Abstract
The benchmark tin oxide (SnO2) electron transporting layers (ETLs) have enabled remarkable progress in planar perovskite solar cell (PSCs). However, the energy loss is still a challenge due to the lack of “hidden interface” control. We report a novel ligand-tailored ultrafine SnO2 quantum dots (QDs) via a facile rapid room temperature synthesis. Importantly, the ligand-tailored SnO2 QDs ETL with multi-functional terminal groups in situ refines the buried interfaces with both the perovskite and transparent electrode via enhanced interface binding and perovskite passivation. These novel ETLs induce synergistic effects of physical and chemical interfacial modulation and preferred perovskite crystallization-directing, delivering reduced interface defects, suppressed non-radiative recombination and elongated charge carrier lifetime. Power conversion efficiency (PCE) of 23.02% (0.04 cm2) and 21.6% (0.98 cm2, VOC loss: 0.336 V) have been achieved for the blade-coated PSCs (1.54 eV Eg) with our new ETLs, representing a record for SnO2 based blade-coated PSCs. Moreover, a substantially enhanced PCE (VOC) from 20.4% (1.15 V) to 22.8% (1.24 V, 90 mV higher VOC, 0.04 cm2 device) in the blade-coated 1.61 eV PSCs system, via replacing the benchmark commercial colloidal SnO2 with our new ETLs.
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Introduction
The organic–inorganic hybrid perovskite (OIHP) materials have attracted enormous research interests1,2,3,4,5,6, owing to the unique merits including material abundancy, low cost, long carrier diffusion lengths up to micrometer scale7, tunable bandgap8, high defects tolerance4, outstanding and bipolar carrier transport properties9,10, and high absorption coefficient11,12. OIHPs have been highlighted to be promising candidates for various optoelectronic applications, such as lasers13, photodetectors14, radiation detectors15, memories16, water splitting, X-ray imagers17,18, light emission diodes (PeLEDs)19, and in particular solar cells. At present, mesoporous titanium oxide (TiO2) nanostructures are the efficient electron transporting layer (ETL) materials for regular n–i–p structure PSCs, delivering a certified PCE of 25.2% with stable power output20. Although mesoporous TiO2 ETL-based PSCs lead the efficiency competition, the high-crystallization annealing temperature is required to ensure high carrier mobility and high film quality of TiO2, which leads to longer energy payback time, also hinders the application in flexible and stretchable devices. Moreover, TiO2-based planar PSCs tend to suffer more photocatalytic issues21.
It is expected that a reliable ETL for efficient PSCs should possess good energy alignment, high mobility, good stability, and high transmittance22. Recently, SnO2-based ETLs1,6,23,24,25,26 have been extensively utilized in PSCs and are considered as the most promising candidate to replace TiO2. SnO2 owns a wide bandgap (Eg) above 3.8 eV and favorable conduction band edge facilitating more efficient charge transfer27. Furthermore, SnO2 exhibited outstanding chemical stability, less photocatalytic degradation, and good electron mobility22,28. Intense research efforts have targeted on the development of highly efficient SnO2 ETLs that allow PCEs to boost up to 23.3% based on commercial colloidal SnO2 ETL, with a low hysteresis, valued by h-index ((PCEreverse−PCEforward)/PCEreverse)1,6,23,24,25,29,30,31,32,33,34,35. Although positive progresses have been demonstrated in those SnO2-based PSCs, the electronic and structural properties (e.g., conductivity, physical and electrical contact, work function, defects level) of SnO2 still highly depend on the synthesis approaches and fabrication conditions. On the other hand, polycrystalline PSCs inevitably possess a large number of crystallographic defects36,37,38, such as interfacial dangling bonds and uncoordinated ions (I−, Pb2+, Cs+, Rb+, K+), which result in increased nonradiative recombination and potential hysteresis issue. Hence, modifications or post-treatments (e.g., metallic ion doping, functional molecular coordinating, semiconducting polymers coating, fullerenes, and fullerene derivatives anchoring) of SnO2 ETLs have been introduced to alleviate interfacial charge recombination and promote carrier extraction, delivering favorable electronic and physical interfacial contact39,40,41,42,43,44. Unfortunately, most of these reported approaches incorporate the additional modification layer which inevitably increases the uncertainty (e.g., complexity, cost, and unreliability) during the scalable manufacturing procedure of PSCs. Moreover, weak interactions between the additional modifier(s) and ETL could be an issue on interfacial electronic contact and device stability45. In addition, reinforced interfacial interactions and high-quality low-temperature processed SnO2 ETLs are critical for flexible and stretchable PSC device manufacturing.
In this work, we report a facile, ligands-assisted, rapid formulated room-temperature synthetic approach for novel multi-functional terminal groups anchored SnO2 QDs, which function as excellent ETLs to in situ manipulate the interfacial contact in planar perovskite solar cells. Such ligand-tailored SnO2 QDs exhibited superior properties over the current benchmark materials (e.g., alcohol-based SnO2 and commercialized colloidal SnO2). The ligand-tailored SnO2 QDs ETLs in planar PSCs show threefold benefits: 1. the ligand-tailored SnO2 QDs not only passivated perovskite at the buried interface with ETL, but also work as a seeding-controlling agent to direct the subsequent high-quality perovskite crystallization, resulting in suppressed non-radiative recombination and elongated charge carrier lifetime; 2. the ultrafine SnO2 QDs act as interfacial “glue” to bridge the perovskite and transparent electrode both chemically and physically, resulting in a favorable electronic and physical interfacial contact; 3. The new SnO2 QDs ETLs allow the crystallization temperature to be lowered to 100 °C, providing a new opportunity for flexible substrate manufacturing. The substantial suppressed non-radiative recombination and reduced buried interface defects are supported with enhanced electroluminescence quantum efficiency (ELQE). In addition, the device stability (humidity, thermal, UV) is noticeably improved. With these improved aspects, the ligand-tailored SnO2 QDs ETL-based devices achieve a high PCE (reverse scan (RS)) of 23.02% (22.51% verified by an ISO/IEC 17025:2005 accredited certification laboratory) in a 1.541 eV bandgap perovskite system. It is noteworthy that a substantially enhanced PCE (VOC) from 20.4% (1.152 V) to 22.8% (1.242 V, 90 mV higher VOC, 0.04 cm2 device) in the blade-coated 1.613 eV PSCs system, via replacing the benchmark commercial colloidal SnO2 ETL with our ligand-tailored SnO2 QDs. We further investigate the feasibility of the ultrafine SnO2 QDs ETL in the upscaling of different PSC systems (Eg = 1.541 and 1.613 eV, respectively, Fig. S1) via manufacturing friendly blade-coating process. We achieve blade-coated devices with 21.6% (0.98 cm2, an impressive VOC loss of only 0.336 V) in a 1.541 eV and 20.7% PCE (0.8 cm2) in a 1.613 eV perovskite system, representing a record PCE for SnO2 ETL-based upscaling blade-coated PSCs to the best of our knowledge. Moreover, we successfully achieved 30 × 30 mm2 mini-modules with 19.5% PCE in 1.541 eV (two sub-cells) and 18.9% in 1.613 eV (three sub-cells) perovskite systems. Therefore, the in situ solution chemistry engineering of metal oxide synthesis contrives a new direction toward achieving low temperature and high-quality functionalized SnO2 ETLs, and is compatible with upscaling of large-area high-quality films in perovskite-based photoelectronic devices.
Results
The organic ligand 2-(2-aminoethyl) isothiourea dihydrobromide (2AT) was introduced in SnO2 QDs synthesis, on the basis that it possesses two types of organic amine terminal groups (a primary amine and a formamidine), which not only facilitate the stabilization and in situ multi-functionalization of the SnO2 QDs but also allow for favorable interfacial passivation through chemical bonding. The chemical structure of the 2AT additive is shown in Fig. 1a, which contains multiple functional terminal groups, including amino (–NH2), imino (–NH), 2-aminoethyl (–CH2–CH2–NH2), and bromide (–Br). The SnO2 QDs solution was synthesized by hydrolysis of tin source (SnCl2·2H2O) with the assist of a small amount of 2AT additive under O2-rich ambient at room temperature via vigorous stirring. Generally, tin source (SnCl2·2H2O) experiences the following main reaction processes (hydrolysis, dehydration, and oxidation)46:
During the hydrolysis step, white precipitate, Sn(OH)Cl, Sn(OH)2, can be generated once SnCl2·2H2O was dissolved into deionized water due to its rapid hydrolysis nature, and then undergoes a dehydration-oxidation process46,47. Consequently, SnO2 QDs transparent yellow aqueous solution can be obtained. Previous studies have demonstrated that SnCl2·2H2O could gradually self-convert into SnO2 colloids via a hydrolysis-oxidation process. However, the resultant aqueous solution is extremely unstable in which SnO2 colloids are prone to aggregate and precipitate, and the synthesis process is time-consuming (several days). In our new solution chemistry strategy, with the assist of 2AT additive, the milky suspension rapidly transforms into a semitransparent bright SnO2 solution and then converts into the yellowish SnO2 solution within 2 h (Figs. 1a and S2), which can be stored for over 3 months without any aggregation and precipitation. These results indicated that the new 2AT additive not only helps in accelerating the hydrolysis–dehydration–oxidation process of SnCl2·2H2O, but also renders the resultant SnO2 solution immune to aggregation and precipitation so that good chemical stability can be attained. This is because the consumption of the hydrogen chloride (see Eq. (1)) by the presence of 2AT additive largely enables an ongoing hydrolysis process and finally accelerated the formation of SnO2 QDs solution. Moreover, thanks to the multi-functional terminal groups of 2AT additive, metal ion (Sn2+, Sn4+) could be chemically interacted with S functionalities of 2AT while the protonated organic amine terminal groups with positive charges are surrounding the as-prepared SnO2 QDs36,46,48, delivering small particle size and suppressed solution aggregation. In addition, these functional groups possibly facilitate the formation of more nuclei at the beginning of the hydrolysis process and thus smaller SnO2 particle size can be obtained due to suppressed segregation by the protonated functional groups. Similar colloidal QDs size control phenomena have been reported in copper indium sulfide/zinc sulfide (CIS/ZnS) core/shell system, cadmium selenide (CdSe) QDs, etc.31,49,50.
To check the difference between our SnO2 QDs and other SnO2, we performed the dynamic light scattering (DLS) measurement as shown in Fig. S3. In the commercial SnO2 NPs solution, DLS showed three Gaussian distributions—i.e., three different sizes (~2, ~13, and ~2500 nm), which is in good agreement with the previous literatures32,51. The DLS of the c-SnO2 also shows three Gaussian peaks (~1, ~5, ~150 nm). While in the 2AT–SnO2 QDs solution, we observed only one Gaussian distribution in small size (~7 nm), which indicated that 2AT–SnO2 QDs are uniformly distributed in the solution with a small deviation in particle size. It should be noted that the method of DLS usually overestimates the absolute particle or cluster size due to the multiple scattering process and electrical double layer around the particle51,52. Furthermore, we investigate the influence of 2AT concentration on SnO2 particle size (Fig. S4). During the synthesis process, in the case of optimal 2AT concentration (also further increasing concentration of 2AT by 5 times), DLS shows only one Gaussian distribution in small size (~7 nm). If too less 2AT (e.g., by decreasing the concentration of 2AT by 10 times during the synthesis process), we observed two Gaussian distributions in small size (~5 nm) and large size (~150 nm). This suggests that insufficient 2AT leads to the partial segregation of SnO2 QDs.
We incorporated SnO2 QDs equipped with multi-functional groups as ETL in planar PSCs. SnO2 QDs-based planar PSC with the architecture of fluorine-doped SnO2 (FTO)/SnO2 QDs/perovskite/spiro-OMeTAD/Au, as demonstrated in Figs. 1b and S5. The morphology of SnO2 QDs was confirmed by transmission electron microscopy (TEM). Figure 1c (1) and Fig. S6 shows the SnO2 QDs with an average size of 2–2.5 nm were uniformly distributed on the TEM copper grid. High-resolution TEM (HR-TEM) results suggested that the SnO2 QDs are highly crystallized which is beneficial to yield a defect-reduced SnO2 film. The lattice fringes of the (110) crystal plane with a space distance of around 0.33 nm are clearly observed as shown in Fig. 1c (2). According to the corresponding selected area electron diffraction (SAED) pattern in Fig. 1c (3), electron reflection rings from the (110), (101), (211), and (310) crystal planes of SnO2 were observed which suggest that the SnO2 QDs are polycrystalline. Scanning transmission electron microscopy (STEM) together with electron energy loss spectra (EELS) was performed to further characterize the SnO2 QDs. Figure 1d shows the selected area of high-angle annular dark-field (HAADF) STEM image and the corresponding EELS maps of Sn and O signals, indicating that the prepared SnO2 QDs films are composed of Sn and O elements. Scanning electron microscopy (SEM) is used to examine the surface morphology of SnO2-coated FTO glass substrate. For comparison, we investigated three types of SnO2 ETLs: alcohol-based SnO2 (c-SnO2), commercialized SnO2 nanoparticles (NPs), and SnO2 QDs. The bare FTO substrate shows a clear and rough morphology due to the nature of large FTO grains (Fig. S7A). Among the three types of SnO2-coated FTO glass substrates, shown in Fig. S7B–D, the SnO2 QDs demonstrate a smoother and full coverage surface coating, evidenced by the less FTO features in the morphology by SEM (Fig. S7) and AFM images (Fig. S8). This agrees with the ultrafine size of the ligand-tailored SnO2 QDs which are beneficial for surface physical defects filling. Considering that the feature of FTO retains a rough surface (Fig. S7A), the quality of physical contact at the interface between the FTO and ETL should be a critical factor on obtaining high electron extraction efficiency with less interface defects. Recently, Choi and co-workers revealed that high surface roughness of FTO, surface energies mismatch, and volume shrinkage of ETL on FTO surface give rise to the formation of physical defects at the interfaces, led to a reduced physical contact area53. Similarly, Segawa group showed that a rough interface can trigger the local-heavy doping caused by the electrostatic dipole, resulting in tunneling phenomenon which can induce the hysteresis in the perovskite solar cell54. Based on the above reported experimental results, we performed SEM, STEM, and HR-TEM to explore the quality of interface contact between the FTO and ETL. In our study, we investigated the c-SnO2/FTO, SnO2 NPs/FTO, and SnO2 QDs/FTO to explore surface covering (or physical defects filling) ability of these ETLs on FTO substrate. We clearly observe a poor physical contact feature in the c-SnO2/FTO interface as shown in Fig. 2a, in which the red arrows reveal the distribution of physical defects. This suggests that the FTO grooves (or valleys) filling ability of c-SnO2 is much weaker than that of our SnO2 QDs (Fig. 2), and commercial SnO2 NPs (Fig. S9). To gain more solid evidence, focused ion beam (FIB) workstation equipped with an in situ micromanipulator was utilized to prepare samples for STEM and HR-TEM imaging. We prepared samples with the architecture of Pt/Carbon/ETL/FTO by lift-off FIB technique (see details in “Materials and methods” and Fig. S10A), as depicted in the HAADF-STEM cross-sectional images in Fig. 2b and d. We directly observed that the rough interface (ETL/FTO) is composed of many FTO nanopyramids. A significant difference in the physical contact of the FTO coated with c-SnO2 and SnO2 QDs (Fig. S10B and S10C) is noted. The dotted red circles (Fig. 2b) show examples of physical defects (the void area). In more detail, the observation on c-SnO2/FTO sample by HAADF-STEM image demonstrates that an uneven distribution feature of c-SnO2 (at areas that were very thick or very thin). This is mainly due to fact that alcoholysis processed c-SnO2 suffers from volume shrinkage of SnO2 films (for example, from SnCl2 to SnO2). Further enlarged HAADF-STEM image reveals that physical defects (the voids) at the valley of c-SnO2/FTO, which is further hammered by HAADE-STEM-EELS cross-sectional element mapping (Fig. 2c). As expected, all elements including F, Sn, and O are identified in c-SnO2/FTO, indicating that c-SnO2 is unevenly distributed (partial shortage, the void) at the protruding areas and the valley of FTO pyramids. As compared to the interface quality of the c-SnO2/FTO sample, the SnO2 QDs/FTO sample exhibit a highly uniform distribution of SnO2 QDs clinging to the FTO, resulting in a physical defect-free interface and reinforced interfacial contact as confirmed by further enlarged HAADF-STEM image (Fig. 2d). The above observations are much more convincingly proved by HAADE-STEM-EELS cross-sectional element mapping (Fig. 2e), indicating that the 2AT additive assisted synthesis process yields SnO2 QDs that fully cover the apexes and grooves (or valleys) of FTO pyramids, delivering a better interfacial physical contact between the FTO and ETL. This can be ascribed to the ultrafine quantum dot particle size of SnO2 crystallites, resulting in improved surface filling ability and suppressed volume shrinkage.
To probe the chemical bonding state of SnO2, X-ray photoelectron spectroscopy (XPS) measurement was conducted for the c-SnO2, SnO2 NPs, and SnO2 QDs films on Silicon substrates. Figure S11 shows the O 1s core level signals from 2AT-SnO2 QDs and commercial SnO2 NPs, the O 1s peaks can be deconvolved into two individual peaks. The peaks at lower and higher binding energy were originated from Sn–O–Sn backbones serving as electron conductance pathways and the hydroxide species (Sn–OH) acting as shallow trap sites34,55. Accordingly, the 2AT SnO2 QDs exhibit a lower impurity level compared to the benchmark commercial SnO2 NPs. It is suggested that hydroxide species (shallow trap sites) can be effectively suppressed with the presence of 2AT within the SnO2. As demonstrated in Fig. 3b, we observe strong peaks at 487.5 and 495.8 eV, which are attributed to Sn4+ ion, and thus suggest the formation of SnO2. Meanwhile, the photoelectron binding energy of Sn 3d core level for SnO2 QDs film exhibit a blue chemical shift (toward high binding energy) in contrast to the c-SnO2 and SnO2 NPs film, indicating that an effective chemical bonding due to the presence of 2AT additive. In addition, we identified the core level signal of N1s, S2p, and Br3d, originating from the multi-functional groups of 2AT additive. Notably, N1s peak at 400.5 eV (Fig. S12A) from SnO2 QDs film is associated with the pronated –NH3+ terminal group of 2AT additive48,56, featuring successful chemical bonding of amino (or 2-aminoethyl) groups via Sn–N bond onto the surface of SnO2 QDs. Similarly, the signal of the S 2p core level (Fig. S12B) appears obviously in comparison with the c-SnO2 and SnO2 NPs film, which can be located at roughly 165.2 eV. This is generally assigned to the C–S–C (sulfide) or C–S–H (thiol)57,58, indicating the presence of sulfur species functionalities on SnO2 QDs. Besides, we also detected the characteristic signals of Br 3d core level located at a binding energy of 68.3 eV from SnO2 QDs (Fig. S12C). It is presumable that the peak could be responsible for the Sn–Br–O and Br–O state35,59, revealing that the Br ions from the 2AT additive are bonded to the Sn atoms of SnO2 QDs. We therefore indicate that SnO2 QDs were indeed equipped with multi-functional terminal groups, possibly by chemical interaction or surface anchoring. Based on the success of ligands-anchored SnO2 QDs, we proposed that multi-functional terminal groups of ligands-anchored SnO2 QDs effectively passivate interfacial imperfections36,38, such as deep level traps (e.g., uncoordinated Pb2+, Pb-I antisite defects, uncoordinated halide ion) and shallow level traps (e.g., halide vacancies and organic species vacancies), via coordinate bonding and ionic (hydrogen) bonding. As shown in Fig. 3a, organic amine terminal groups (a primary amine and a formamidine) of 2AT not only can occupy A-site vacancies (shallow level traps) but also passivating the undercoordinated Pb2+ or Pb-I antisite defects (deep level traps) at the interface of ETL/PVSK. Furthermore, the terminal –NH3+ cation of 2AT can passivate negatively charged defects or dangling bonds (uncoordinated halide ion) at the interface through ionic (hydrogen) bonding. In addition, sulfur species of ligand-tailored SnO2 QDs could afford interface passivation via coordinate bonding between uncoordinated Pb2+ and sulfur atom57. Exploiting the significantly beneficial effects of ligands-anchored SnO2 QDs on interface binding, high-quality perovskite film with efficient device performance can be achieved, as we will discuss below.
First, we examine the chemical bonding between 2AT-SnO2 QDs and perovskite –Pb 4f spectra of the 2AT-SnO2 QDs/perovskite and the SnO2 NPs/perovskite samples were investigated as demonstrated in Fig. S13. There are two main peaks Pb 4f7/2 and Pb 4f5/2 located at 138.76 and 143.61 eV, respectively. We attributed the two small noticeable peaks at 136.85 and 141.74 eV to the presence of metallic Pb, likely due to the existence of non-radiative recombination centers of commercial SnO2 NPs-based perovskite which is detrimental to device performance60. It is noted that the Pb 4f7/2 and Pb 4f5/2 of the 2AT-SnO2 QDs/perovskite sample show lower binding energies of 138.57 and 143.47 eV, respectively. This is probably due to the fact that Pb ion accepts electron pairs from the functional groups within 2AT via coordination bonding61. These chemical interactions significantly passivate the trap states, resulting in a long carrier lifetime and suppressed hysteresis. Moreover, we further increase the concentration of 2AT by five times in the SnO2 QDs, the Pb 4f peaks are further shifted by 0.35 eV towards the lower binding energy direction. This suggests that the ligands of 2AT in the SnO2 QDs have a stronger coordination interaction with the subsequent perovskite. In addition, partial ligands on SnO2 QDs surface could exchange or wash away during the coating of perovskite precursor, and these detached ligands contribute to the passivation in the bulk perovskite31.
Ultraviolet photoelectron spectroscopy (UPS) and UV–visible absorption spectra measurement were thoroughly conducted in order to determine the energy band diagram of ETLs and PVSK films, and the detailed results are summarized in the Supporting Information (Figs. S14, S15 and Table S1). We found that the energy-level diagram of the device with our ligand-tailored SnO2 QDs ETL exhibits a more favorable band alignment for charge transfer among these three ETLs. Capacitance–voltage measurements were conducted to further elucidate the effect of various ETLs on strengthening the built-in potential (Vbi) in PSCs by Mott–Schottky analysis (Fig. S16). Notably, an enhanced built-in potential enables a reinforced built-in field that efficiently sweeps out the photo-generated carriers. Importantly, this indicates that the separation of photo-generated carriers in SnO2 QDs based PSCs is more efficient and the reinforced Vbi provide more efficient driving force for the improvement in PCE.
To investigate the impact of multi-functional groups in SnO2 on the perovskite crystallization process, we first check the contact angles (Fig. 3c) of various ETLs-coated FTO substrates. The contact angle is a direct signature of the surface wettability which largely affects the surface nucleation density and Gibbs free energy for nucleation. That is, a lower contact angle value gives rise to a reduced Gibbs free energy, thus enabling a better nucleation process25. Taking c-SnO2 (43.7°) and SnO2 NPs (14.5°) coated FTO substrates as a comparison, we find that the SnO2 QDs sample shows the lowest contact angle (5.8°), which can be ascribed to the nature of hydrophilic organic amine terminal groups at the ligand-tailored SnO2 QDs. These results indicate that the SnO2 QDs sample effectively promotes a higher perovskite nucleation density which is responsible for an improved crystallization process resulting in a better crystallinity and enhanced interface physical binding (Figs. S17 and S18A). Therefore, we hypothesize that functional organic amine terminal groups of the ligands-armed SnO2 QDs possess the ability to act as a seeding-controlling agents to alter the crystallization kinetics resulting in improved crystallinity and favorable PVSK surface feature (Fig. S17D–L). To verify our hypothesis, we further carried out grazing incident wide-angle X-ray scattering (GIWAXS) to examine the quality of perovskite films. Figure 3d shows 2D GIWAXS patterns of perovskite films on the ETLs-coated quartz substrates, all the sample displays the typical scattering rings with a qr value (Fig. 3e) of 1.0, 2.0, and 2.2 Å−1 which corresponding to the (110), (220), and (310) planes62. It is noted that SnO2 QDs sample clearly demonstrates the highest diffraction (110) peak intensity at qr = 1.0 Å−1 compared to the other two samples, suggesting that a better crystallinity. To quantitatively estimate the non-radiative recombination in our devices, we tested our solar cells operating as LEDs under different voltage bias as shown in Fig. 3f and a bright red emission (~770 nm) can be observed (inset). Figure S18B suggests that the SnO2 QD-based PSCs as LED exhibit the lowest turn-on voltage over other two samples due to the reduced interfacial energy losses from carrier injection and transport63. Figure 3g shows the plot of ELQE as a function of current density. With a higher maximum ELQE (ELQEmax) of 4.4%, the SnO2 QD-based PSCs deliver a lower nonradiative Voc loss (∆Voc, nonrad) of 133 mV using ELQE @JSC injection (0.61%) according to literature64. In comparison, the ∆Voc, nonrad (ELQEmax & ELQEJsc injection) of c-SnO2 and SnO2 NPs based PSCs are ~187 mV (0.6% and 0.08%) and ~162 mV (1.3% and 0.12%), respectively. Detailed results are listed in the Supporting Information (Table S2). These results indicate that SnO2 QD-based samples effectively minimize the non-radiative recombination centers at the ETL/perovskite interface compared to other samples, resulting in an increased EL efficiency. Owing to the reduced interfacial energy loss, noticeably Voc improvement (~0.05 V) can be attained for SnO2 QD-based samples.
To further investigate the effect of different ETLs on the film quality of PVSK film under the micro-scale, we used confocal fluorescence microscopy to map the spatially resolved luminescence generation in these PVSK thin films, which allows us to visually analyze the microscale spatial heterogeneity of as-prepared PVSK films. As a correlative scan area, we start with an optical microscope image of the samples, this allows direct comparison between optical microscope images and confocal photoluminescence (PL) images. In Fig. 4a, we show the optical microscopy image of laser-patterned glass substrates, which suggest a regular squama-like textured feature (~50 μm width) row in a row. Figure 4b–D shows the optical microscopy of patterned glass/c-SnO2/PVSK, patterned glass/SnO2 NPs/PVSK, and patterned glass/SnO2 QDs/PVSK. Under an optical microscope, similar squama-like textured features were observed in the PVSK films upon the various ETLs coated patterned glass substrates. Figure 4e, f show the 120 µm-by-120 µm spatial confocal PL images of patterned glass/c-SnO2/PVSK, patterned glass/SnO2 NPs/PVSK, and patterned glass/SnO2 QDs/PVSK, which were acquired from different depth regions (Fig. 4h, level 1–8) within the perovskite layer with respect to the ETLs. We found that PL intensity becomes notably weaker when the detected region approach to the PVSK/ETLs interface and/or PVSK top surface, which is attributed to the quenching effect originated from carrier injection of SnO2 ETLs, recombination centers of PVSK/ETLs interface and PVSK surface defects (or strain-related defects), for example, dangling bonds, undercoordinated ions and dislocations36,38. We also observed that PL intensity of the c-SnO2 sample gives the weakest signal in the shallow probing depth (detected region: level 8), indicating that more surface defects are induced in the c-SnO2/PVSK sample, resulting in a significant PL quenching compared to SnO2 NPs/PVSK and SnO2 QDs/PVSK samples. This result also indicates that incorporation of ligands-functionalized SnO2 QDs ETL plays a role both in more efficient interface charge transfer and strengthening the overall passivation of non-radiative recombination, delivering an improved PVSK film quality. It is interesting to point out that in the confocal PL mapping image of patterned glass/c-SnO2/PVSK sample, we observed dim stripes pattern as well as a lot of heterogeneities, which are the evidence of non-radiative recombination centers65. In contrast, the PL intensity from SnO2 NPs/PVSK and SnO2 QDs/PVSK sample demonstrates a much more uniform and intense PL signal distribution. We attribute this dim stripe patterns along with the significant PL quenching to the increased physical defects (or non-radiative recombination center), which are located at the grooves between the two squama-like textured feature rows. This is due to the fact that c-SnO2/PVSK sample exhibits poor groove (or valley) filling ability. On the basis of the above results, it is well-confirmed that ligand-tailored SnO2 QDs are able to deliver a physical defects-free interface, suppressed non-radiative recombination, reduced PVSK surface defects, and provide a better seeding template to assist in the nucleation and subsequent perovskite growth.
To further explore the dynamics of charge carriers, perovskite films on various ETLs prepared on quartz substrates were investigated by nanosecond broadband transient absorption (TA) spectroscopy. 2D contour plots of the TA data are shown in Fig. 4i–k, and representative TA spectra at different delay times are presented in Fig. 4l–n. All TA spectra feature a negative signal of Gaussian shape around 750 nm. This band is consistent with published data and has been attributed to ground state bleaching (GSB) as a consequence of the population of band edge states by charge carriers66,67. We note that in the case of SnO2 QDs, the GSB signal exhibits a smaller full width at half maximum (FWHM). Since the GSB originates from charge filling of band edge states, its width is related to the charge distribution profile67. In fact, a narrower FWHM indicates less imperfections, such as defects or traps, which in turn leads to a higher Voc68. In addition, SnO2 QDs/perovskite also exhibit a blue-shifted GSB (~3 nm) compared to the other two samples. This is attributed to an optimized degree of order (the same underlying mechanism leading to a narrower FWHM of GSB) and accordingly the suppression of non-radiative centers, as revealed from the decay kinetics in Fig. 4o. Since the GSB originates from the population of band-edge states by charge carriers, investigating decay dynamics provides insight to the underlying charge recombination mechanisms. Here, we find that all decays can be described by single exponential functions with lifetimes of 112.3 ± 2.5, 227.3 ± 2.5, and 405.1 ± 4.6 ns, respectively. In view of the proposed mechanism69, we thus assign the recombination to be of first-order. Considering the weak excitonic binding energy in these perovskite materials, we can further assign the first-order recombination to trap-assisted recombination, that is, Shockley–Read–Hall (SRH) recombination. Hence, the increased lifetime indicates that the trap density is the highest in the c-SnO2 sample, and decreases in the commercial SnO2 NPs sample, and is the lowest in the ligand-assisted SnO2 QDs sample. The observation of a decreasing trap density implies that multifunctional terminal groups in the SnO2 can effectively passivate the interface and improve the film quality, both of which contribute to the solar cell performance. These findings consistently explain the alleviated (or negligible) hysteresis and enhanced VOC in the SnO2 QDs-based device, which are further supported by 2D GIWAXS patterns, ELQE, and spatial confocal PL microscopy as discussed above.
Solar cell performance and device stability
Previous studies reveal that perovskite shows improved structural stability, suppressed ion migration, reduced defect density, and lowered voltage-loss by doping a small amount of alkali cations70, such as cesium (Cs) rubidium (Rb), and potassium (K). In this study, as an example, we adopted the state-of-the-art Cs, Rb, and K co-doped FAMA mixed-cation perovskite with a one-step chlorobenzene anti-solvent quenching technique71. The J–V curves of the best-performing c-SnO2, SnO2 NPs, and SnO2 QDs based PSCs under the RS and forward scan (FS) directions are shown in Fig. 5a–c, with the corresponding photovoltaic parameters summarized in Table S3. The c-SnO2-based devices exhibit a PCE of 17.6% (FS) and 19.3% (RS) with considerable J–V hysteresis, whereas PCEs for devices with SnO2 NPs (FS: 19.3%, RS: 19.8%) and SnO2 QDs (FS: 21.0%, RS: 20.4%) have negligible hysteresis. The SnO2 QDs-based devices exhibit a remarkable improvement in Voc (FS: 1.208 V, RS: 1.205 V) compared to the c-SnO2-based devices (FS: 1.148 V, RS: 1.161 V) and SnO2 NPs-based devices (FS: 1.159 V, RS: 1.156 V). The SnO2 QDs-based devices also have stable Voc under 1 sun illumination (inset in Fig. 5c). This dramatic enhancement in Voc is likely ascribed to reduced interfacial non-radiative recombination and improved PVSK film quality. This indicates that the ligand-tailored SnO2 QDs, which possess multi-functional terminal groups, play an essential role in effective interfacial passivation, hammered by the observations in 2D GIWAXS, ELQE, spatial confocal PL microscopy, and nanosecond-TA spectroscopy. Figure 5d further confirms the stable power output during maximum power point (MPP) tracking under 1 sun illumination (100 s) for c-SnO2 (18.8%), SnO2 NPs (19.7%), and SnO2 QDs (21.2%) based devices, respectively. To examine the effect of these ETLs on the device-to-device reproducibility variation, we fabricated 38 independent devices incorporating three different ETLs and statistically summarized the PV parameters. Figure 5e clearly depicts that the performances of PSCs with commercial SnO2 NPs ETLs (FS: 18.47 ± 0.61%, RS: 18.67 ± 0.72%) surpass those with c-SnO2 ETLs (FS: 16.17 ± 1.40%, RS: 18.05 ± 0.58%), while the PSCs with SnO2 QDs ETLs (FS: 19.77 ± 0.38 %, RS: 19.87 ± 0.71%) have the best performances. The improved PCE is mainly attributed to an increase in the Voc of ~50 mV with SnO2 QDs ETLs comparing to the PSCs with the other two ETLs. The c-SnO2 ETL-based PSCs have a much larger standard deviation, as shown in Fig. 5f. Short-circuit current density (Fig. 5g) obtained from c-SnO2-based devices (FS: 21.83 ± 0.03 mA cm−2, RS: 21.87 ± 0.03 mA cm−2) is smaller than those obtained from SnO2 NPs-based devices (FS: 22.05 ± 0.50 mA cm−2, RS: 22.06 ± 0.53 mA cm−2) and SnO2 QDs-based devices (FS: 21.94 ± 0.41 mA cm−2, RS: 21.97 ± 0.41 mA cm−2). The low performance of c-SnO2-based samples is linked to poor interfacial physical contact. This configuration exhibits the most exaggerated interfacial physical defects (Figs. 2a, S10B, and S17A), which can act as carrier recombination centers resulting in lower Jsc as well as decreased FF (Fig. 5h). Expectedly, the average h-index (Fig. 5i) obtained from J–V characteristics in c-SnO2-based devices (0.105 ± 0.068) is much larger than those of PSCs with SnO2 NPs (0.018 ± 0.013) and SnO2 QDs (0.023 ± 0.018). Previous research works have established that J–V hysteresis mainly originates from the existence of traps/defects on the surface of ETLs and PVSK bulk films as well as their interfaces36,37,38. According to the above results, we can deduce that the dramatic suppressed J–V hysteresis should result from decreased interfacial physical defects and reduced charge accumulation at the interface, as well as improved PVSK film quality.
It worth mentioning that our multi-functional terminal groups anchored SnO2 QDs ETLs have strongly reduced annealing temperature—even to below 100 °C. The devices with room temperature processed ETL still achieve an acceptable performance (FS: 15.1 ± 1.9%, RS: 15.6 ± 1.7%). We designate the differentiated annealing temperature of SnO2 QDs ETLs from 200 °C to room temperature (best-performing PSCs are shown in Fig. S19), and the corresponding statistical data of the photovoltaic parameters are shown in Fig. S20. It is very encouraging that the 100 °C-annealed ETL device still shows high performance (FS: 18.7 ± 0.99%, RS: 18.5 ± 0.79%), only slightly lower than that of 120 °C-annealed ETL samples (FS: 19.0 ± 0.68%, RS: 19.1 ± 0.78%). The optimal condition is achieved with samples based on 150 °C-annealed ETLs (FS: 19.9 ± 0.71%, RS: 19.8 ± 0.38%) while devices based on 200 °C-annealed ETLs exhibit a slightly smaller PCE value (FS: 19.9 ± 0.88%, RS: 19.3 ± 0.62%).
We then systematically investigate the stability of our as-prepared unencapsulated devices (c-SnO2, SnO2 NPs and SnO2 QDs), which were carried out under a series of aging conditions (e.g., dry box storage with 25–30% relative humidity, 85 °C thermal aging in glovebox, and continuous UV light irradiance aging in the glovebox). The results of stability tests were shown in Fig. S21. The storage lifetime (dry box with 25–35% relative humidity) of PSCs with SnO2 NP ETLs or SnO2 QD ETLs exhibited a more significant enhancement compared to that of c-SnO2-based devices. The c-SnO2-based devices maintain only 48% of their initial value after 1000 h degradation, while PSCs with SnO2 NP ETLs or SnO2 QD ETLs retaining ~76% and ~80% of their initial PCEs, respectively. The PSCs with SnO2 QD ETLs (or SnO2 NP ETLs) showed improved thermal (Fig. S21B) and UV irradiance stability (Fig. S21C), which allowed the devices to achieve a T80 (when PCE drops to 80% of the original value) of ~180 h after 85 °C thermal aging testing or ~40 h after 365 nm UV irradiance aging testing, while the c-SnO2-based devices only demonstrated a T80 of ~50 h with 85 °C thermal aging and ~20 h with 365 nm UV irradiance aging. These results possibly indicate that improved physical contact at FTO/ETLs interface (or ETLs/PVSK interface), and thereby reduced interface nonradiative recombination accounts plausibly for the observed enhanced thermal, UV, and moisture endurance. Furthermore, strengthened interfacial adhesion and efficient interfacial passivation could be another main reason for the improved stability of devices with tailored SnO2 QDs.
To further prove the versatility and genericity of the ultrafine SnO2 QDs ETL, we applied this new ETL to a lower bandgap, i.e., 1.541 eV (CsFAMA) perovskite system, via manufacturing friendly blade coating process and the results are even more exciting. A high PCE (reverse scan) of 23.02% (certified at 22.51%, Enli Tech., Fig. S22) was realized for the blade-coated n–i–p devices (Fig. 6a, b and Table S4). Figure 6c shows our setup of room temperature meniscus-guided blade-coating technique assisted with nitrogen air-knife quenching72. The perovskite precursor solution was blade-coated on the ligand-tailored SnO2 QDs coated substrate by an automatic wire-bar coater with an adjustable film applicator, delivering a large-area (up to 90 mm × 100 mm here) high-quality perovskite film (Fig. 6d). In this study, upscaling device with an active area from 0.04 to 0.98 cm2 exhibits a record performance (21.6% PCE, maximum VOC of 1.205 V) for SnO2 ETL-based upscaling PSCs (Fig. 6e). Considering the perovskite bandgap of 1.541 eV, this indicates a significantly small bandgap–VOC offset (WOC = Eg–VOC or simply VOC loss) of 0.336 V, representing one of the lowest VOC loss for SnO2 ETL-based PSCs. We further extended it to blade coated 30 × 30 mm2 mini-modules with 1.613 eV perovskite systems (18.9% PCE for three sub-cells, Figs. 6f and S23) and 1.541 eV (19.5% PCE for two sub-cells, Fig. S24A). More noticeably, after delicate optimization, a substantially enhanced PCE (VOC) from 20.4% (1.152 V) to 22.8% (1.242 V, 90 mV higher VOC) was achieved in the meniscus-guided blade-coated PSCs (1.613 eV perovskite system, Figs. S24B and S24C), via replacing the benchmark commercial colloidal SnO2 ETL1 with our ligand-tailored SnO2 QDs ETL2 (Fig. S24D). Detailed device PV parameters are summarized in Table S4, Figs. S25, and S26.
Discussion
In this paper, we demonstrate a facile, ligand-assisted, and room-temperature synthetic approach to rapidly formulate SnO2 QDs anchored by multi-functional terminal groups and utilize such SnO2 QDs as ETLs to in situ manipulate critical interfacial contact in planar perovskite solar cells. We explore the interfacial contact and visualize morphological properties via systemic characterization to in-depth illuminate the synergistic effect of physical and chemical interfacial modulations, originated from the new multifunctional ligand-tailored SnO2 QDs, on enhanced device performance. Compared with the existing benchmark SnO2 nano-materials, ligand-tailored SnO2 QDs exhibited superior properties, including low processing temperature (<100 °C), strengthened perovskite interfacial physical and chemical adhesions, buried interface defects passivation, and preferred perovskite crystallization-directing. These benefits together allow us to achieve a PCE of 23.02% (certified efficiency 22.51%) in a 1.541 perovskite system (RS, 0.04 cm2 active area), with significantly enhanced EL quantum efficiency thanks to the substantially suppressed non-radiative recombination and buried interface defects. Furthermore, we successfully prove the scalability of new ETL in the blade-coated PSCs—0.98 cm2 active area PSC with 21.6% PCE (a VOC loss as low as 0.336 V)—a record for SnO2 ETL-based upscaling PSCs. Moreover, in the blade-coated 1.613 eV PSCs system, a substantially enhanced PCE (VOC) from 20.4% (1.152 V) to 22.8% (1.242 V, 90 mV higher VOC) has been achieved via replacing the benchmark commercial colloidal SnO2 ETL with our new ETLs. Moreover, encouraging mini-modules were successfully demonstrated in both 1.541 eV (19.5% PCE for two sub-cells) and 1.613 eV (18.9% PCE for three sub-cells) perovskite systems. Our in situ solution chemistry engineering of metal oxide synthesis contrives a new direction toward achieving low temperature and high quality functionalized SnO2 ETLs, compatible with upscaling manufacture of large-area high-quality perovskite films for solar cells and other optoelectronic devices.
Materials and methods
Experimental details can be found in the Supplementary Information.
Data availability
All data is available in the main text or Supplementary materials.
References
Jiang, Q. et al. Surface passivation of perovskite film for efficient solar cells. Nat. Photonics 13, 460–466 (2019).
Lee, M. M. et al. Efficient hybrid solar cells based on meso-superstructured organometal halide perovskites. Science 338, 643–647 (2012).
Malinkiewicz, O. et al. Perovskite solar cells employing organic charge-transport layers. Nat. Photonics 8, 128–132 (2014).
Green, M. A. et al. The emergence of perovskite solar cells. Nat. Photonics 8, 506 (2014).
Grätzel, M. et al. The light and shade of perovskite solar cells. Nat. Mater. 13, 838 (2014).
Anaraki, E. H. et al. Highly efficient and stable planar perovskite solar cells by solution-processed tin oxide. Energy Environ. Sci. 9, 3128–3134 (2016).
Shi, D. et al. Low trap-state density and long carrier diffusion in organolead trihalide perovskite single crystals. Science 347, 519–522 (2015).
Eperon, G. E. et al. Formamidinium lead trihalide: a broadly tunable perovskite for efficient planar heterojunction solar cells. Energy Environ. Sci. 7, 982–988 (2014).
Wehrenfennig, C. et al. High charge carrier mobilities and lifetimes in organolead trihalide perovskites. Adv. Mater. 26, 1584–1589 (2014).
Lang, F. et al. Influence of radiation on the properties and the stability of hybrid perovskites. Adv. Mater. 30, 1702905 (2018).
Im, J. H. et al. 6.5% efficient perovskite quantum-dot-sensitized solar cell. Nanoscale 3, 4088–4093 (2011).
Kojima, A. et al. Organometal halide perovskites as visible-light sensitizers for photovoltaic cells. J. Am. Chem. Soc. 131, 6050–6051 (2009).
Saliba, M. et al. Structured organic–inorganic perovskite toward a distributed feedback laser. Adv. Mater. 28, 923–929 (2016).
Dou, L. T. et al. Solution-processed hybrid perovskite photodetectors with high detectivity. Nat. Commun. 5, 5404 (2014).
Yakunin, S. et al. Detection of gamma photons using solution-grown single crystals of hybrid lead halide perovskites. Nat. Photonics 10, 585–589 (2016).
Zhou, F. C. et al. Low‐voltage, optoelectronic CH3NH3PbI3−xClx memory with integrated sensing and logic operations. Adv. Funct. Mater. 28, 1800080 (2018).
Wei, H. T. et al. Sensitive X-ray detectors made of methylammonium lead tribromide perovskite single crystals. Nat. Photonics 10, 333–339 (2016).
Kim, Y. C. et al. Printable organometallic perovskite enables large-area, low-dose X-ray imaging. Nature 550, 87 (2017).
Tan, Z. K. et al. Bright light-emitting diodes based on organometal halide perovskite. Nat. Nanotechnol. 9, 687 (2014).
Jeong, J. et al. Pseudo-halide anion engineering for α-FAPbI3 perovskite solar cells. Nature 592, 381–385 (2021).
Kim, H. S. et al. Parameters affecting I–V hysteresis of CH3NH3PbI3 perovskite solar cells: effects of perovskite crystal size and mesoporous TiO2 layer. J. Phys. Chem. Lett. 5, 2927–2934 (2014).
Jiang, Q. et al. SnO2: a wonderful electron transport layer for perovskite solar cells. Small 14, 1801154 (2018).
Ke, W. J. et al. Low-temperature solution-processed tin oxide as an alternative electron transporting layer for efficient perovskite solar cells. J. Am. Chem. Soc. 137, 6730–6733 (2015).
Jiang, Q. et al. Enhanced electron extraction using SnO2 for high-efficiency planar-structure HC (NH2)2PbI3-based perovskite solar cells. Nat. Energy 2, 16177 (2016).
Yang, D. et al. High efficiency planar-type perovskite solar cells with negligible hysteresis using EDTA-complexed SnO2. Nat. Commun. 9, 3239 (2018).
Yoo, J. J. et al. Efficient perovskite solar cells via improved carrier management. Nature 590, 587–593 (2021).
Dong, Q. S. et al. Improved SnO2 electron transport layers solution‐deposited at near room temperature for rigid or flexible perovskite solar cells with high efficiencies. Adv. Energy Mater. 9, 1900834 (2019).
Yang, G. et al. Tin oxide (SnO2) as effective electron selective layer material in hybrid organic–inorganic metal halide perovskite solar cells. J. Energy Chem. 27, 962–970 (2018).
Zhu, Z. L. et al. Enhanced efficiency and stability of inverted perovskite solar cells using highly crystalline SnO2 nanocrystals as the robust electron‐transporting layer. Adv. Mater. 28, 6478–6484 (2016).
Singh, M. et al. Facile synthesis of composite tin oxide nanostructures for high-performance planar perovskite solar cells. Nano Energy 60, 275–284 (2019).
Park, S. Y. et al. Simultaneous ligand exchange fabrication of flexible perovskite solar cells using newly synthesized uniform tin oxide quantum dots. J. Phys. Chem. Lett. 9, 5460–5467 (2018).
Liu, Z. et al. Coagulated SnO2 colloids for high-performance planar perovskite solar cells with negligible hysteresis and improved stability. Angew. Chem. Int. Ed. 58, 11497–11504 (2019).
Yang, G. et al. Effective carrier concentration tuning of SnO2 quantum dot electron‐selective layers for high‐performance planar perovskite solar cells. Adv. Mater. 30, 1706023 (2018).
Yu, H. et al. Superfast room-temperature activation of SnO2 thin films via atmospheric plasma oxidation and their application in planar perovskite photovoltaics. Adv. Mater. 30, 1704825 (2018).
Abuhelaiqa, M. et al. Stable perovskite solar cells using tin acetylacetonate based electron transporting layers. Energy Environ. Sci. 12, 1910–1917 (2019).
Chen, B. et al. J. Imperfections and their passivation in halide perovskite solar cells. Chem. Soc. Rev. 48, 3842–3867 (2019).
Akin, S. et al. New strategies for defect passivation in high‐efficiency perovskite solar cells. Adv. Energy Mater. 10, 1903090 (2020).
Han, T. H. et al. Interface and defect engineering for metal halide perovskite optoelectronic devices. Adv. Mater. 31, 1803515 (2019).
Ke, W. J. et al. Cooperative tin oxide fullerene electron selective layers for high-performance planar perovskite solar cells. J. Mater. Chem. A 4, 14276–14283 (2016).
Liu, X. et al. A low‐temperature, solution processable tin oxide electron‐transporting layer prepared by the dual‐fuel combustion method for efficient perovskite solar cells. Adv. Mater. Interfaces 3, 1600122 (2016).
Hui, W. et al. Red‐carbon‐quantum‐dot‐doped SnO2 composite with enhanced electron mobility for efficient and stable perovskite solar cells. Adv. Mater. 32, 1906374 (2020).
Park, M. et al. Low-temperature solution-processed Li-doped SnO2 as an effective electron transporting layer for high-performance flexible and wearable perovskite solar cells. Nano Energy 26, 208–215 (2016).
Bai, Y. et al. Low temperature solution‐processed Sb: SnO2 nanocrystals for efficient planar perovskite solar cells. ChemSusChem 9, 2686–2691 (2016).
Tu, B. et al. Novel molecular doping mechanism for n‐doping of SnO2 via triphenylphosphine oxide and its effect on perovskite solar cells. Adv. Mater. 31, 1805944 (2019).
Wang, R. et al. A review of perovskites solar cell stability. Adv. Funct. Mater. 29, 1808843 (2019).
Lu, X. et al. Room-temperature synthesis of colloidal SnO2 quantum dot solution and ex-situ deposition on carbon nanotubes as anode materials for lithium ion batteries. J. Alloy. Compd. 680, 109–115 (2016).
Cigala, R. M. et al. The inorganic speciation of tin(II) in aqueous solution. Geochim. Cosmochim. Acta 87, 1–20 (2012).
Hu, W. P. et al. Low‐temperature in situ amino functionalization of TiO2 nanoparticles sharpens electron management achieving over 21% efficient planar perovskite solar cells. Adv. Mater. 31, 1806095 (2019).
Li, L. et al. Efficient synthesis of highly luminescent copper indium sulfide-based core/shell nanocrystals with surprisingly long-lived emission. J. Am. Chem. Soc. 133, 1176–1179 (2011).
Aniskevich, Y. et al. Underpotential deposition of cadmium on colloidal CdSe quantum dots: effect of particle size and surface ligands. J. Phys. Chem. C 123, 931–939 (2018).
Wei, J. et al. SnO2-in-polymer matrix for high-efficiency perovskite solar cells with improved reproducibility and stability. Adv. Mater. 30, 1805153 (2018).
Chan, D. Y. C. et al. Electrical double layer interactions between dissimilar oxide surfaces with charge regulation and Stern–Grahame layers. J. Colloid Interface Sci. 296, 150–158 (2006).
Song, S. et al. Systematically optimized bilayered electron transport layer for highly efficient planar perovskite solar cells (η = 21.1%). ACS Energy Lett. 2, 2667–2673 (2017).
Kim, T. W. et al. Direct observation of the tunneling phenomenon in organometal halide perovskite solar cells and its influence on hysteresis. ACS Energy Lett. 3, 2743–2749 (2018).
Qiu, L. B. et al. Scalable fabrication of stable high efficiency perovskite solar cells and modules utilizing room temperature sputtered SnO2 electron transport layer. Adv. Funct. Mater. 29, 1806779 (2019).
Shen, Z. et al. Surface amino-functionalization of Sn-Beta zeolite catalyst for lactic acid production from glucose. RSC Adv. 9, 18989–18995 (2019).
Chen, H. et al. Efficient bifacial passivation with crosslinked thioctic acid for high‐performance methylammonium lead iodide perovskite solar cells. Adv. Mater. 32, 1905661 (2019).
Wang, Z. et al. Interfacial sulfur functionalization anchoring SnO2 and CH3NH3PbI3 for enhanced stability and trap passivation in perovskite solar cells. ChemSusChem 11, 3941–3948 (2018).
Feng, Y. C. et al. Synthesis of mesoporous BiOBr 3D microspheres and their photodecomposition for toluene. J. Hazard. Mater. 192, 538–544 (2011).
Bi, D. et al. Polymer-templated nucleation and crystal growth of perovskite films for solar cells with efficiency greater than 21%. Nat. Energy 1, 16142 (2016).
Liu, H. R. et al. Pyridine-functionalized fullerene electron transport layer for efficient planar perovskite solar cells. ACS Appl Mater. Interfaces 11, 23982–23989 (2019).
Hu, H. L. et al. Room‐temperature meniscus coating of >20% perovskite solar cells: a film formation mechanism investigation. Adv. Funct. Mater. 29, 1900092 (2019).
Xie, J. S. et al. Perovskite bifunctional device with improved electroluminescent and photovoltaic performance through interfacial energy‐band engineering. Adv. Mater. 31, 1902543 (2019).
Qing, J. et al. High‐quality ruddlesden–popper perovskite films based on in situ formed organic spacer cations. Adv. Mater. 31, 1904243 (2019).
Noel, N. K. et al. Interfacial charge-transfer doping of metal halide perovskites for high performance photovoltaics. Energy Environ. Sci. 12, 3063–3073 (2019).
Xing, G. C. et al. Long-range balanced electron-and hole-transport lengths in organic-inorganic CH3NH3PbI3. Science 342, 344–347 (2013).
Manser, J. S. et al. Band filling with free charge carriers in organometal halide perovskites. Nat. Photonics 8, 737–743 (2014).
Kagan, C. et al. Electronic energy transfer in CdSe quantum dot solids. Phys. Rev. Lett. 76, 1517–1520 (1996).
Herz, L. M. et al. Charge-carrier dynamics in organic-inorganic metal halide perovskites. Annu. Rev. Phys. Chem. 67, 65–89 (2016).
Luo, D. Y. et al. Minimizing non-radiative recombination losses in perovskite solar cells. Nat. Rev. Mater. 5, 44–60 (2020).
Jeon, N. J. et al. Solvent engineering for high-performance inorganic–organic hybrid perovskite solar cells. Nat. Mater. 13, 897–903 (2014).
Liu, K. et al. Zwitterionic-surfactant-assisted room-temperature coating of efficient perovskite solar cells. Joule 4, 2404–2425 (2020).
Acknowledgements
This work was financially supported by the Research Grants Council of Hong Kong (GRF grant nos. 15246816, 15218517 and CRF grant no. C5037-18G), Shenzhen Technology Innovation Commission (Project no. JCYJ20200109105003940), and the funding provided by the Hong Kong Polytechnic University (Project Code: 1-CDA5 and Sir Sze-yuen Chung Endowed Professorship Fund (8-8480)). S/TEM work was carried out at the Hong Kong Polytechnic University and was supported by the Hong Kong Research Grants Council through the Early Career Scheme (Project no. 25301617) and the Hong Kong Polytechnic University grant (Project no. 1-ZE6G). X.G. and Y.Z. thank Dr. Wei Lu for optimizing the JEOL JEM-2100F microscope. G.L. and K.L. thank the RGC Postdoctoral Fellowship Scheme (PDFS2021-5S04). K.L. thanks Guangdong Basic and Applied Basic Research Foundation (2020A1515110156). H.H. gratefully acknowledge the support from the National Natural Science Foundation of China (62004129). A.N. and C.S. acknowledge the financial support from Nazarbayev University Grant (090118FD5326 and 110119FD4506), the targeted Program BR05236524, and social policy grants.
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G.L., Z.R., K.L., and H.H. conceptualized the work and designed the experiments. Z.R., K.L., and H.H. conducted device fabrication and data analysis. K.L., X.G., Y.G., P.W.K.F, Q.L., H.T., J.H., H.Z., M.S., M.Q., M.-F.L., D.S., A.N., C.S., C.-S.L., X.L., F.L., and Y.Z. contributed materials characterization and data analysis. All authors discussed the results and commented on the paper. G.L., Z.R., K.L., and H.H. revised and finalized the paper.
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Ren, Z., Liu, K., Hu, H. et al. Room-temperature multiple ligands-tailored SnO2 quantum dots endow in situ dual-interface binding for upscaling efficient perovskite photovoltaics with high VOC. Light Sci Appl 10, 239 (2021). https://doi.org/10.1038/s41377-021-00676-6
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DOI: https://doi.org/10.1038/s41377-021-00676-6