thickness is ~10 µm). For the average and s.d. values, the results were obtained with 5 samples prepared with the same condition; (c) Work function of the pristine m-C layer and m-C layers. For the average and s.d. values, the results were obtained with 8 samples prepared with the same conditions; (d) Time-resolved photoluminescence (TRPL) spectra of the samples of

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perovskite/m-C,

perovskite/(m-C/10%NiO),

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perovskite/(m-C/30%NiO)

and

perovskite/(m-C/50%NiO).

Figure 3d shows the time-resolved photoluminescence (TRPL) spectra of the perovskite layer in the m-C layers

with or without NiO.

It was found that the samples of

perovskite/(m-C+10%/30%/50%NiO) showed much stronger PL quenching effect compared with the sample of perovskite/m-C. The perovskite/m-C interface yielded a much longer lifetime of

15.95

ns,

while

the

perovskite/(m-C/10%NiO),

perovskite/(m-C/30%NiO)

and

perovskite/(m-C/50%NiO) yielded shorter lifetimes of 2.77 ns, 1.65 ns and 2.59 ns (Table S5). The results indicate that the incorporation of NiO in the m-C layers can effectively enhance the hole extraction ability of the m-C electrodes. Notably, the sample of m-C/30%NiO layer showed slightly higher quenching efficiency than m-C/50%NiO. This might be related to variation of the conductivity of the m-C layer, for which incorporating 50% NiO in the m-C layer caused a severe decrease of the conductivity.

Figure 4. Photovoltaic parameters of devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO. The thickness of the insulating ZrO2 layer varies from 500 nm to 3 µm. For

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the average and s.d. values, the results were obtained from 5 devices prepared with the same condition.

As the work function of the m-C layers significantly increased when NiO was incorporated, it was expected the VOC and overall PCE of the devices can also be improved.25, 27 However, when we fabricated devices with m-C/30%NiO and m-C/50%NiO, the VOC stayed almost unchanged, (Figure 4a and Table S6), while the PCE slightly increased (Figure 4b). For printable mesoscopic PSCs, the photo-generated holes have to travel through the perovskite absorber in the entire ZrO2 layer and reach the carbon electrode. Considering the ZrO2 layer has a thickness of 3 µm, the recombination due to the relatively long charge diffusion length might dominate the VOC of the device and weaken the influence from the counter electrode. To gain deeper insight on how the work function of the carbon electrode influences the photovoltaic performance of printable mesoscopic PSCs, we reduced the thickness of the insulating ZrO2 layer to 1 µm and 500 nm. When the thickness of ZrO2 layer is reduced to 1 µm, an enhancement in the VOC of ~60 mV can be observed when NiO was incorporated in the m-C layer. When an ultra-thin ZrO2 layer of 500 nm was employed, the enhancement can further increase to ~90 mV, as the ratio of NiO varied from 0% to 50% in the m-C layer. At the same time, the FF of the devices based on carbon electrodes with different amount of NiO were around 0.64~0.65 (Figure 4c). The JSC of the devices slightly increased when 10% NiO was incorporated, and then stayed unchanged for higher NiO ratios (Figure 4d). Thus, the values of the overall PCE of the devices were mainly determined by the variations of the VOC. Figure 5a shows the current density-voltage (J-V) curves of the representative devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO and with 500 nm thick ZrO2 layer. Since the devices showed similar JSC and FF, and varied VOC. We mainly focused on the charge extraction and recombination process in the devices. It was expected that a more efficient charge extraction of the m-C layer due to higher ratio of NiO can suppress charge recombination in the device, which was characterized by impedance spectroscopy (IS) measurements. As shown in Figure 5b, the RC response in the high-frequency region is assigned to the charge exchange process at the interface of perovskite/m-C, whereas the low frequency region represents the interface of perovskite/TiO2. Rs is the series resistance, mainly including the sheet resistance of FTO, the contact resistance and so on. Charge-transfer resistance (Rct) is the charge transfer

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resistance corresponding to the charge transport through the interface of perovskite/m-C. Charge-recombination resistance (Rrec) is the charge transfer resistance of recombination process between electrons in the TiO2 layer and holes in the perovskite. The impedance data were fitted by three RC circuit models, as shown in Figure S4, and all capacitor elements were replaced by constant phase elements. In Table S7, Rct of devices based on m-C with 30% NiO was found to be considerably lower than those of 10% and 50%, which supported the higher charge transfer rate at the perovskite/m-C interface. The Rrec of m-C with 50% NiO was found to be considerably higher than those of 30% and 10%, which supported the lower recombination rate at the perovskite/TiO2 interface.

Figure 5. (a) Current density-voltage (J-V) characteristics measured from forward bias to reverse bias under simulated AM 1.5 G illumination (100 mW cm-2) condition and in the dark of the representative devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO and with 500 nm ZrO2 layer; (b) Impedance spectroscopy characterizations of the devices; The Nyqusit plots are collected in the frequency range of 50 mHz to 4 MHz under illumination at 10 mW cm-2 with applied bias of 0.5 V. The solid line are the fitted curves; (c, d) Charge transport lifetime

(τt)

and

recombination

time

(τr)

obtained

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fitting

the

transient

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photocurrent/photovoltage decay curves for devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO.

The photoexcited charge-carrier dynamics in these devices were further investigated by intensity modulated photocurrent spectroscopy (IMPS) and intensity modulated photovoltage spectroscopy (IMVS) measurements, which can be used to reveal the charge transport and recombination processes in PSCs. The charge transport time (τt) constant and recombination time constant (τr) were derived from the IMPS and IMVS responses. As illustrated in Figure 5c and d, the devices based on m-C with 30% NiO exhibited the shortest τt, while the devices based on m-C with 50% NiO exhibited the longest τt. For the τr, the devices based on m-C with 50% NiO showed the largest values, indicating significantly suppressed recombination process. A more efficient hole extraction due to the lower Efp of the m-C would enhance the electron-hole separation at the interface of perovskite infiltrated in ZrO2 layer and carbon layer, hence suppress the charge recombination. These results are consistent with the EIS data as discussed above. According to the above discussions, we propose that increasing the work function of the carbon electrodes can effectively improve the VOC without scarifying the JSC and FF of the devices on the condition that the ZrO2 possess a relatively small thickness. However, it should be noted that, the devices also achieved relatively low VOC, even with NiO in the m-C layer. This indicated that the insulating effect of the ZrO2 layer is weakened as the thickness decreased. The TiO2 layer and carbon layer may contact directly, and lead to severe charge recombination. Increasing the thickness of ZrO2 is an effective method to completely separate the TiO2 layer and the carbon layer. But the correspondingly increased charge diffusion length will also aggravate the recombination process and dominate the VOC. Besides, the quality of the perovskite absorber in the mesoporous scaffolds and corresponding interfaces also play an essential role in the recombination process for the device performance.33, 34 When NiO was incorporated in the m-C layer, the microstructure of the scaffold may also change, especially for the high ratio of NiO, influencing the crystallization process and quality of the perovskite absorber. The NiO can enhance the extraction of holes from the perovskite. At the same time, NiO may help separate the TiO2 and carbon layer when the ZrO2 layer is too thin. Thus, in the next step, to further improve the performance of printable mesoscopic PSCs, it is urgent to develop counter electrodes with

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higher work function to facilitate the charge extraction and explore more efficient insulating layers to minimize the charge diffusion length. In conclusion, a hybrid carbon electrode was developed for printable mesoscopic PSCs via incorporating a m-C layer with a c-C layer. As the work function of m-C increased from 4.94 eV to 5.04 eV, the VOC of the devices can be enhanced without sacrificing the JSC and FF, when the ZrO2 layer possesses a relatively small thickness. The more efficient hole extraction ability of the m-C layer can effectively suppress the charge recombination in the device. When the thickness of ZrO2 increased to ~3 µm, the VOC of the devices was mainly dominated by the recombination process due to the longer charge diffusion length. This work has revealed how the work function of hybrid carbon electrodes influences the performance of printable mesoscopic PSCs and provided theoretical support to further break the performance bottlenecks of printable mesoscopic PSCs.

ASSOCIATED CONTENT Supporting Information The experimental details, SEM cross-section and EDX elements mapping images (Figure S1), the XPS spectra (Figure S2), the equivalent circuit diagram (Figure S3), the scheme of the fabrication process of the devices (Figure S4), photovoltaic parameters of the devices (Table S1-9). This information is available free of charge via the Internet at http://pubs.acs.org. AUTHOR INFORMATION Corresponding Author *

Y. Rong. E-mail: [email protected]; H. Han. E-mail: [email protected]

Author Contributions #

P. J., Y. X and M. X. contributed equally in this work.

Notes The authors declare no competing financial interest.

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ACKNOWLEDGMENTS The authors acknowledge financial support from the National Natural Science Foundation of China (Grant Nos. 51502141, 91733301, 91433203, 61474049 and 21702069), the Ministry of Science and Technology of China (863, 2015AA034601), the Science and Technology Department of Hubei Province (No. 2017AAA190), the 111 Project (No. B07038), the China Postdoctoral Science Foundation (2016M602292, 2017M612452), Special financial aid to post-doctor research fellow (2017T100548) and the Science and Technology Department of Jiangsu Province (BK20150920). We thank the Analytical and Testing Center of Huazhong University of Science and Technology (HUST) for performing various characterization and measurements.

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(10) Dong, Q.; Fang, Y.; Shao, Y.; Mulligan, P.; Qiu, J.; Cao, L.; Huang, J., Electron-hole diffusion lengths > 175 µm in solution-grown CH3NH3PbI3 single crystals. Science 2015, 347, 967-970. (11) D'Innocenzo, V.; Grancini, G.; Alcocer, M. J.; Kandada, A. R.; Stranks, S. D.; Lee, M. M.; Lanzani, G.; Snaith, H. J.; Petrozza, A., Excitons versus free charges in organo-lead tri-halide perovskites. Nat. Commun. 2014, 5, 3586. (12) Rong, Y.; Liu, L.; Mei, A.; Li, X.; Han, H., Beyond Efficiency: the challenge of stability in mesoscopic perovskite solar cells. Adv. Energy Mater. 2015, 5, 1501066. (13) Wang, Z.; Shi, Z.; Li, T.; Chen, Y.; Huang, W., Stability of perovskite solar cells: a prospective on the substitution of the A Cation and X Anion. Angew. Chem. Int. Ed. 2017, 56, 1190-1212. (14) Domanski, K.; Correa-Baena, J.-P.; Mine, N.; Nazeeruddin, M. K.; Abate, A.; Saliba, M.; Tress, W.; Hagfeldt, A.; Grätzel, M. Not all that glitters is gold: metal-migration-induced degradation in perovskite solar cells. ACS Nano 2016, 10, 6306-6314. (15) Yuichi, K.; K., O. L.; V., L. M.; Shenghao, W.; R., R. S.; Yabing, Q. Silver iodide formation in methyl ammonium lead iodide perovskite solar cells with silver top electrodes. Adv. Mater. Interfaces 2015, 2, 1500195. (16) Habisreutinger, S. N.; Mcmeekin, D. P.; Snaith, H. J.; Nicholas, R. J., Research Update: Strategies for improving the stability of perovskite solar cells. APL Mater. 2016, 4, 643. (17) Ku, Z.; Rong, Y.; Xu, M.; Liu, T.; Han, H., Full printable processed mesoscopic CH3NH3PbI3/TiO2 heterojunction solar cells with carbon counter electrode. Sci. Rep. 2013, 3, 3132. (18) Anyi, M.; Xiong, L.; Linfeng, L.; Zhiliang, K.; Tongfa, L.; Yaoguang, R.; Mi, X.; Min, H.; Jiangzhao, C.; Ying, Y., A hole-conductor-free, fully printable mesoscopic perovskite solar cell with high stability. Science 2014, 345, 295-298. (19) Rong, Y.; Liu, L.; Mei, A.; Li, X.; Han, H., Beyond efficiency: the challenge of stability in mesoscopic perovskite solar cells. Adv. Energy. Mater. 2015, 5, 1501066. (20) Li, X.; Tschumi, M.; Han, H.; Babkair, S. S.; Alzubaydi, R. A.; Ansari, A. A.; Habib, S. S.; Nazeeruddin, M. K.; Zakeeruddin, S. M.; Grätzel, M. Outdoor performance and stability under elevated temperatures and long-term light soaking of triple-layer mesoporous perovskite photovoltaics. Energy Tech. 2015, 3, 551-555. (21) Hu, Y.; Si, S.; Mei, A.; Rong, Y.; Liu, H.; Li, X.; Han, H., Stable large-area printable mesoscopic perovskite module exceeding 10% efficiency. Solar RRL 2017, 1, 1600019. (22) Rong, Y.; Ming, Y.; Ji, W.; Li, D.; Mei, A.; Hu, Y.; Han, H. Toward industrial-scale production of perovskite solar cells: screen printing, slot-die coating, and emerging techniques. J. Phys. Chem. Lett. 2018, 9, 2707-2713. (23) Wei, Z.; Chen, H.; Yan, K.; Zheng, X.; Yang, S., Hysteresis-free multi-wall carbon nanotube-based perovskite solar cells with a high fill factor. J. Mater. Chem. A. 2015, 3, 24226-24231. (24) Yan, K.; Wei, Z.; Li, J.; Chen, H.; Yi, Y.; Zheng, X.; Xia, L.; Wang, Z.; Wang, J.; Xu, J., High-performance graphene-based hole conductor-Free perovskite solar cells: schottky junction enhanced hole extraction and electron blocking. Small 2015, 11, 2269-2274. (25) Zheng, X.; Chen, H.; Li, Q.; Yang, Y.; Wei, Z.; Bai, Y.; Qiu, Y.; Zhou, D.; Wong, K. S.; Yang, S., Boron doping of multiwalled carbon nanotubes significantly enhances hole extraction in carbon-based perovskite solar cells. Nano Lett. 2017, 17, 2496-2505.

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(26) Zhang, L.; Liu, T.; Liu, L.; Hu, M.; Yang, Y.; Mei, A.; Han, H., The effect of carbon counter electrodes on fully printable mesoscopic perovskite solar cells. J. Mater. Chem. A 2015, 3, 9165-9170. (27) Duan, M.; Tian, C.; Hu, Y.; Mei, A.; Rong, Y.; Xiong, Y.; Xu, M.; Sheng, Y.; Jiang, P.; Hou, X.; Zhu, X.; Qin, F.; Han, H. Boron-doped graphite for high work function carbon electrode in printable hole-conductor-free mesoscopic perovskite solar cells. ACS Appl. Mater. Interfaces 2017, 9, 31721-31727. (28) Xu, X.; Liu, Z.; Zuo, Z.; Zhang, M.; Zhao, Z.; Shen, Y.; Zhou, H.; Chen, Q.; Yang, Y.; Wang, M., Hole selective NiO contact for efficient perovskite solar cells with carbon electrode. Nano Lett. 2015, 15, 2402-2408. (29) Jiang, P.; Jones, T. W.; Duffy, N. W.; Anderson, K. F.; Bennett, R.; Grigore, M.; Marvig, P.; Xiong, Y.; Liu, T.; Sheng, Y., et al. Fully printable perovskite solar cells with highly-conductive, low-temperature, perovskite-compatible carbon electrode. Carbon 2017, 129, 830-836. (30) Rong, Y.; Hu, Y.; Ravishankar, S.; Liu, H.; Hou, X.; Sheng, Y.; Mei, A.; Wang, Q.; Li, D.; Xu, M.; Bisquert, J.; Han, H. Tunable hysteresis effect for perovskite solar cells. Energy Environ. Sci. 2017, 10, 2383-2391. (31) Chen, H.; Yang, S., Carbon-based perovskite solar cells without hole transport materials: the front runner to the market? Adv. Mater. 2017, 29,1603994. (32) Liu, Z.; Zhang, M.; Xu, X.; Cai, F.; Yuan, H.; Bu, L.; Li, W.; Zhu, A.; Zhao, Z.; Wang, M., NiO nanosheets as efficient top hole transporters for carbon counter electrode-based perovskite solar cells. J. Mater. Chem. A. 2015, 3, 24121-24127. (33) Rong, Y.; Hou, X.; Hu, Y.; Mei, A.; Liu, L.; Wang, P.; Han, H., Synergy of ammonium chloride and moisture on perovskite crystallization for efficient printable mesoscopic solar cells. Nat.Commun. 2017, 8, 14555. (34) Hu, Y.; Zhang, Z.; Mei, A.; Jiang, Y.; Hou, X.; Wang, Q.; Du, K.; Rong, Y.; Zhou, Y.; Xu, G.; Han, H. Improved performance of printable perovskite solar cells with bifunctional conjugated organic molecule. Adv. Mater. 2018, 30, 1705786.

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The Journal of Physical Chemistry 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

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TOC graphic Hybrid carbon electrode

Single carbon electrode

c-C m-C/perovskite

m-C/perovskite

ZrO2/perovskite

ZrO2/perovskite

LTC TiO2/perovskite

TiO2/perovskite

Efn

Efn VOC

VOC

Efp

Efp

m-C

m-C

FTO

Perovskite/m-C

TiO2 ZrO2

FTO

c-C

Perovskite/m-C

TiO2 ZrO2

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The Journal of Physical Chemistry

Figure 1. Schematic configuration and energy band diagram of printable mesoscopic PSCs with a single m-C layer (a, c) and a hybrid m-C/c-C layer (b, d) as the counter electrode. Efn and Efp are the electron and hole quasi-Fermi levels, respectively. 119x108mm (300 x 300 DPI)

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The Journal of Physical Chemistry 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Figure 2. (a) The photograph of printable mesoscopic PSCs based on hybrid carbon electrodes with NiO, MoO3, Co2O3 and CuO, respectively; (b-c) The SEM cross-section images and EDX elements mapping of printable mesoscopic PSCs based on hybrid carbon electrode with NiO and MoO3. 119x107mm (300 x 300 DPI)

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The Journal of Physical Chemistry

Figure 3. (a) XRD patterns of the pristine m-C layer and m-C layers with 10%, 30%, and 50% NiO; (b) Sheet resistance of the pristine m-C layer and m-C layers with 10%, 30%, and 50% NiO (the thickness is ~10 µm). For the average and s.d. values, the results were obtained with 5 samples prepared with the same condition; (c) Work function of the pristine m-C layer and m-C layers. For the average and s.d. values, the results were obtained with 8 samples prepared with the same conditions; (d) Time-resolved photoluminescence (TRPL) spectra of the samples of perovskite/m-C, perovskite/(m-C/10%NiO), perovskite/(m-C/30%NiO) and perovskite/(m-C/50%NiO). 119x89mm (300 x 300 DPI)

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The Journal of Physical Chemistry 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Figure 4. Photovoltaic parameters of devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO. The thickness of the insulating ZrO2 layer varies from 500 nm to 3 µm. For the average and s.d. values, the results were obtained from 5 devices prepared with the same condition. 119x87mm (300 x 300 DPI)

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The Journal of Physical Chemistry

Figure 5. (a) Current density-voltage (J-V) characteristics measured from forward bias to reverse bias under simulated AM 1.5 G illumination (100 mW cm-2) condition and in the dark of the representative devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO and with 500 nm ZrO2 layer; (b) Impedance spectroscopy characterizations of the devices; The Nyqusit plots are collected in the frequency range of 50 mHz to 4 MHz under illumination at 10 mW cm-2 with applied bias of 0.5 V. The solid line are the fitted curves; (c, d) Charge transport lifetime (τt) and recombination time (τr) obtained by fitting the transient photocurrent/photovoltage decay curves for devices based on hybrid carbon electrodes with 10%, 30% and 50% NiO. 119x93mm (300 x 300 DPI)

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TOC 80x68mm (300 x 300 DPI)

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