Self-assembled manganese acetate@tin dioxide colloidal quantum dots as an electron-transport layer for efficient and stable perovskite solar cells

Yutao Li a, Chenyu Zhao a, Lexin Wang a, Lin Fan ab, Maobin Wei ab, Huilian Liu ab, Xiaoyan Liu ab, Jinghai Yang *ab, Fengyou Wang *ab and Lili Yang *ab
aKey Laboratory of Functional Materials Physics and Chemistry of the Ministry of Education, Jilin Normal University, Changchun 130103, China. E-mail: jhyang1@jlnu.edu.cn; wfy@jlnu.edu.cn; llyang1980@163.com
bNational Demonstration Center for Experimental Physics Education, Jilin Normal University, Siping 136000, China

Received 18th January 2024 , Accepted 27th April 2024

First published on 29th April 2024


Abstract

An SnO2 electron-transport layer (ETL) is a critical and mainstream component utilized in perovskite solar cells (PSCs) on account of its exceptional photoelectric performances and low-temperature fabrication process. Nevertheless, a significant number of defects on the surface of SnO2 quantum dots (QDs) can lead to QD agglomeration in dispersion and poor film quality, ultimately compromising the power conversion efficiency (PCE) and stability of devices. In this study, we developed multifunctional manganese acetate (Mn(Ac)2)-stabilized SnO2 quantum dots (Mac-SnO2 QDs) and utilized them to prepare ETLs for PSCs. The C[double bond, length as m-dash]O groups of Mn(Ac)2 can terminate the Sn4+ dangling bonds on Mac-SnO2 QDs, thereby preventing QD agglomeration, facilitating the preparation of a uniform film with good electrical properties. In addition, Mn2+ can permeate upward into the perovskite film, passivating I at the grain boundary and reducing perovskite bulk defects. Moreover, the perovskite grown on Mac-SnO2 releases residual stress, which can improve device performance and stability. As a consequence, Mac-SnO2 PSCs achieved a high PCE of 23.36% with improved stability. This successful approach of utilizing an organic acid salt to modify SnO2 QDs provides a facile and efficient strategy for enhancing the efficiency and stability of PSCs.


1. Introduction

Interest in organic–inorganic hybrid perovskite solar cells (PSCs) has recently surged in the photovoltaic field owing to their remarkable optoelectronic performances, such as high carrier mobility, low exciton binding energy, long carrier diffusion length, and excellent absorption coefficient.1–3 Since the advent of the first PSCs, their certified power conversion efficiency (PCE) has boomed to 26.1% over the past dozen years, which is comparable to mature commercial silicon cells.4–6 One of the critical factors for achieving advanced devices is the application of inorganic metal oxides, such as ZnO, SnO2, and TiO2, as electron-transport layers (ETLs).7–10 These ETLs play a key role in extracting and separating carriers, have high transmittance to allow light into the absorbed layer, and display well-matched energy levels with the perovskite material. Currently, SnO2 stands out among the many ETLs because of its excellent photoelectric properties, high optical transmittance, exceptional ultraviolet (UV) stability, and suitability for low-temperature preparation.11–15 However, similar to other inorganic metal oxides, the surface of SnO2 quantum dots (QDs) possesses a significant number of metallic dangling bonds, leading to disordered surface charges. Consequently, QDs will attract each other because of van der Waals interaction, resulting in instability and agglomeration of the QDs.16,17 Upon film formation, the material suffers from pinholes and non-uniformity, leading to poor film quality. Moreover, the presence of Sn dangling bonds on the surface can capture hydroxyl groups during film formation and induce perovskite degradation.18–20 These surface defects inevitably trap electrons, resulting in carrier non-radiative recombination, thus affecting interface electron transport.

To mitigate film surface defects, some researchers have adopted the method of surface modification for SnO2 films. For instance, a multi-fluorine-containing C70-porphyrin dyad molecule (F70PD), bathocuproine (BCP)-core-based nonconjugated polyelectrolytes, histamine diiodate (HADI), and ionic potassium L-aspartate (PL-A) are considered suitable modification layers for the SnO2 surface.21–24 Their multifunctional groups can interact with surface-uncoordinated Sn4+ of the SnO2 layer, enhance interfacial charge transport, and ultimately restrain carrier non-radiative recombination. Moreover, fullerene dimers prepared by combining phenanthroline with two fullerenes (2C60-Bphen), oteracil potassium (OP), and a potassium sulfonate salt (3Cl-BSAK) have been used to match the energy level between the SnO2 ETL and perovskite layer, thus effectively decreasing the interface energy barrier and enhancing interfacial charge extraction.25–27 However, the surface modification of SnO2 films may not sufficiently passivate the bulk defects of the SnO2 film. As a result, some researchers have focused on modifying the surface of individual SnO2 QDs for the sake of enhancing the overall quality of SnO2 films. Organic large molecules, such as streptomycin sulfate, heparin potassium, and poly(ethylene glycol) diacrylate, have been incorporated to significantly passivate the defects of SnO2 QDs and inhibit their agglomeration through their multiple functional groups.28–30 This method can result in a uniform SnO2 film. However, the large organic molecules may induce additional steric hindrance, affecting the ETL conductivity.31 Consequently, utilizing small ions to stabilize QDs seems to be a potential way to relax the trade-off between the surface passivation and reducing the steric hindrance.

In this study, we developed multifunctional manganese acetate (Mn(Ac)2)-stabilized SnO2 QDs (Mac-SnO2 QDs) and utilized them to prepare ETLs for PSCs. The molecular formula of Mn(Ac)2 is (CH3COO)2Mn. The C[double bond, length as m-dash]O groups of the Mac-SnO2 QDs could terminate Sn dangling bonds, which reduces particle interactions, suppressing QDs agglomeration, and allowing forming a uniform film. Moreover, the Mac-SnO2 QDs could reduce the defects that exist in the ETL/perovskite interface due to the C[double bond, length as m-dash]O group. Interestingly, during the experiment, we observed that the perovskite grown on Mac-SnO2 released residual stress during annealing and the Mn2+ could spread upward into the perovskite layer, passivating the I that appear in the grain boundary. In consequence, the PCE could be elevated from 21.11% to 23.36%. More importantly, the Mac-SnO2 devices demonstrated good long-term stability, with the PCE maintaining 90% of its original value under environmental conditions for nearly 600 h.

2. Results and discussion

In Fig. S1, X-ray diffraction (XRD) was utilized to confirm the ETLs formation and crystallographic characteristics. The results demonstrate that the addition of Mn(Ac)2 did not alter the SnO2 crystal structure. Subsequently, the size variation between Mac-SnO2 and SnO2 QDs was investigated using transmission electron microscopy (TEM). The distinct electron diffraction circles observed for both samples indicated a polycrystalline nature.32 It was found that both the SnO2 and Mac-SnO2 QDs had sizes of ∼5 nm (Fig. 1a and b). One step further, the particle size analysis in the SnO2 and Mac-SnO2 colloidal dispersion was performed by dynamic light scattering (DLS) (Fig. 1c and d). The average particle sizes for the fresh SnO2 and Mac-SnO2 dispersions were similar, respectively. After 72 h of aging, the particle size of the fresh SnO2 solution significantly increased, while that of the Mac-SnO2 solution remained almost unchanged under identical conditions. Additionally, we measured the zeta potential to exhibit the electrostatic potential of the particles in solution. The fresh SnO2 dispersion showed a zeta potential value of −23.60 mV, which declined to −9.94 mV after aging for 72 hours in storage (Fig. S2). This indicates the electrostatic potential could not provide enough repulsion to disperse the particles, leading to unfavorable agglomeration (a common occurrence for inorganic metal oxide particles in colloidal dispersions).33 On the contrary, the stabilized Mac-SnO2 solution exhibited a large zeta potential (−40.5 mV), and was little changed after aging, suggesting that the addition of Mn(Ac)2 stabilized the SnO2 QDs by terminating the surface defects, thereby inhibiting QDs agglomeration.34 Furthermore, the more evenly dispersed Mac-SnO2 particles benefit the formation of a denser and more uniform film. Top-view scanning electron microscopy (SEM) and atomic force microscopy (AFM) were carried out to illustrate the ETLs surface morphology. The Mac-SnO2 film displayed a compact and dense morphology, superior to that of the SnO2 film (Fig. S3). The surface root-mean-square (Rq) roughness decreased from the SnO2 film (1.26 nm) to the Mac-SnO2 film (0.95 nm), manifesting the smoother film (Fig. 1e and f). Moreover, UV–visible (UV–vis) transmittance spectroscopy was performed to probe the optical properties of the SnO2 and Mac-SnO2 films (Fig. 1g). The optical transmittance of the ITO/Mac-SnO2 film increased in the range from 470 to 800 nm, verifying that the Mac-SnO2 film was uniform and compact due to the more dispersed QDs.
image file: d4qi00166d-f1.tif
Fig. 1 HRTEM images and their SAED images of (a) SnO2 and (b) Mac-SnO2. (c) Particle-size distribution of fresh SnO2 and Mac-SnO2 solutions. (d) Particle-size distribution of 72 h-aged SnO2 and Mac-SnO2 solutions. AFM topographical images of (e) SnO2 and (f) Mac-SnO2 films. (g) Optical transmittance spectra of ITO/SnO2 and ITO/Mac-SnO2 films.

In order to further elucidate the mechanism behind the differences between SnO2 and Mac-SnO2, we conducted a comprehensive study from various perspectives. Our findings revealed that the dispersion of SnO2 was transparent and colorless, whereas the Mac-SnO2 dispersion exhibited an orange hue, indicative of an interaction between Mn(Ac)2 and SnO2 (Fig. S4). The interaction was analyzed through X-ray photoelectron spectroscopy (XPS) measurements (Fig. S5a). The Mn peak of 2p could be observed in the Mac-SnO2 film (Fig. S5b). Notably, after the incorporation of Mn(Ac)2, the peaks for Sn 3d3/2 and Sn 3d5/2 in SnO2 were shifted toward lower binding energies, from 494.88 and 486.48 eV to 494.45 and 486.04 eV, respectively (Fig. 2a). This shift indicated the increased electron density around the Sn atoms, attributable to the interaction between Sn and Mn(Ac)2.35 Additionally, XPS for O 1s was also performed (Fig. 2b and c). The pristine SnO2 film displayed a distinct peak at 530.38 eV, confirming the presence of hydroxyl groups (OH), while the peak of saturated oxygen (O2−) was at 531.47 eV. However, the OH peak was diminished in the Mac-SnO2 film, suggesting that C[double bond, length as m-dash]O effectively reduced the density of absorbed OH sites. To further confirm the bonding between SnO2 and Mn(Ac)2, Fourier-transform infrared (FTIR) spectroscopy was conducted (Fig. 2d). Mn(Ac)2 exhibited two characteristic peaks for C[double bond, length as m-dash]O bonds.36 After adding Mn(Ac)2 into the SnO2 QDs dispersion solution, the C[double bond, length as m-dash]O peaks moved from 1558 and 1444 cm−1 to 1543 and 1412 cm−1, consistent with the XPS results mentioned earlier, and further supporting the formation of Mac-SnO2 resulting from the interaction between C[double bond, length as m-dash]O and the SnO2 QDs surface. This effect can reduce the following presence of OH groups absorbed on the oxygen vacancies and inhibit the non-radiative recombination of the SnO2 surface, offering potential benefits.37 We further verified our experimental results via density functional theory (DFT) calculations. As displayed in Fig. 2e, there were oxygen vacancies on the SnO2 surface. After adding acetic acid groups (Ac), the C[double bond, length as m-dash]O in acetic acid could combine with Sn on the SnO2 surface (Fig. S6). The interaction was then explored by calculating the charge density difference of Ac adsorbed on the SnO2 surface (Fig. 2f). In the figure, the blue regions denote electron depletion after charge redistribution, and the yellow regions represent electron accumulation. It could be concluded that the Sn atoms obtained electrons from the C[double bond, length as m-dash]O group through the Sn–O bond from the electron clouds at the interface, which was in accord with the XPS and FTIR results. A schematic drawing shows the whole process in Fig. 2g; whereby, the pristine SnO2 QDs agglomerated due to a good deal of Sn4+ dangling bonds existing on the surface, while the C[double bond, length as m-dash]O groups of Mn(Ac)2 could passivate the Sn4+ dangling bonds, so that Ac inhibited the QDs agglomeration, like the ligands around SnO2, thus allowing obtaining a dense Mac-SnO2 film without pinholes.


image file: d4qi00166d-f2.tif
Fig. 2 XPS spectra of (a) Sn 3d and (b and c) O 1s for SnO2 and Mac-SnO2. (d) FTIR spectra of SnO2 and Mac-SnO2. Side view of (e) SnO2–Ov and the charge density difference of (f) SnO2–Ov/Ac. (g) Schematic of the distribution of SnO2 and Mac-SnO2 QDs in the solutions and films.

Electrical properties are a key factor to evaluate the performance of ETLs. We determined the electrical conductivities of the two films by using the current–voltage (IV) characteristic curves. The device structure of ITO/ETL/Ag was used in the test, and the specific values were as 2.81 × 10−5 S cm−1 (SnO2) and 5.68 × 10−5 S cm−1 (Mac-SnO2), respectively (Fig. S7a).38 Additionally, we obtained the electron mobility by fabricating the space charge-limited current (SCLC) model (structure: ITO/ETL/PCBM/Ag) and by using the Mott–Gurney equation (Fig. S7b):39

 
image file: d4qi00166d-t1.tif(1)
where the physical quantities ε0, εr, L, J, and V in the formula represent the vacuum permittivity, relative dielectric constant, ETL thickness, dark current density, and applied voltage, respectively. It was verified that the electron mobility of the Mac-SnO2 ETL was 5.23 × 10−3 cm2 V−1 S−1, which was significantly larger than that of the SnO2 ETL (9.03 × 10−3 cm2 V−1 S−1). The increased conductivity and electron mobility of the Mac-SnO2 film were ascribed to inhibited non-radiative recombination and the denser ETL film without pinholes, demonstrating the electron extraction and transfer efficiency were higher.40

We next investigated the surface morphology and structure of the perovskite layers based on the two types of ETLs by SEM (Fig. 3a and b). Their cross-sectional images are displayed in Fig. 3c and d. The Mac-SnO2/perovskite grains were larger than those of the SnO2, and the Mac-SnO2/perovskite layer appeared denser and more uniform, while the control film exhibited undesirable pinholes. Consistent with a more homogeneous morphology, the AFM images show the Rq of the Mac-SnO2/perovskite films (8.56 nm) was slightly reduced compared to that of the control film (9.69 nm), indicating a smoother and superior surface quality (Fig. S8). The effect of different ETLs on the crystallization of perovskite was further explored by XRD (Fig. 3e). Two characteristic peaks at 14.0° and 28.2° were observed, indicating the (110) and (220) cubic phase of the perovskite film. Compared to the diffractions of the (110) and (220) lattice planes on the SnO2/perovskite film, those on the Mac-SnO2/perovskite film were stronger, which means the Mac-SnO2/perovskite possessed enhanced crystallinity. The different crystallizations of the perovskite films may stem from the difference in the surface groups on the ETLs. We mirrored the surface Gibbs free energies via performing contact angle analysis of the two types of ETLs (Fig. 3f). The contact angle on Mac-SnO2 (13.64°) was found to be lower than that on SnO2 (22.89°), indicating the perovskite deposited on Mac-SnO2/ETL had a lower surface Gibbs free energy and higher surface wettability.41 Lower Gibbs free energies are beneficial for the spreading of the perovskite precursor solution, uniform nucleation, and the formation of a high-crystallinity perovskite layer.42


image file: d4qi00166d-f3.tif
Fig. 3 Top-view and cross-section SEM images of perovskite layers grown on (a and c) SnO2 and (b and d) Mac-SnO2 ETL. (e) XRD patterns of the SnO2/perovskite and Mac-SnO2/perovskite. (f) The water contact angles on SnO2 and Mac-SnO2 films.

Furthermore, we conducted cross-sectional elemental mapping of the Mac-SnO2/perovskite films (Fig. S9), and found that Pb and I were evenly distributed within the perovskite, indicating uniform film growth. Surprisingly, we also detected the presence of Mn2+ in the perovskite film, suggesting that Mn2+ had diffused upward into the perovskite films. Previous reports indicate that Mn2+ can passivate I dangling bonds at perovskite grain boundaries, leading us to speculate that the diffused Mn2+ may passivate the I at the grain boundary.43,44 XPS measurements were next applied to investigate the interaction between Mac-SnO2 and the perovskite (Fig. S10), and so Mn(Ac)2 was added to the perovskite for XPS characterization. As exhibited in the I 3d spectrum (Fig. 4a), the peaks for I 3d5/2 and I 3d3/2 in the perovskite film (618.65 and 630.13 eV) moved toward higher binding energies (618.91 and 630.40 eV) after adding Mn(Ac)2, which verified the Mn2+ and the uncoordinated I interact with each other, as we had estimated. Meanwhile, it could be noted that the Pb 4f5/2 and Pb 4f7/2 peaks (142.86 and 137.98 eV) were shifted to lower binding energies of 142.69 and 137.81 eV in the Mn(Ac)2-added perovskite, implying the interactions between Pb2+ of perovskite and the C[double bond, length as m-dash]O of Mn(Ac)2 (Fig. 4b).45 In addition, we found a peak for Pb0 in the perovskite sample, which disappeared in the Mn(Ac)2-added perovskite sample, indicating that the interaction of Pb2+ dangling bonds and the C[double bond, length as m-dash]O groups suppressed the Pb0 production. Afterwards, we evaluated the charge trap density (Ntrap) of the perovskite films by adopting the SCLC model (electron-only device: ITO/ETL/perovskite/PCBM/Ag) (Fig. 4c). The formula used to calculate this is as follows:46

 
image file: d4qi00166d-t2.tif(2)
where L, e, ε, and VTFL represent the thickness of the perovskite films, elementary charge, relative dielectric constant of the perovskite, and the onset voltage of the trap-filled limit region, respectively. The calculated Ntrap of the perovskite was appreciably reduced from 3.37 × 1015 (SnO2/perovskite) to 2.27 × 1015 cm−3 (Mac-SnO2/perovskite), which corresponded to the higher quality perovskite layer without pinholes and the reduced non-radiative recombination.


image file: d4qi00166d-f4.tif
Fig. 4 XPS spectra of (a) Pb 4f and (b) I 3d for the perovskite and Mn(Ac)2 + perovskite. (c) Dark IV curves based on SnO2 and Mac-SnO2. Depth-dependent GIXRD patterns of the (d) SnO2/perovskite and (e) Mac-SnO2/perovskite, and their (f) linear fits of 2θ − sin2[thin space (1/6-em)]Ψ. (g) Residual stress diagram of the SnO2/perovskite and Mac-SnO2/perovskite.

In addition, it is known that film stress can accelerate perovskite film degradation and device failure.47 Consequently, we explored the residual stress of the SnO2/perovskite and Mac-SnO2/perovskite films by depth-dependent grazing incident X-ray diffraction (GIXRD).48–50 Variable grazing tilt angles (ψ) from 10° to 50° were selected to detect the different depths of the perovskite films. As the incidence angle increased, the characteristic peak (110) in the SnO2/perovskite film gradually shifted to lower angles due to the compressive stress caused by lattice contraction (Fig. 4d). On the contrary, there was a slight peak shift for the Mac-SnO2/perovskite film, implying a release of interfacial stress owing to the effective passivation of the uncoordinated Pb2+ at the perovskite buried interface (Fig. 4e).51 Subsequently, we fitted the 2θ as a function of sin2[thin space (1/6-em)]Ψ to evaluate the lattice strain variation more accurately, where the slopes of the fitting line represent the residual strain and were calculated by the 2θ − sin2[thin space (1/6-em)]Ψ curves (Fig. 4f). Also, the elastic stress ε can be calculated as follows:52

 
image file: d4qi00166d-t3.tif(3)
where C is the constant and E is the Young's modulus. The fitted curve had a negative slope in the SnO2/perovskite film, demonstrating severe strain; while the slope was closer to 0 for the Mac-SnO2/perovskite film, implying the residual strain was effectively eliminated. Fig. 4 g shows that the residual strain in the perovskite was significant, and there was little residual strain in the Mac-SnO2/perovskite film.

The energy level alignment between the ETL and perovskite determines the effectiveness of charge extraction and the recombination rate. Consequently, we examined the energy level of SnO2 and Mac-SnO2 by ultraviolet photoelectron spectroscopy (UPS). A decreased work function (WF) of the Mac-SnO2 was observed, calculated to be −3.12 eV, while the value for the pristine SnO2 was −3.16 eV (Fig. 5a and b).53 The valence band maximum (VBM) for both were −7.90 eV (SnO2) and −7.81 eV (Mac-SnO2), respectively. The optical band gap (Eg) values were determined using a Tauc plot derived from the UV–vis absorption spectroscopy analysis (Fig. 5c), showing values of 3.78 eV (SnO2) and 3.77 eV (Mac-SnO2). The conduction band minimum (CBM) was derived from the VBM and the Eg, and were calculated to be −4.12 eV for SnO2 and −4.04 eV for Mac-SnO2. The CBM of Mac-SnO2 was closer to the CBM of the perovskite, resulting in a smaller energy loss during electron transfer. As displayed in Fig. 5d, the energy band diagram demonstrated that the Mac-SnO2 was more beneficial for enhancing electron extraction and preventing hole transport. We further probed the surface potential of the SnO2 and Mac-SnO2 ETL via applying Kelvin probe force microscopy (KPFM) (Fig. S11). The average surface potential of the Mac-SnO2 surface (575 mV) was higher than that of the SnO2 film (460 mV), which was in line with the consequences of UPS. Additionally, we examined the interfacial electron transmission processes of the control and Mac-SnO2/perovskite films by measuring the steady-state photoluminescence (PL) (Fig. 5e). Significant PL quenching was noticed in the Mac-SnO2/perovskite film compared to the control samples, indicating a shortened carrier recombination lifetime and enhanced electron extraction.54 Besides the PL, in order to further explore the carrier dynamics of the perovskite, time-resolved photoluminescence (TRPL) analysis was performed. As depicted in Fig. 5f, the Mac-SnO2/perovskite film displayed a shorter lifetime in the first stage (τ1) (10.86 ns) than that of SnO2 (21.79 ns). The shortened lifetime indicated efficient charge transport at the Mac-SnO2/perovskite interface due to the improved interface contact and band alignment.55


image file: d4qi00166d-f5.tif
Fig. 5 UPS spectra of (a) SnO2 and (b) Mac-SnO2. (c) Tauc plots of SnO2 (left) and Mac-SnO2 (right). (d) Energy band structure diagram of the ETL and perovskite. (e) PL and (f) TRPL spectra of perovskite layers deposited on glass/SnO2 and glass/Mac-SnO2 substrates.

We fabricated complete PSCs with a structure of ITO/ETL/perovskite/HTL (Spiro-OMeTAD)/Ag to explore the influence on the device photovoltaic performance (Fig. 6a). The corresponding SEM images of devices based on the two ETLs are presented in Fig. 6b. Fig. 6c shows the reverse scanning current density–voltage (JV) curve of the two champion devices. The introduction of Mac-SnO2 led to a champion PCE of 23.36% [short-circuit current density (Jsc) = 24.96 mA cm−2, open-circuit voltage (Voc) = 1.16 V, fill factor (FF) = 80.69%], obviously higher than the reference PSC based on SnO2 (PCE = 21.11%, Jsc = 24.25 mA cm−2, Voc = 1.12 V, FF = 77.66%). The photovoltaic parameters of the forward scans are shown in Table S1. The Voc and FF displayed significant improvements, which could be mainly ascribed to the reduced bulk and interfacial non-radiative recombination, and the suitable energy band alignment of the Mac-SnO2/perovskite film, leading to rapid charge carrier extraction. Compared with the pristine sample, the PSC devices based on Mac-SnO2 demonstrated lower hysteresis, which was likely due to the efficient carrier transport and reduced non-radiative recombination (Fig. S12). Furthermore, we varied the concentrations of the Mac-SnO2 solution to determine the optimal PCE (Fig. S13). The relevant parameters are exhibited in Table S2, indicating that the best PCE was obtained when the Mn(Ac)2 concentration was 7.5 mg mL−1. Subsequently, we fabricated 20 individual devices based on the SnO2 and the optimized Mac-SnO2 layers. The statistical histogram of the PCEs and other parameters are displayed in Fig. 6d, and Tables S3 and S4. Based on the parameters, it could be concluded that the devices based on different ETLs all exhibited excellent reproducibility, with the Mac-SnO2 ETL devices showing higher PCEs. A comparative analysis of the maximum power point (MPP) was conducted to understand the steady PCE outputs and PCEs for SnO2 and Mac-SnO2 devices, respectively (Fig. 6e). The Mac-SnO2 device exhibited a stable PCE of 21.61% over 100 s, which the JV results above accorded with. Meanwhile, the SnO2 device demonstrated a stable PCE of 19.51% over time, indicating that devices with Mac-SnO2 ETLs offered greater operational stability. The external quantum efficiency (EQE) spectra of the PSCs and the integrated current density curve are exhibited in Fig. 6f, while the EQE spectra of cells with different Mac-SnO2 concentrations are shown in Fig. S14.


image file: d4qi00166d-f6.tif
Fig. 6 (a) Schematic structure of a Mac-SnO2-based PSC. (b) SEM images of the cross-sections of the SnO2- and Mac-SnO2-based devices. (c) JV curves of the optimal SnO2 and Mac-SnO2 cells. (d) PCE distributions of the SnO2- and Mac-SnO2-based devices from 20-device statistics, respectively. (e) Steady-state output of the SnO2 and Mac-SnO2 PSCs measured at MPP. (f) EQE spectra of the SnO2- and Mac-SnO2-based devices.

The performance of cells is closely associated with the trap-assisted recombination behavior. We performed light intensity-dependent Voc analysis to gain insights into the mechanism of the carrier recombination process (Fig. S15a). The relationship where Voc is dependent on the light intensity is as follows:56

 
image file: d4qi00166d-t4.tif(4)
where n, k, and I represent the ideal coefficient, Boltzmann constant, and light intensity, respectively. Compared to the n value of 1.36 for PSCs with pristine SnO2, the lower n value for the Mac-SnO2 device (1.12) indicated that trap-assisted Shockley–Read–Hall (SRH) monomolecular recombination was inhibited. Meanwhile, the light intensity-dependent Jsc analysis was performed (Fig. S15b). In general, the expression JscIα describes the relationship of the Jsc with the light intensity.57 The α of the Mac-SnO2 PSC (0.99) was closer to 1 compared to the pristine SnO2 device (0.98), which indicated the negligible bimolecular recombination of the Mac-SnO2 device. The recombination rates of PSCs were also explored by conducting transient photovoltage (TPV) measurements (Fig. S16). The Mac-SnO2 device demonstrated a longer lifetime (263 μs), while that of the SnO2 device was 126 μs. The slower carrier recombination was attributed to the reduced trap-assisted recombination, leading to the higher Voc in the Mac-SnO2 devices.58 Furthermore, carrier migration owing to defects in PSCs will result in the formation of dark current. The Mac-SnO2 devices displayed a lower leakage current, indicating inhibited non-radiative recombination at the interface (Fig. S17).59 Subsequently, electrochemical impedance spectroscopy (EIS) measurements were utilized to explore the carrier recombination and carrier-transport behaviors in the two types of devices (Fig. S18). It is well known that the high-frequency ranges in a Nyquist diagram is associated with transfer resistance (Rtr) at the ETL/perovskite interface, and the high frequency represents the recombination resistance (Rrec).60 The Mac-SnO2 devices exhibited a relatively lower Rtr value but higher Rrec value than that of the control devices, demonstrating a low electron-transfer barrier and restrained recombination at the interfaces. The built-in potential (Vbi) and the carrier-transport behavior of PSCs can be estimated via capacitance–voltage (CV) measurements (Fig. S19). The extracted Vbi values of the SnO2 and Mac-SnO2 devices were approximately 0.95 and 1.07 V, respectively. A higher Vbi is conducive to extending the depletion region to increase the driving force for photogenerated carriers and accelerate carrier transport, which were in accordance with the Voc values for the PSCs.61 The above discussions of the PSCs shows that the Mac-SnO2 ETL could effectively improve the interface electron transfer and suppress non-radiative recombination.

Besides the photovoltaic properties, the stability of cells is also crucial for practical applications. Consequently, the long-term stability of the two cells under the ambient environment (25–30 °C, 30%–40% humidity) was monitored. As depicted in Fig. 7a, the Mac-SnO2 PSC possessed an increased life. After storage for 600 h, the Mac-SnO2-based PSCs maintained 90% of the initial PCE, whereas the SnO2 PSC degraded faster, dropping to 55% of its initial efficiency. Moreover, the XRD patterns of the SnO2/perovskite film exhibited a clear peak of PbI2 after 20 days under ambient conditions (Fig. 7b). It was also observed that part of the SnO2/perovskite film changed color from black to yellow, while the Mac-SnO2/perovskite film maintained a well-preserved structure and black color (Fig. S20). We also tested the light stability and thermal stability of devices. After storing the device in a N2 atmosphere at 85 °C for 150 h, the efficiency of the Mac-SnO2 device retained 84% of its original PCE, while the SnO2 device quickly dropped to 59% of its original PCE (Fig. S21a). In addition, after lighting the devices continuously for 60 h under 1 sun illumination, the Mac-SnO2-based device retained 78% of the original PCE, while the SnO2-based device retained only 61% of the original efficiency (Fig. S21b). Consequently, the introduction of Mac-SnO2 proved to be an efficient way to improve the stability of the device.


image file: d4qi00166d-f7.tif
Fig. 7 (a) Normalized PCEs of SnO2 and Mac-SnO2 PSCs placed in the ambient environment (25–30 °C, 30%–40% humidity). (b) XRD spectra of the SnO2/perovskite and Mac-SnO2/perovskite before and after exposure to an air environment with 30%–40% humidity for 20 days.

3. Conclusion

In summary, we developed multifunctional Mac-SnO2 QDs and employed them to fabricate ETLs for PSCs. The C[double bond, length as m-dash]O groups in Mn(Ac)2 could passivate the Sn4+ on the surface of the SnO2 QDs, thereby reducing the van der Waals forces between the QDs, inhibiting QDs agglomeration, and contributing to the increased conductivity of the Mac-SnO2 ETLs. Meanwhile, the Mn2+ spread upward in the perovskite layer, passivating the I at the grain boundary and reducing perovskite bulk defects. The perovskite grown on the Mac-SnO2 ETL could release residual stress and suppress non-radiative recombination at the interface. Moreover, the well-matched energy level between Mac-SnO2 and the perovskite is beneficial for extracting and transporting electrons. Ultimately, the champion device showed an increased PCE from 21.11% to 23.36%. More importantly, the Mac-SnO2 devices also displayed enhanced long-term stability, with the PCE maintaining 90% of the original value under environmental conditions for nearly 600 h. Therefore, using multifunctional organic acid salts to stabilize SnO2 QDs offers an effective method to further improve ETL quality and PSC performance. In the future, we should further explore small ions with better passivation effects and smaller resistance to stabilize SnO2 QDs, which will further enhance the conductivity of the ETL. In addition, the use of ionic liquids to stabilize SnO2 QDs is also a method worth exploring in depth, as it can not only passivate the surface defects of QDs, but also effectively inhibit ion migration at the ETL/perovskite interface through organic ligands, thereby improving device performance and stability.

4. Experimental section

Preparation of the ETL

The SnO2 colloidal dispersion was diluted with deionized water at a ratio of 1[thin space (1/6-em)]:[thin space (1/6-em)]3. In the case of the Mac-SnO2 solution, different concentrations of Mn(Ac)2 (2.5, 5.0, 7.5, 10.0, and 12.5 mg mL−1 in deionized water) were added to the SnO2 colloid dispersion, also at a ratio of 1[thin space (1/6-em)]:[thin space (1/6-em)]3.

Fabrication of the PSCs

The ITO substrate needed to undergo washing four times with deionized water and alcohol, respectively, with each cycle requiring 20 min of ultrasonic treatment. Subsequently, the ITO substrates were treated with a 20 min exposure to ultraviolet ozone (UV/O3). The SnO2 solution and Mac-SnO2 solution were spin-coated on the ITO substrate at 3000 rpm for 30 s, then annealed at 150 °C for half an hour and then cooled to room temperature. The ITO/ETL samples were further subjected to a 20 min UV/O3 treatment. Next, in order to grow the perovskite layer, the ITO/ETL material was transferred into a nitrogen-filled glove box (with H2O and O2 concentrations of <1 ppm). In the case of the perovskite solution, it was formed by dissolving 217 mg of FAI (1.26 mmol), 643 mg of PbI2 (1.39 mmol), 27 mg of PbBr, 19 mg of CsI, 7.4 mg of MABr, and 20 mg of MACl in 1 mL mixed solvent (DMSO to DMF volume ratio of 2[thin space (1/6-em)]:[thin space (1/6-em)]8). A total of 85 μL of the Cs0.05(FA0.85MA0.15)0.95Pb(I0.85Br0.15)3 precursor solution was then deposited onto the ITO/SnO2 layer using a spin-coating process of 10 s at 1000 rpm and 30 s at 5000 rpm. At 27 s after the start of the procedure, 120 μL of CB was injected onto the rotating substrate for 2 s. The resulting films were heated for 1 h at 100 °C. Subsequently, to produce the HTL mixed solution, 72.3 mg of Spiro-OMeTAD was combined with 35 μL of Li-TFSI solution (250 mg of Li-TFSI in 1 mL of acetonitrile), 10 μL of FK209 solution (300 mg of FK209 in 1 mL of acetonitrile), and 30 μL of TBP in 1 mL of CB. Next, 85 μL of the HTL mixture was spin-coated onto the perovskite films for 30 s at 4000 rpm. The final step involved plating a 100 nm Ag layer under vacuum conditions.

For more comprehensive information regarding the materials used and the characterization processes, refer to ESI notes 1 and 2.

Conflicts of interest

There are no conflicts to declare.

Acknowledgements

The authors gratefully acknowledge the support from the National Natural Science Foundation of China (Grant No. 62275101, 22075101), Program for the Development of Science and Technology of Jilin Province (Item No. YDZJ202201ZYTS300, 20210509050RQ).

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Footnote

Electronic supplementary information (ESI) available. See DOI: https://doi.org/10.1039/d4qi00166d

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