Thermally Stable Perovskite Solar Cells by Systematic Molecular Design of the Hole-Transport Layer

Schloemer, Tracy H.; Gehan, Timothy S.; Christians, Jeffrey A.; Mitchell, David; Dixon, Alex; Li, Zhen; Zhu, Kai; Berry, Joseph J.; Luther, Joseph M.; Sellinger, Alan

doi:10.1021/acsenergylett.8b02431

Cited by 69 publications

(93 citation statements)

References 49 publications

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“…However, the complicated synthesis procedures and low yield of Spiro‐OMeTAD make its price very expensive, triggering the researchers over the world to search for/develop efficient and low‐cost alternative HTMs. To date, many alternative HTMs constructed with different conjugated core units, such as phenothiazine, thiophene, phenoxazine, silolothiophene, triazines, and tetraphenylethene, have been reported . Benzotriazole (BTA) is a cheap and commercially available material, which has been widely used in designing sensitizers for dye‐sensitized solar cells by reason of the outstanding electron‐accepting property.…”

Section: Summary Of Optical and Electrochemical Properties Of 2fbta‐1mentioning

confidence: 99%

Fluorine‐Substituted Benzotriazole Core Building Block‐Based Highly Efficient Hole‐Transporting Materials for Mesoporous Perovskite Solar Cells

Chen

et al. 2020

Solar RRL

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Two novel donor–accepter–donor structured hole‐transporting materials based on fluorine‐substituted benzotriazole (BTA) core building blocks (2FBTA‐1 and 2FBTA‐2) are designed and synthesized through molecular regulation. Applying these materials into perovskite solar cells, power conversion efficiencies of 7.55% and 17.94% are obtained for 2FBTA‐1 and 2FBTA‐2, respectively. The better photovoltaic performance of 2FBTA‐2 is attributed to its more suitable energy level, more planar molecular configurations, and higher hole mobility. Moreover, the devices with 2FBTA‐2 as hole transport material (HTM) show good stability in air. The results indicate that BTA is a promising building block for future HTM design.

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Section: Summary Of Optical and Electrochemical Properties Of 2fbta‐1mentioning

confidence: 99%

Fluorine‐Substituted Benzotriazole Core Building Block‐Based Highly Efficient Hole‐Transporting Materials for Mesoporous Perovskite Solar Cells

Chen

et al. 2020

Solar RRL

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“…[ 18,23,24 ] The chemical structure of spiro‐OMeTAD is shown in Figure a. Although other small molecules, [ 25–27 ] polymers, [ 28–30 ] and inorganics [ 31–33 ] have been developed for the HTLs of PSCs, spiro‐OMeTAD is still excellent among the reported HTL materials in terms of PCEs. PSCs with spiro‐OMeTAD are comparably stable at room temperature.…”

Section: Introductionmentioning

confidence: 99%

Understanding the Degradation of Spiro‐OMeTAD‐Based Perovskite Solar Cells at High Temperature

et al. 2020

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Organic-inorganic halide perovskites are promising as the light absorber of solar cells because of their efficient solar power conversion. An issue frequently occurring in perovskite solar cells (PSCs) with a hole transport layer of N,N-di (4-methoxyphenyl)amino]-9,9 0-spirobifluorene (spiro-OMeTAD) is a quick performance degradation at high temperature. Herein, it is discovered that postdoping of the spiro-OMeTAD layer by iodine released from the perovskite layer is one possible mechanism for the high-temperature PSC degradation. Iodine doping leads to the highest occupied molecular orbital level of the spiro-OMeTAD layer becoming deeper and, therefore, induces the formation of an energy barrier for hole extraction from the perovskite layer. It is demonstrated that it is possible to suppress the high-temperature degradation by using an iodine-blocking layer or an iodine-free perovskite in PSCs. These findings will guide the way for the realization of thermally stable perovskite optoelectronic devices in the future.

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“…[ 118–120,125 ] Spiro‐OMeTAD can be processed at room temperature out of orthogonal solvents (chlorobenzene) but is known to have poor temperature stability, because its dopants are too mobile, and will crystallize if heated, potentially causing mechanical deformations to the recombination stack and thus decreasing the solvent barrier properties. [ 165,166 ] This highlights the fact that each CL chosen brings their own complications to tandem fabrication, either through potential processing incompatibilities or instabilities.…”

Section: Tandem Fabrication: a Story Of Compromisementioning

confidence: 99%

“…[ 19,178,179 ] In n–i–p devices, Spiro‐OMeTAD is one of the most commonly used HTLs to reach high‐efficiency in a single junction, but has poor device operational and temperature stability and is likely the cause for the ≈100 °C ceiling in n–i–p tandems. [ 13,165 ] There are ample studies that explain the poor stability of spiro‐OMeTAD, [ 13,120,165,180 ] but the ISOS testing protocols (ISOS‐L‐1, 2, 3) [ 152–154 ] used are likely much more rigorous than what is required strictly for tandem fabrication, although all tandems should be made with the goal of passing these ISOS tests. This 100 °C ceiling does not limit perovskite fabrication but does limit the use of more traditional ETLs, such as TiO 2 or SnO 2 , for the CL3 because of the required higher annealing temperatures.…”

Section: Tandem Fabrication: a Story Of Compromisementioning

confidence: 99%

Choose Your Own Adventure: Fabrication of Monolithic All‐Perovskite Tandem Photovoltaics

et al. 2020

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power conversion efficiencies (PCE) certified over 25% [9] merely 10 years after their first report (no small feat). [10,11] Perovskites have also made rapid progress in stability [12] (which is arguably their Achilles heel) now with regular reports of thousands of hours, [13-17] reaching up to one year, [18] of device operational stability, even at elevated temperatures. [19,20] Finally, there have been impressive efforts in scaling the MHP deposition methods to maintain film uniformity over larger areas, through the use of novel solvent chemistries [21-23] and a variety of processing techniques [24,25] which has culminated in a certified 17.25% PCE for a ≈20 cm 2 module [26] and 17.9% PCE for a >800 cm 2 module. [27] An additional unique characteristic of MHPs is the ability to widely tune the composition of ABX 3 where A is usually a mixture of methylammonium (MA +), formamidinium (FA +) and cesium (Cs +); B can be a mixture of Pb 2+ and Sn 2+ ; and X is typically a mixture of I − , Br − , and Cl −. Changing the composition allows the bandgap (E g) to be modulated from ≈1.2 to >2.4 eV. [28-32] A large range of compositions and bandgaps have been used to make solar cells with PCEs over 20%. [4,33-39] The ability to reach high efficiencies at a wide range of bandgaps naturally motivates the use of perovskites in multijunction photovoltaics with various absorbers employed in tandem. By coupling together two MHPs with complementary bandgaps into a tandem device (Figure 1A), the incident solar spectrum can be more efficiently converted than in a single bandgap device by reducing the thermalization losses. This loss reduction increases the maximum attainable PCE. [40] Pairing the high efficiency (>30%) with the promises for ultralow cost manufacturing and light weight makes all-perovskite tandems one of the most exciting PV technologies in a generation. This combination of characteristics not only has the potential to further lower the solar electricity costs, but also to open the field to applications beyond the capabilities of the crystalline silicon dominant market, such as unmanned aerial vehicles. [41-44] While single-junction perovskite cells currently have demonstrated the highest efficiencies among polycrystalline thin-film PVs, they are likely to have a maximum practical efficiency of ≈28% PCE whereas all-perovskite tandems have a clear path to well over 30%. [40,45] There has been a flurry of work on monolithic, 2-terminal (2T) perovskite-based tandems, pairing a wide-E g MHP with materials such as low-E g tin/lead (Sn/Pb) Metal halide perovskites (MHPs) have transfixed the photovoltaic (PV) community due to their outstanding and tunable optoelectronic properties coupled to demonstrations of high-power conversion efficiencies (PCE) at a range of bandgaps. This has motivated the field to push perovskites to reach the highest possible performance. One way to increase the efficiency is by fabricating multijunction solar cells, which can split the solar spectrum, reducing thermalization loss. Low-cost all-pero...

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Thermally Stable Perovskite Solar Cells by Systematic Molecular Design of the Hole-Transport Layer

Cited by 69 publications

References 49 publications

Fluorine‐Substituted Benzotriazole Core Building Block‐Based Highly Efficient Hole‐Transporting Materials for Mesoporous Perovskite Solar Cells

Fluorine‐Substituted Benzotriazole Core Building Block‐Based Highly Efficient Hole‐Transporting Materials for Mesoporous Perovskite Solar Cells

Understanding the Degradation of Spiro‐OMeTAD‐Based Perovskite Solar Cells at High Temperature

Choose Your Own Adventure: Fabrication of Monolithic All‐Perovskite Tandem Photovoltaics

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