1. Introduction

The need to replace fossil fuels with alternative energy sources has driven increased scientific interest in using solar energy. In contrast to first-generation silicon solar cells, new photovoltaic technologies have been developed to simplify manufacturing processes and reduce infrastructure costs. As emerging technologies, organic and perovskite solar cells show promising potential, and both types of devices are built in similar architectures. Ternary organic solar cells (TOSCs) are being studied in the field of organic photovoltaics (OPV), as they offer improved efficiency and stability at relatively low costs [1,2]. As perovskite solar cells (PSCs) have become highly efficient in a very short time, much research effort is currently focused on the optimization of device interlayers [3,4,5].

Hybrid organic/inorganic perovskite solar cells (PSCs) are highly promising in photovoltaics because of their optoelectronic properties, including an excellent absorption coefficient, long carrier diffusion length, tuneable bandgap, and high mobility of the charge carriers [6,7,8]. Additionally, PSCs offer the advantage of a low-cost manufacturing process [9,10]. The power conversion efficiency (PCE) of PSCs with a regular (n-i-p type) structure has rapidly increased from its initial value of 3.8% [11] to the current 26.0% [12], which approaches the PCE of crystalline silicon solar cells [13,14]. However, the n-i-p type devices have some drawbacks, such as the high-temperature processing (500 °C) required for curing the mesoporous TiO₂ of the electron transport material (ETM). In addition, the requirements for the hole transporting materials (HTMs), such as high hole conductivity and mobility, high thermal stability, and a proper energy level, reduce the number of potential candidates. To overcome these issues, an emerging inverted planar PSC (p-i-n type) structure was designed by Guo et al. [15]. This p-i-n type configuration shows many advantages compared to their regular counterparts, e.g., low-temperature processing and compatibility with large-scale fabrication [16,17], severely suppressed hysteresis effects, and good compatibility with the flexible substrate. Several studies have been recently published showing efficiencies near 25% [18,19].

Since HTMs and ETMs can aid the extraction of the free charge carriers at the corresponding electrodes [20], the exploration of new transporting materials has been one of the strategies to reduce the performance gap between both architectures, as they play a key role in the stability of the devices [21]. In inverted PSCs (iPSCs), the quality of the HTM film is crucial, since this affects the crystallinity and morphology of the perovskite film [22]. Conductive polymers such as polytriarylamine (PTAA) and poly(3,4-ethylenedioxythiophene)/poly(styrene sulfonic acid) (PEDOT:PSS) have been widely used as HTMs. They can modify the hydrophilic nature of the perovskite surface, reducing moisture [23], and enabling less sophisticated depositing methods [24] and lower-temperature annealing [25]. However, devices based on these polymeric HTMs still have some drawbacks that limit their future scaling up. The PEDOT:PSS-based devices yield moderate V_oc values below 1.0 V, owing to the relatively low work function that does not match well with that of the perovskite [26]. These devices also present lower stability due to the hygroscopic nature and the acidity of PEDOT:PSS, accelerating the degradation of the perovskite (PVK) [27,28]. Finally, PEDOT:PSS can be partly dissolved by the precursor solvent of the PVK, resulting in nonhomogeneous films [23]. Doping of PEDOT:PSS to simultaneously improve its conductivity and reduce degradation issues has been explored by a few authors [29,30]. On the other hand, PTAA promotes higher V_oc and power conversion efficiency (PCE) values. However, its high hydrophobic nature causes a more complex deposition method, which reduces the reproducibility of devices with higher charge recombination due to heterogeneous growth of the perovskite [31]. The high PTAA price, together with the need for doping [32], hinders its application in large-scale iPSC fabrication. To solve these concerns, several dopant-free small molecular HTMs have been synthesised using different types of central core moieties (e.g., thiophenyl, carbazole, truxene, pyrene, triphenylamine [20,31,33,34,35]). The utilization of small organic molecules as HTMs enables the production of extremely thin films (<20 nm), resulting in higher mobilities without the need for doping [36,37]. This can be accomplished using only a minimal quantity of the material. HTMs containing spiro-core structures extract holes more efficiently from the adjacent perovskite layer, as their perpendicular core geometry can prevent intermolecular π-π interactions, and form amorphous homogeneous layers [38,39,40,41]. Generally, the rigid 3D core structure is detrimental to hole mobility. However, the introduction of diverse functional groups could enhance the mobility of spiro-based thin films and modify the energy of the interface [42,43,44], which alters the crystal morphology of the perovskite layer.

Herein, in this work we present the design and synthesis of a novel spiro-type HTM (Syl-SC) by replacing one of the methoxyphenyl groups by ethoxytriisopropylsilane for each N atom, as shown in Scheme 1. We have investigated the effects of the Syl-SC on the performance of p-i-n type PSCs based on CsFAMA triple-cation perovskite (Table 1). Reference cells were prepared using PEDOT:PSS and doped and undoped Spiro-OMeTAD (N2,N2,N2′,N2′,N7,N7,N7′,N7′-octakis(4-methoxyphenyl)-9,9′-spirobi[9H-fluorene]-2,2′,7,7′-tetramine) [45]. The incorporation of the triisopropylsilylether group improves the compound solubility [46], giving rise to uniform, hydrophobic, and high transmittance films, which can be easily deposited by spin-coating under environmental conditions.

After device optimization, we realized that the PCE of perovskite solar cells shows strong dependence on the thickness of the Syl-SC layer, which can be modulated by the precursor Syl-SC solution concentration. Impedance spectroscopy and transient optoelectronic measurements were carried out to further understand the interfacial charge recombination.

2. Materials and Methods

2.1. Materials

The PEDOT:PSS was purchased from Heraeus Deutschland GmbH and Co. KG, Hanau, Germany, Lead(II) bromide (PbBr₂) and lead(II) iodide (PbI₂) were acquired from TCI; formamidinium iodide (FAI) and methylammonium bromide (MABr) and were purchased from Dyenamo (99.99%). Cesium iodide (CsI) and all the anhydrous solvents, i.e., dimethyl sulfoxide (DMSO), dimethyl formamide (DMF), and chlorobenzene (CB), were purchased from Sigma Aldrich (St. Louis, MO, USA) and used without further purification. The patterned indium tin oxide (ITO, 15 Ω/square) glass substrates were provided by Xin Yan Technology Ltd., Hong Kong.

2.2. Deposition of the HTMs

The solution of PEDOT:PSS was spin-coated onto the ITO substrate at 5000 rpm for 45 s, and then annealed on a hot plate at 150 °C for 10 min in air. The Syl-SC was dissolved in chlorobenzene with three different concentrations (2, 0.8, and 0.5 mg/mL) and spin-coated on top of the ITO substrate at 3000 rpm for 30 s, and then annealed at 100 °C for 10 min in air.

2.3. Preparation of the Perovskite Triple-Cation Cs_0.05FA_0.79MA_0.16Pb(I_0.85Br_0.15)₃ (CsFAMA) Precursor Solution

The preparation of the perovskite precursor solution has been reported in our earlier works [45]: The perovskite precursors FAI (1.1 M), MABr (0.2 M), PbI₂ (1.15 M), and PbBr₂ (0.2 M) were dissolved in anhydrous DMF:DMSO (4:1 v/v). Then, 42 µL of a CsI stock solution (1.5 M in DMSO) was added to the mixed perovskite solution. The precursor solution was stirred and then filtered using a PTFE filter head (pore size of 0.22 µm).

2.4. Device Fabrication

The structure of the inverted planar PSCs (iPSCs) was ITO/HTM (PEDOT:PSS or Syl-SC)/CsFAMA/C₆₀/BCP/Ag, as illustrated in Figure 1a. Prepatterned ITO glass substrates were sequentially cleaned with Mucasol solution (2% in deionized water), DI water, ethanol, and IPA in an ultrasonic bath for 10 min each. Firstly, 60 µL HTM (PEDOT:PSS or Syl-SC) solution was spin-coated onto the clean ITO substrate and annealed, then the ITOs were cooled down to room temperature and transferred into a N₂-atmosphere glovebox. Next, the deposition of the triple-cation perovskite layer was achieved in a N₂ glovebox by spin-coating onto the HTM film in a static antisolvent-assisted two-step procedure at 1000 rpm for 10 s, and 4000 rpm for 25 s, followed by the addition of 110 µL on the spinning substrate during the last 12 s for the antisolvent step. After that, the samples were annealed for 40 min at 100 °C. Afterwards, 20 nm of C₆₀ and 8 nm of bathocuprine (BCP) were thermally evaporated successively on top of the perovskite layer as electron-selective layers. Lastly, a 100 nm Ag layer was deposited at low pressure (10⁻⁶ bar) to complete the device. The active area of all devices is 0.09 cm².

2.5. Device Characterizations

The current density–voltage (J–V) curves were recorded using a Keithley source measure unit (Model 2400) as a voltage source, and a solar simulator ABET technologies, (model 11,000 class type A) as the light source. The measurements were registered under 1 Sun conditions (100 mW/cm², AM 1.5 AG) calibrated with a silicon reference cell. The devices were sealed in a holder under a N₂ atmosphere. The EQE spectra were recorded using a quantum efficiency measurement system from Lasing, S.A. (IPCE-DC, LS1109-232) with a Newport 2936-R power-meter unit. The light dependence of the open circuit voltage (V_oc) and short-circuit current density (J_sc) was established by measuring the J–V characteristics under different light intensities using a set of optical density filters.

The images of the surface morphology of the perovskite film were taken with a field emission scanning electron microscopy (FESEM, Thermo Fisher Scientific model Scios 2, Waltham, MA, USA).

Photoinduced charge extraction (CE) and transient photovoltage (TPV) measurements were performed in open-circuit voltage equilibrium by illuminating the devices using a white light LED ring from LUXEON^®, Lumileds, The Netherlands. The white LED ring is connected to a programmable power supply and a control box that controls the applied bias, providing different light intensities switched from open- to short-circuit states. All of the signals were recorded using a Yokogawa DLM2052 oscilloscope (Yokogawa Electric Corporation, Tokyo, Japan), which registers the voltage drops. In TPV measurements, the small light perturbation pulses were provided by a nanosecond PTI GL-3300 nitrogen laser with a 580 nm laser pulse wavelength (<100 ns pulses). Impedance spectroscopy (IS) measurements were carried out with a frequency range of 5 Hz–1 MHz at forward applied bias voltages of 0.75 V and an AC signal with 50 mV amplitude under 1 sun (AM 1.5 G) illumination using an HP-4193A impedance analyser, Hewlett-Packard Company, Palo Alto, CA, USA.

3. Results and Discussion

3.1. Synthesis and Photoelectrochemical Properties

Scheme 1 depicts the synthesis pathway of the Syl-SC molecule. The spiro-type fluorine core [55] was incorporated through a Buchwald–Hartwing coupling [56,57] from the commercial 2,2′,7,7′-tetrabromo-9,9′-spirobi[fluorene], and the secondary amine 2. The initial amine 1 was synthesized using a well-established procedure involving a nucleophilic substitution between 4-iodoanisole and ethanolamine [58]. The protection of the hydroxyl group with the triisopropylsilyl [56] produces the silyl amine 2. Syl-SC was obtained with a good yield, and its chemical structure was characterized using nuclear magnetic resonance (NMR) spectroscopy (Figure S2, Supporting Information). The thermal properties were investigated using thermogravimetric analysis (TGA) and differential scanning calorimetric (DSC) methods (Figure S3, Supporting Information). From TGA analysis, it can be deduced that Syl-SC exhibited lower thermal stability compared to Spiro-OMeTAD, with a decomposed temperature at 123 °C, and 170 °C for the spiro (Table S1, Supporting Information), probably due to the N-ethoxytrialkylsislylether substituent incorporation. Considering that Syl-SC is a viscous oil under ambient conditions, and DSC measurements showed one glass transition at 171 °C for Syl-SC (Table S1), we can assume a polymorphic behaviour, as well as for the Spiro-OMeTAD counterpart [59].

Differential pulse voltammetry (DPV) and cyclic voltammetry (CV) were used to analyse the electrochemical properties of Syl-SC (Figure S4, Supporting Information) using tetrabutylammonium hexafluorophosphate (0.1 M) as the supporting electrolyte, a Pt counter electrode, a glassy carbon working electrode, and Ag/AgCl reference electrode. The redox potential and frontier orbitals are gathered in Table S2 (Supporting Information). The highest occupied molecular orbital (HOMO) level was obtained from the half-wave potentials determined by CV, E_HOMO = −($E_{OX}^I$ + 4.8). Additionally, the optical band gap energy (E_g) was utilized to estimate the lowest unoccupied molecular orbital (E_LUMO = E_g + E_HOMO). Figure 1b illustrates the energy level alignment for the materials employed in the iPSCs. The low HOMO energy level of PEDOT:PSS usually yields a V_oc between 0.85 and 1 V [30]. The Syl-SC has a deeper HOMO energy level than PEDOT:PSS, which better matches the valence band of CsFAMA. The high energy gap between the LUMO of Syl-SC to the CsFAMA conduction band indicates that Syl-SC can effectively block the injection of electrons from the perovskite to the anode, and suppress the current leakage. On the other hand, an effective electron transfer to the cathode is expected due to the proper alignment between the conduction band of perovskite and the lowest unoccupied molecular orbital (LUMO) levels of the electron transport layers (ETLs). The energy levels for ITO, PEDOT:PSS, CsFAMA, C₆₀, BCP, and Ag were taken from the literature [21,31,60,61,62].

3.2. Electrical Characterization and Performance Analysis

The photovoltaic performance of iPSC devices containing Syl-SC as a dopant-free HTL was evaluated using the triple-cation perovskite CsFAMA as the absorber layer. Similar iPSCs using PEDOT:PSS as the HTM were fabricated as a reference, and compared with reference devices made of doped and undoped spiro. We studied the effects of Syl-SC thickness on the performance parameters of iPSCs by tuning the Syl-SC concentration in the chlorobenzene solution. The current density vs. voltage (J–V) curves of the best-performing iPSCs are shown in Figure 2a with PEDOT:PSS and three different Syl-SC concentrations, 0.5 mg/mL, 0.8 mg/mL, and 2 mg/mL, under 1 Sun illumination (AM 1.5G, 100 mW/cm²). The best-performing parameters of the optimization of Syl-SC concentration are summarized in Table 2. Average PCE and standard deviation values were calculated from over eight devices. Statistical results for the devices that contain PEDOT:PSS and Syl-SC with three different concentrations are shown in the Supporting Information (Figure S5). We observed a decrease in the PCE, V_oc, and fill factor (FF) of devices with a Syl-SC concentration of 2 mg/mL, whereas the J_sc is quite similar to that of devices with 0.5 mg/mL and 0.8 mg/mL. PCE significantly improves by reducing the Syl-SC concentration from 2 mg/mL (PCE = 13.07%) to 0.5 mg/mL (PCE = 15.09%); however, we observe a lack of reproducibility in the devices fabricated with 0.5 mg/mL of Syl-SC solution. Notably, when using a Syl-SC concentration of 0.8 mg/mL, both V_oc and FF were simultaneously improved, affording an increment of the PCE up to 15.77%.

The J–V curves of devices made with Syl-SC and PEDOT:PSS showed a low hysteresis effect; however, in devices with Syl-SC, the hysteresis reduced the FF and V_oc, while in PEDOT-PSS-based devices, the hysteresis had a major effect on the FF. The hysteresis index (HI), HI = (PCE_reverse − PCE_forward)/(PCE_reverse) [63], was calculated to quantify the discrepancy between the two scanned efficiencies. The best Syl-SC device (0.8 mg/mL) shows the lowest hysteresis index in comparison with both PEDOT:PSS and spiro-based reference devices. The champion device based on Syl-SC exhibited the highest PCE of 15.77% (reverse scan), with a J_sc of 20.00 mA/cm², a V_oc of 1.006 V, and an FF of 80.10%. On the other hand, the champion device based on PEDOT:PSS exhibited a PCE of 14.76% (reverse scan), with a J_sc of 21.37 mA/cm², a V_oc of 0.866V, and an FF of 79.70%, values that are higher than the references made with doped and undoped spiro in our previous work [45]. Thus, we have continued our work, taking as a sole reference the device made with PEDOT:PSS. The higher PCE of the iPSC with Syl-SC (0.8 mg/mL) can be mainly attributed to its higher V_oc compared to the device with PEDOT:PSS (1.006 and 0.866 V, respectively). However, the iPSC with PEDOT:PSS exhibits a higher J_sc than that of the Syl-SC-based device (21.37 and 19.57 mA/cm², respectively). To validate the J_sc calculated from J–V curves, external quantum efficiency (EQE) measurements were performed on devices with Syl-SC and PEDOT:PSS. Figure 2c displays the EQE spectra and the integrated J_sc of the PSCs. The integrated J_sc, calculated from the EQE, is 21.45 mA/cm² for PEDOT:PSS and 19.25 mA/cm² for Syl-SC, which fits with the current density extracted from the J–V curve.

3.3. Morphological Characterization of the Films

Since the hole-transporting layer can influence the crystallinity and morphology of perovskite film, surface modifications of the HTL layer have been investigated. Images of the water droplets on the surface of PEDOT:PSS and Syl-SC are shown in Figure S6 of the Supporting Information. The contact angle (CA) test demonstrated the hydrophilic nature of the PEDOT:PSS film, with a CA of 16°, whereas the Syl-SC film exhibited a higher contact angle of 73°. The higher wettability of the bottom layer promotes better spreading of the perovskite precursor solution during the spin-coating process. Nevertheless, some studies have reported that a relatively hydrophobic surface promotes the formation of high-quality polycrystalline films compared to those deposited on a hydrophilic surface [22]. In addition, the effects of HTMs on the surface morphology of CsFAMA films were characterized by a field emission scanning electron microscope (FESEM). The FESEM images show a highly smooth surface for the PEDOT:PSS film (Figure S6c, Supporting Information), while Syl-SC forms a structured domain surface (Figure S6d, Supporting Information). The FESEM images of CsFAMA grown on PEDOT:PSS and Syl-SC (0.8 mg/mL) are shown in Figure 3a,b, respectively. It is noteworthy that perovskite films presented a smooth surface and full coverage in both HTMs, and pinholes between grain boundaries were not observed. As evidenced by the FESEM surface images, the CsFAMA film grown on Syl-SC showed a smaller grain size than that of CsFAMA deposited on PEDOT:PSS. The grain size distribution analysis (Figure 3c) reveals a perovskite average grain size difference of more than 100 nm between the two studied bottom substrates. The Syl-SC film promotes the formation of smaller CsFAMA crystals (approximately 163.9 nm in diameter) compared to PEDOT:PSS (approximately 271.6 nm).

The larger crystals observed on PEDOT:PSS indicated a better growth of the perovskite film, which can explain the higher J_sc value for the PEDOT-PSS-based device [22,31]. Figure 3d displays a cross-sectional view obtained by FESEM of the iPSC based on Syl-SC. The image shows a compact and clear multilayered structure with well-defined interfaces. The cross-sectional FESEM images show that Syl-SC promotes a proper crystallization of CsFAMA. The thickness of all layers that integrate the device was measured from the FESEM images (see Figure S7, Supporting Information).

3.4. Charge Recombination Characterization

To assess the influence of the Syl-SC interlayer on the interfacial charge recombination in devices, we analysed the light intensity dependence of V_oc and J_sc. Figure 4a shows the variation of J_sc against light intensity (P_light) fitted by the power-law function $J_{SC}={P_{light}}^{\alpha }$, where $\alpha$ represents the second-order bimolecular recombination degree. A power ($\alpha$) value ~1 suggests that the charge recombination mechanism can be mostly assigned to the monomolecular recombination processes, whereas the bimolecular recombination is negligible under short-circuit conditions [64,65]. The estimated $\alpha$ value of samples with Syl-SC and PEDOT:PSS were 0.95 and 0.90, respectively, which suggested a low contribution of bimolecular recombination. However, the slightly higher $\alpha$ value indicates that Syl-SC can better reduce the bimolecular recombination than PEDOT:PSS. Figure 4b shows the light intensity dependence of V_oc. The semilogarithmic V_oc vs. P_light plot was fitted by the equation $V_{OC}=n_{id} ( kT/q ) Ln {(P}_{light})+C$, where $n_{id}$ is the ideality factor, k is the Boltzmann constant, T is the temperature, q is the elementary charge and C is a fitting parameter. The expected n value ranges between 1 and 2 ($1\le n_{id}\le 2$); the bimolecular recombination is dominating if the $n_{id}$ value approaches 1, while the monomolecular recombination mechanisms are responsible for the charge recombination (e.g., trap-assisted and geminate recombination) when $n_{id}$ values are close to 2 [66,67]. The devices with PEDOT:PSS and Syl-SC exhibited similar $n_{id}$ close to 1 (1.05 and 1.10), which indicates both HTMs can suppress the monomolecular recombination under open-circuit conditions. These results suggest that Syl-SC enables perovskite films of good quality with low defects or impurities at the HTM/CsFAMA interface and at grain boundaries, which reduces the monomolecular recombination [68].

We also carried out electrochemical impedance spectroscopy (EIS) measurements to investigate charge recombination. Figure 4c displays the Nyquist plots of devices with PEDOT:PSS and Syl-SC measured under 1 Sun illumination at 0.75 V bias. Both iPSCs presented one typical semicircle shape corresponding to the resistor/capacitor circuit [69]. The EIS responses were interpreted using an equivalent-circuit model with one external series resistance (R_series) and one resistor/capacitor (RC) element, as shown in the inset of Figure 4c. The fitting parameters of the circuit elements are summarized in Table S3 (Supporting Information). Since the iPSCs have similar structures, and the only difference lies in the HTM layer, the changes in the EIS measurements are attributed to the HTM/CsFAMA interface. The R_series is associated with the contact resistances and sheet resistance of ITO, and can be estimated from the high-frequency range. The similar R_series of iPSCs with PEDOT:PSS and Syl-SC (7.18 and 7.30 Ω, respectively) indicate that there are no major differences in the hole-extraction dynamics between devices with the two HTMs. On the other hand, the characteristic semicircle describes the electrochemical behaviour of devices, which involves geometrical capacitance (C1) and interfacial charge recombination resistances (R1). The recombination resistance (R1 in Table S3) is 35.01 Ω and 25.11 Ω for devices with Syl-SC and PEDOT:PSS, respectively. The larger recombination resistance implies lower recombination losses; thus, Syl-SC can better suppress the interfacial charge recombination.

To obtain further insight into the effects of Syl-SC on the charge recombination dynamics, we carried out charge extraction (CE) and transient photovoltage (TPV) measurements under standard device PV operating conditions in terms of light intensity and applied voltage [70], which is important for PSCs that display light intensity-dependent properties [71,72,73]. As a large modulation transient method, CE is a measurement that allows extraction of all the charges present in the solar cell once the V_oc of the device is stabilized, and while the illumination is switched off. After a short circuit of the solar cell, the resultant transient discharging current is measured through a small external load resistor. Figure 5a shows the charge extraction of the device obtained applying different open circuit voltages under illumination. The charge density exhibited two different regimes, linear and exponential. The linear trend in the voltage region 0–0.8 V is attributed to accumulated charge at the electrodes (geometrical capacitance). On the other hand, after 0.8 V, the charge carrier density exhibited an exponential dependency on the applied voltage, and is related to the accumulated charge at the HTM/perovskite/ETM interfaces (chemical capacitance). The charge density within the bulk of the device is estimated by subtracting the geometrical capacitance from the CE data. The charge density at the bulk (solid lines in Figure 5a) shows a more pronounced slope at 0.7–0.85 V for the PEDOT:PSS, and at 1 V for Syl-SC. The better energy alignment between the HOMO of the Syl-SC and the perovskite valence band (VB) would be the reason for these differences in the charge vs. voltage. As previously reported [74], the resulting V_oc arises from the respective HOMO energy level [75], as well as the disorder of the density of states and the recombination constant [72,76]. So thus, we analyse the interfacial carrier losses using TPV measurements in the different solar cell devices. Figure S8 (Supporting Information) shows the variation of the carrier lifetime (${\tau }_{∆n}$) as a function of the V_oc. To analyse the recombination kinetics more effectively, we compare the carrier lifetime (extracted from the TPV plot) as a function of charge density (extracted from the CE plot), as shown in Figure 5b. Thus, we compare the differences in carrier lifetime under a determinate charge value (vertical solid line at 4 × 10⁻⁸ C/cm²), as shown in the inset of Figure 5b. The recombination in the devices with PEDOT:PSS is one order of magnitude faster than that of devices with Syl-SC, which explains the differences in V_oc values. Thus, Syl-SC can better reduce the charge recombination than that PEDOT:PSS. This result agrees with those obtained from light intensity-dependence of V_oc and J_sc, and impedance spectroscopy analyses.

4. Conclusions

To summarize, we have successfully synthesized a new hole-transporting small molecule, Syl-SC, and used it as a dopant-free hole-transport layer (HTL) for inverted planar perovskite solar cells (PSCs) under ambient conditions. We showed that optimizing the thickness of the HTL is an effective approach to enhance the device performance in the inverted configuration. The champion device with a PCE of 15.77% is made of a 15 nm ultrathin HTL obtained from a Syl-SC precursor solution of 0.8 mg/mL. Compared to the control PEDOT:PSS HTL and references with undoped and doped Spiro-OMeTAD, the Syl-SC HTL improved the V_oc of iPSCs devices because of several reasons. This improvement can be attributed to the deeper HOMO energy level of Syl-SC, which better aligns with the valence band of the CsFAMA. Further analysis using impedance spectroscopy and transient optoelectronic measurements revealed that the Syl-SC HTL significantly reduced interfacial charge collection, improved fill factor (FF), and overall device efficiency. These findings demonstrate that modifying the well-known Spiro-OMeTAD through side-chain engineering is a promising strategy for developing efficient hole-transporting materials (HTMs), without the need for chemical dopants.

Footnotes

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Scheme 1. Synthesis route of Syl-SC.

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Figure 1. (a) Device architecture. (b) Comparison of the energy levels of the components of the device.

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Figure 2. (a) J–V curves of devices based on Syl-SC at different concentrations at reverse scan under AM 1.5 g illumination. (b) J–V curves (forward and reverse scans) of the best PCSs prepared with PEDOT:PSS and Syl-SC HTMs under AM 1.5 g illumination. (c) EQE spectra (line and symbols) and integrated short-circuit current density (solid lines).

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Figure 3. Top view surface FESEM images of (a) PEDOT:PSS; (b) Syl-SC (0.8 mg/mL); (c) CsFAMA grain size distribution on PEDOT:PSS (red)/Syl-SC (green) calculated from [Forumla omitted. See PDF.]150 grains from FESEM images; (d) cross-sectional FESEM image of the p-i-n device with Syl-SC as the HTM.

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Figure 4. (a) Dependence of Jsc on the light intensity. The experimental data (symbols) are fitted (solid lines) using [Forumla omitted. See PDF.]; (b) dependence of Voc on the light intensity. The experimental data (symbols) are fitted (solid lines) using [Forumla omitted. See PDF.]; (c) impedance spectroscopy Nyquist plot for iPSCs with PEDOT:PSS and Syl-SC measured under 1 Sun illumination at 0.75 V bias. The inset shows the equivalent circuit model used to fit (solid lines) the experimental data (symbols).

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Figure 5. (a) CE under different open light biases for PSC with Syl-SC and PEDOT:PSS as hole transport layers. Symbols represent the geometrical and chemical capacitances. Dashed lines correspond to the linear fitting of the geometrical capacitance. The solid lines represent the charge density at the bulk after subtracting the geometrical capacitance. (b) Charge carrier density (n) from CE versus the carrier lifetime from TPV measurements, both capacitive contribution and bulk dynamics representation.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/nano13142042/s1, Figure S1: Infrared spectra in KBr of Syl-SC compound; Figure S2: (a) ¹H NMR spectrum of Syl-SC (300 MHz, CD₃COCD₃), (b) ¹³C NMR spectrum of Syl-SC (75 MHz, CD₃COCD₃); Figure S3: (a) Thermogravimetric analysis (TGA) curve of Syl-SC; method 30–900 °C to 10 °C/min under 80.0 mL/min of N₂. (b) Differential scanning calorimetry (DSC) trace of Syl-SC measured under N₂ flow at heating and cooling of 10 °C/min from 30 to 300 °C; Table S1: Thermal properties of HTM; Figure S4: (a) UV-vis of Syl-SC in CH₂Cl₂ solution. (b) Tangent to the UV-vis absorption curve on the side of lower energy to estimate the transition energy (E_g) from the transition wavelength (λ_trans). (c) Differential pulse voltammetry (DPV) and (d) cyclic voltammetry in CH₂Cl₂ solution for Syl-SC vs. Ag/AgCl; Table S2: Optical and electrochemical properties of Syl-SC; Figure S5: Devices based on PEDOT:PSS and Syl-SC at different concentrations. (a) Performance device (PCE) boxplot; (b) open circuit voltages (V_oc) boxplot; (c) current density (J_sc) boxplot; and (d) fill factor (FF) boxplot; Figure S6: The contact angles between HTL film and water droplet on the substrate of (a) PEDOT:PSS and (b) Syl-SC. Top surface FESEM of (c) PEDOT:PSS and (d) Syl-SC; Figure S7: Cross-sectional FESEM image of the p-i-n device containing Syl-SC as HTM with the thickness of the layer’s components; Table S3: Impedance parameters extracted from Nyquist plots fitted with the electrical equivalent circuit; Figure S8: Charge carrier lifetime (${\tau }_{∆n}$) as a function of device V_oc. References [56,58,77,78] are cited in the Supplementary Materials.

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