Abstract
Eliminating the excess energetic driving force in organic solar cells leads to a smaller energy loss and higher device performance; hence, it is vital to understand the relation between the interfacial energetics and the photoelectric conversion efficiency. In this study, we systematically investigate 16 combinations of four donor polymers and four acceptors in planar heterojunction. The charge generation efficiency and its electric field dependence correlate with the energy difference between the singlet excited state and the interfacial charge transfer state. The threshold energy difference is 0.2 to 0.3 eV, below which the efficiency starts dropping and the charge generation becomes electric field-dependent. In contrast, the charge generation efficiency does not correlate with the energy difference between the charge transfer and the charge-separated states, indicating that the binding of the charge pairs in the charge transfer state is not the determining factor for the charge generation.
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Introduction
In a single-particle state picture, the photoelectric conversion process in organic solar cells (OSCs) involves the transition from an initial singlet (S1) excited state with energy Egopt generated by light absorption to a final charge-separated (CS) state with energy ECS (Fig. 1). In the CS state, there is a pair of free positive and negative charges, which are present in the donor and acceptor, respectively. Thus, ECS can be regarded as the energetic difference between the onset energy of the lowest unoccupied molecular orbital band (ELUMOA) for the acceptor and that of the highest occupied molecular orbital band (EHOMOD) for the donor. The enthalpy difference between the two states (Egopt − ECS) is the primary energetic driving force for the overall charge generation. In high-performance OSCs, internal quantum efficiencies (IQEs) as high as 100%1,2 and fill factors (FFs) of upto 80%3,4 have been reported, comparable with inorganic and perovskite solar cells5. The high FF is associated with flat current-voltage curves around the short-circuit condition, which indicates that the charge generation efficiency is independent of the electric field at the donor/acceptor (D/A) interfaces. These observations have proved that efficient, electric field-independent photoelectric conversion using organic semiconductors is possible with a sufficiently large driving force of Egopt − ECS. However, this excess energy (Egopt − ECS) is wasted as heat, resulting in large overall energy loss in the form of low open-circuit voltage (VOC). This fundamental trade-off between the energetic driving force for charge generation and the cell voltage is a reason for the power conversion efficiency (PCE) of OSCs being limited to 15% to date6. Therefore, the essential question in realizing efficient OSCs beyond the current limit is how much the excess energy can be reduced to increase VOC while maintaining efficient charge generation.
Several experimental studies have shown that the relaxed charge transfer (CT) state at the D/A interface is the main precursor for the charge separation process7,8,9. The overall energy loss during the charge generation can, therefore, be separated into two components: the exothermic transition from the S1 to CT states and the subsequent endothermic transition from the CT to CS states, written as
where ECT is the lowest energy of the CT state. Egopt − ECT represents the energetic loss to form the CT state and ECS − ECT corresponds to the binding energy of the charge pairs in the CT state.
Recently, Egopt − ECT has been used as an empirical indicator to show the low energy loss for mixed bulk heterojunction (BHJ) OSCs. High photoelectric conversion efficiency with Egopt − ECT of 0.1 eV or even smaller has been proposed10,11,12. However, there is a fundamental problem in estimating the interfacial energetics of BHJs due to their microscopic inhomogeneity; the disorder and the molecular intermixing can change the molecular properties at the D/A interface substantially compared with those in the bulk13,14,15. Therefore, for BHJs, using the bulk Egopt, EHOMOD, and ELUMOA values measured for the pristine materials to calculate the overall energy loss is questionable. Moreover, large deviations in molecular properties near the D/A interface in BHJs make it difficult to discuss the data reported from different groups for various material combinations. In contrast, planar heterojunctions (PHJs) are a suitable structure for investigating the direct correlation between the interfacial properties and the device performance16,17,18,19,20,21,22,23 because of their well-defined interfacial structure. Even with PHJs, however, reliable discussion of the interfacial energetics has suffered from the uncertainty of ELUMOA due to the lack of accurate measurement methods, leading to a lack of quantitative studies of the intrinsic link between the interfacial energetics and the photoelectric conversion process.
In this study, we systematically investigate the charge generation in OSCs with 16 combinations of four donor polymers and four acceptors using PHJ structure. A well-defined interface of PHJs allows us to eliminate the effects of the complicated mixed interfaces and the inhomogeneity of the structures. We also use reliable electronic PHJ properties, such as EHOMOD and ELUMOA, which are directly measured by ultraviolet photoemission spectroscopy (UPS) and low-energy inverse photoemission spectroscopy (LEIPS)24,25 for each pristine film. The correlations of the charge generation efficiency and its electric field dependence with the energetic difference of Egopt−ECT and ECS−ECT are investigated to explore the minimum requirement of the energetic driving force in efficient OSCs.
Results
Molecular structures and energy levels of materials
Figure 2a shows the molecular structures of the materials used in this study. P3HT, PDCBT, PTB7, and J61 were used as representative polymer donors. These polymers have different electronic structures, although they can all show high external quantum efficiencies (EQEs) of more than 65% in mixed BHJ structures with the proper acceptors26,27,28,29. One fullerene derivative (PCBM) and three non-fullerene materials (BTAs) were used as the acceptors. BTAs have similar core π-conjugated structures but different energy levels due to their different end functional groups. Using BTAs as the acceptor in BHJ-type OSCs gave a high VOC (1.15–1.30 eV) with a PCE of upto 8.25%30,31,32.
Figure 2b shows the energy levels of the eight materials. EHOMOD and ELUMOA values were measured by UPS (Supplementary Fig. 1) and LEIPS (Supplementary Fig. 2), respectively. The energy levels are presented with the aligned Fermi level (EF = 0) because of the equilibrated charge distributions when the materials are in contact. The energy levels with respect to the vacuum level are shown in Supplementary Fig. 3. The cross point of the optical absorption and emission spectra for the film state was used to determine the energy of the S1 state (Egopt; Supplementary Fig. 4). The dotted lines in Fig. 2b indicate EHOMOD + Egopt and ELUMOA−Egopt for the donors and the acceptors, respectively. ECS of the PHJ systems was defined as the difference between ELUMOA and EHOMOD for each combination of materials (Supplementary Table 1).
Solar cell characteristics
The PHJ devices with the combinations of the four donor polymers and the four acceptors were prepared. Supplementary Table 2 shows the film preparation conditions. Each donor film was transferred onto the acceptor film by the water-assisted contact film transfer method reported elsewhere33,34 (see also the Methods section for details). The device structure was indium tin oxide (ITO)/polyethylenimine ethoxylated (PEIE)/acceptor/donor/MoOx/Ag. Current density-voltage (J-V) characteristics were recorded under AM1.5 100 mW cm−2 simulated sunlight irradiation. The J-V characteristics and EQEs are shown in Supplementary Figs. 5 and 6. Short circuit current density (JSC), VOC, FF, and PCE of all the OSCs are summarized in Supplementary Table 3.
Evaluation of E CT
Two main empirical methods have been proposed to obtain ECT at the D/A interface of OSCs. First, we measured the temperature (T) dependence of the J-V characteristics under light irradiation and evaluated ECT by linearly extrapolating the qVOC-T plot to 0 K according to the literature35,36. This method relies on the assumptions that the non-geminate charge recombination occurs exclusively through the single manifold of the interfacial CT state and that the non-radiative component of the charge recombination does not occur at 0 K. We observed that the qVOC-T plots for all the combinations of materials showed linear relationships in the range of 300 to 210 K (Supplementary Fig. 7), as previously reported35,36. We used the intersections of qVOC at 0 K as ECT in this study, although it has been suggested that there may be differences of less than 0.2 eV between qVOC at 0 K and ECT at room temperature due to the temperature dependence of ECT35.
We also conducted highly sensitive EQE and electroluminescence (EL) measurements to evaluate the absorption and emission of CT states for all the systems (Supplementary Fig. 8). Fitting the edges of the EQE and EL spectra with Gaussian functions with common parameters gives ECT as the cross point of the two Gaussians and the reorganization energy, λ, as the width of the functions according to the formula based on Marcus electron transfer theory35. For four of the 16 PHJ systems, we observed well-resolved CT bands and obtained ECT values using the optical measurements with reasonable fittings. However, six systems had lower goodness of fit due to deformations in the peak shapes, and a further six systems had ECT bands that were poorly separated from the S1 bands and it was impossible to extract information about the CT states. The extracted values are summarized in Supplementary Table 1.
The ECT values determined by qVOC-T plots and EQE/EL measurements matched well for eight systems, with deviations below 15% (Supplementary Fig. 9 and Supplementary Table 1), whereas two PHJ systems with a low goodness of fit showed larger deviations (47 and 30% for BTA3/P3HT and PCBM/P3HT, respectively). The accuracy of the EQE/EL technique may be limited in PHJs because the small D/A interface area led to a smaller interfacial absorption/emission signal relative to that of the bulk, which reduced the reliability of the Gaussian fittings. Because of the lower reliability of ECT determined by EQE/EL measurements, we decided to focus on the ECT values from the qVOC-T plots. However, using the ECT values obtained by the EQE/EL measurements did not change our discussion and conclusions.
Evaluation of interfacial charge generation efficiency
In OSCs based on PHJs, the EQE at wavelength λ can be expressed as
where t is the layer thickness, ηabs(λ, z) is the light absorption efficiency at position z (with the origin at ITO/acceptor interface), ηED(z) is the efficiency for the excitons generated at position z to diffuse to the D/A interface, ηgen is the interfacial charge generation efficiency from the exciton, and ηcol is the charge collection efficiency (Fig. 3a). Note that the efficiencies can depend on whether the events happen at the donor or acceptor sides37, which is indicated by the superscripts D and A, respectively.
In PHJs, non-geminate recombination has a negligible effect under short-circuit conditions, as shown in the transient photocurrent measurements with variable light intensity (Supplementary Fig. 10 and Supplementary Note 1). Therefore, ηcol under short-circuit conditions can be assumed as unity. This assumption is not necessarily true for BHJs and can be characteristic of PHJs because the electrons and holes are spatially separated in the thin acceptor and the donor layers, respectively.
To evaluate ηabs(λ, z), we calculated light absorption profiles in the multilayered films by using the optical transfer matrix formalism following a reported procedure38,39. The optical constants of the eight materials and the other layers were evaluated separately by using a spectroscopic ellipsometer (see Methods and Supplementary Note 2 for details). By using these optical constants and the films thicknesses determined by X-ray reflectivity, the simulated reflectance spectra of the OSC devices with normal incident light reproduced the experimental spectra well for all the PHJ systems (Supplementary Fig. 11), which supports the validity of the optical models. These analyses give the full energy dissipation profiles, ηabs(λ, z), which indicate how much light at each wavelength is absorbed at each position in the multilayered films.
To reproduce the EQE spectra with ηgen as the unknown parameter, in principle, the diffusion equation can be solved numerically in PHJs to obtain ηED from the diffusion constants and the exciton lifetimes. However, accurate evaluation of these parameters is difficult due to many factors, such as the dimensionality of the diffusion process. Indeed, the reported diffusion constants and diffusion length vary greatly in the literature depending on the measurement method40. Therefore, we used a simple model assuming the exciton collection length (ECL) near the D/A interface for each material and that all the generated excitons reach the D/A interface (Fig. 3b). The ECLs of each material were determined to reproduce the observed EQE spectra best for the PHJ systems. Note that the lower limits of ECL were determined by the restriction that the maximum ηgen is 100% and we allowed practical variations of ECL (13 to 18 nm for PCBM and 7 to 12 nm for other materials) to estimate the possible error range of ηgen. The uncertainty of the ECL is shown as the error bars for calculated ηgen. The EQE spectra calculated with these ECLs and ηgen reproduced the experimental EQE spectra of most of the systems well (see Supplementary Note 3 and Supplementary Fig. 11).
Charge generation efficiency and state energy difference
The logarithms of ηgen were plotted against Egopt − ECS, which is the overall energetic driving force of charge generation (Fig. 4a). The filled and open symbols show the charge generation from the excitons generated at the donor (ηgenD) and the acceptor sides (ηgenA), respectively. The error bars indicate the variations of the assumed ECL. There was a weak trend with scattering in which a smaller driving force produced lower ηgen. Interestingly, when the logarithms of ηgen were plotted against Egopt − ECT, the trend was much clearer with a threshold behavior (Fig. 4b). A strong positive correlation of ηgen with Egopt − ECT was observed for systems where Egopt − ECT was smaller than 0.2 eV, whereas ηgen reached a maximum in systems with Egopt − ECT larger than 0.2 eV. Then ηgen decreased in systems with Egopt − ECT larger than 0.8 eV. This behavior is probably explained by the inverted region in Marcus charge transfer theory; the efficiency of the intermolecular charge transfer is at a maximum when the free energy difference between the initial and the final states is equal to the reorganization energy of the charge transfer event41. Similar behavior has been reported using time-resolved microwave conductivity42 and photoluminescence (PL) quenching43. The clear correlation between ηgen and Egopt − ECT suggests that the charge transfer process from the S1 to CT states can be described by Marcus theory and that this process has a large effect on the overall charge generation process of organic solar cells. When we used the ECT values determined by EQE/EL measurements, the trend in the dependence of ηgen on Egopt − ECT discussed above remained unchanged (Supplementary Fig. 12). We also checked the possible energy transfer between the donor and acceptor had little effect on the trend (See Supplementary Fig. 13 and Supplementary Note 4).
Note that the dispersion of ηgen are too large to extract any meaningful information from the theoretical fit of Marcus theory to Fig. 4b. The charge generation process is probably a more complicated process than a single Marcus type transition and other contributions such as triplet state formation44,45 should be considered for more detailed analysis. Also, the variations of the reorganization energy of each material46 causes the dispersion. Instead of a theoretical fit, we plotted a Gaussian derived from Marcus theory with a reorganization energy of 0.3 eV in Fig. 4b (gray line; see detail in Supplementary Note 5). The upper limit of the charge generation efficiency well follows the Gaussian line in the Marcus normal region, supporting the primary role of the Marcus theory for the charge generation process of OSCs.
The charge transfer from the CT to CS state is endothermic due to the Coulombic binding of the charge pairs; hence, ηgen was expected to increase as ECS − ECT decreased. However, no clear correlation was observed between ηgen and ECS − ECT (Fig. 4c). This indicates that the effect of the CT binding energy (ECS − ECT) is not apparent on the charge generation of OSCs. In addition, there were large differences in ηDgen and ηAgen for each PHJ (filled and open symbols, respectively, with same shapes and colors in Fig. 4). This observation also implies the small effect of the CT binding energy on the charge generation process because the CT binding energy is independent of the origin of the excitation. This result is consistent with the previous report that the transition from the CT to CS states in the PTB7:PCBM BHJ system was a nearly barrier-free, efficient process47. The exact mechanism of this efficient CT state splitting is still unclear. An explanation has been proposed based on a kinetic Monte Carlo simulation that the Coulombic binding of the CT states can be overcome by the relaxation of electrons (holes) in the disordered density of states of the acceptor (donor)48. It has also been proposed that the entropic gain plays a significant role in the CT states splitting into CS states49,50. Either way, we conclude that the energetic (enthalpic) driving force is important for the S1 to CT transition, whereas factors other than the energetics are more important for CT states splitting into CS states.
Electric field dependence of charge separation
Next, we investigated the electric field dependence of the charge generation. For quantitative discussion, we defined the degree of the electric field dependence as the ratio of the charge generation efficiency with an applied bias of 0 V (i.e., short circuit) to −1.0 V as
To evaluate ηgen at a bias of −1.0 V, we conducted EQE measurements at a −1.0 V bias and reproduced the spectra by using the simulated light absorptance in the same way as for ηgen under short-circuit conditions. Figure 5a, b show the electric field dependence plotted against Egopt − ECT and ECS − ECT, respectively. No clear trend was observed in the ECS − ECT plot. In contrast, the charge generation become less dependent on the electric field at Egopt − ECT of around 0.4 eV.
The FF of the PHJs also decreased with Egopt − ECT below about 0.3 eV (Supplementary Fig. 14), whereas a similar but weaker trend was observed in the relationship with ECS − ECT. The former observation may also suggest that Egopt − ECT has a large effect on the electric field dependence of the charge generation. However, both geminate and non-geminate recombination can affect the FF and their complete separation would be difficult under the OSC operating conditions.
Electric field dependence of emission from the S1 state
The clear correlations of ηgen, FF, and the electric field dependence of ηgen with Egopt − ECT suggest that the transition from the S1 to the CT states has a large effect on the overall charge generation process in OSCs. If the decay of the S1 to the ground state competing with transition of the S1 to CT state is the origin of the electric field dependence in the cells, the S1 emission may also show electric field dependence. To test this, we selected four PHJ cells with different electric field dependences of ηgen and measured the PL with an applied reverse bias. Figure 6a, b compare the PL of BTA3/J61 and PCBM/J61 PHJ devices, respectively, under applied biases of 0 V and −1.5 V. The PL of the PHJs and pristine films is shown in Supplementary Fig. 15. The PL of PCBM/J61 upon excitation of J61 at 540 nm was assigned to the emission from the S1 state of J61. In contrast, the PL of BTA3/J61 upon excitation of J61 at 500 nm was assigned to the emission from the S1 state of BTA3. This is attributed either to the energy transfer from J61 to BTA3 prior to the emission or to the regeneration of the excited state of BTA3 through the CT state. We could not distinguish these processes, but the possible contribution of the energy transfer does not affect the following discussion because the efficiency of the energy transfer would not be affected by the electric field.
In the PCBM/J61 PHJ, the PL intensity was almost unchanged under a reverse bias of −1.5 V. This is consistent with the observation that the electric field dependence of ηgenD was small (11%) in this system. The S1 state of J61 generated within the ECL was efficiently converted to the CT states regardless of the internal electric field. The S1 state generated outside of the ECL (far from the D/A interface) decayed to the ground state, and the emission was mainly detected as PL. In contrast, in BTA3/J61 the PL from the S1 state of BTA3 decreased substantially with an applied bias of −1.5 V. This is consistent with the relatively large field dependence of ηgenA (50%) in this system; the larger internal electric field generated by the applied bias promoted the CT state formation and decreased the population of the S1 state in BTA3, which decreased the PL signal intensity. We conducted the same experiments for BTA2/J61 (electric field dependences of ηgenA and ηgenD were 45% and 56%, respectively), PCBM/PTB7 (electric field dependence of ηgenD was 24%), and BTA2/P3HT (electric field dependence of ηgenD was 10%) and found that the electric field dependence of the S1 emission appeared in only the BTA2/J61 PHJ (Supplementary Fig. 16). Based on these results, we conclude that the origin of the electric field dependence of the charge generation observed for small Egopt − ECT is the competition between the decay from the S1 to the ground state and the transition from S1 to CT state. The Egopt − ECT less than 0.2 eV reduces the transition rate from the S1 to CT states51 and increases the rate from the CT to S1 states52. The electric field dependence of S1 state dissociation has been reported using a BHJ device with a low driving energy53,54, indicating that this observation is general, regardless of the device architecture.
Discussion
Here we discuss the efficient BHJ OSCs with small energy driving force. There are several reports of efficient BHJ solar cells with a small Egopt − ECT (less than 0.1 eV)10,11,12. For these efficient cells, the charge generation does not depend on the electric field and the FFs are larger than 0.6. In this study, however, we observed a stricter requirement, that Egopt − ECT larger than 0.2 to 0.3 eV is necessary for efficient electric field-independent charge generation. To explain this discrepancy, we hypothesize that Egopt − ECT of BHJ is underestimated. In the random mixture of the donor and acceptor material, the aggregation and crystallinity near the D/A interface differ from those of the bulk domain13,14,15 because of the interfacial disorder or molecular intermixing55,56. In this situation, Egopt at the interface becomes larger than that of the bulk due to the disorder, and ECT also increases due to a deeper EHOMOD in the disordered donor or a shallower ELUMOA in the disordered acceptor (Supplementary Fig. 17). However, the broadened optical gap in the disordered layer would be difficult to detect in the absorption spectra because its absorptance is small and the blue-shifted absorptance overlaps with the bulk absorptance. Hence, Egopt of the pristine materials or apparent Egopt is generally used for calculating Egopt − ECT of BHJs, which could cause the underestimation of the energy difference. Indeed, we showed previously that when a disordered polymer layer approximately 4 nm thick was intentionally placed between the donor and acceptor layers of a PHJ, the interfacial ECT value increased by approximately 0.25 eV without altering the Egopt of the bulk57. A similar situation may occur unintentionally at the D/A interfaces in mixed BHJs. The discrepancy in the criteria for PHJs and BHJs highlights the importance of controlling interfacial structures, which could change the design principles of the organic semiconducting materials beyond simple energy level matching.
Finally, we discuss the energy loss of Egopt − qVOC. Energy qVOC is equivalent to the splitting of the quasi-Fermi levels of holes and electrons under photoirradiation, which are related to the energy levels and the charge density at the steady state. Therefore, Egopt − qVOC includes both single-particle state energetics and the charge recombination kinetics. This kinetic loss can be described as the energy difference, ECT − qVOC. The total energy loss Egopt − qVOC is the sum of the energetics and kinetic losses58,
Figure 7a shows ECT − qVOC of the PHJ OSCs plotted against ECT. The loss of ECT − qVOC is distributed around 0.5 eV with no clear correlation with ECT. This suggests that the recombination kinetics depend weakly on the interfacial energetics. Benduhn et al. observed a slight decrease in this energy loss with increasing ECT in BHJs. They explained the dependence by using the energy gap law of non-radiative recombination59, in which the electron transfer rate increases as the energy difference between the initial and final states decreases. However, we did not see this trend in our data set: 16 data points may be not enough to see such a subtle difference. The minimum threshold of Egopt − ECT is 0.2 to 0.3 eV for the charge generation and ECT − qVOC is distributed around 0.5 eV, which accounts for the minimum Egopt − qVOC of 0.7 to 0.8 eV for the efficient OSCs. Indeed, ηgen decreased dramatically when the overall energy loss was below this threshold (Fig. 7b). This result is roughly consistent with the previously observed trend that the EQE of the BHJ OSCs drastically decreases when the Egopt − qVOC loss of the system is below 0.6 eV60.
However, there is a notable exception from the trend: the BTA3/P3HT system shows a significantly smaller ECT − qVOC of 0.31 eV compared with other systems (Fig. 7a, blue filled circles), whereas the other combinations containing either BTA3 or P3HT followed the general trend. This means that the recombination loss relates to the properties of the D/A interface, especially the transition probability from the CT state to the ground state, through many factors, such as the electronic coupling, the effective molecular distance, and the molecular orientations between the donor and acceptor molecules. In other words, a low recombination loss may not be achieved by fine tuning the properties of each material, such as the energetics, but by careful optimization of the interfacial structures in the specific D/A combinations.
In 16 organic PHJ systems, the charge generation efficiency and the electric field dependence of the charge generation clearly correlated with the energy offset, Egopt − ECT, but was not correlated with the binding energy of the CT state, ECS − ECT. The threshold energy required for the efficient charge generation was Egopt − ECT of 0.2 to 0.3 eV. Below the threshold, the S1 state decayed to the ground state, which started to limit the charge generation efficiency. The obvious inconsistency in the required energy between for PHJs in this study and for the some efficient BHJs (less than 0.1 eV) could be due to the difference in the interfacial structures; there could be key features in the interfacial structures of BHJs that universally reduce the apparent thresholds for the charge separation. Revealing these factors will lead to find the methodology for reducing the energy loss while maintaining efficient charge generation.
Methods
Materials
Regioregular poly(3-hexylthiophene-2,5-diyl) (P3HT, RMI-001EE, Mw: 36,000, Rieke Metals), poly({4,8-bis[(2-ethylhexyl)oxy]benzo[1,2-b:4,5-b′]dithiophene-2,6-diyl}{3-fluoro-2-[(2-ethylhexyl)carbonyl]thieno[3,4-b]thiophenediyl}) (PTB7, 1-Material), and [6,6]-phenyl C61 butyric acid methyl ester (PC61BM, purity: 99.5%, Solenne) were used as received. Poly[5,5′-bis(2-butyloctyl)-(2,2′-bithiophene)-4,4′-dicarboxylate-alt-5,5′-2,2′-bithiophene] (PDCBT, Mw: 128,000), J61, and the BTA series were synthesized following literature methods28,29,30.
Device fabrication
A glass substrate with a patterned ITO electrode was cleaned by sequential ultrasonication in detergent solution, water, 2-propanol, and acetone, followed by UV-O3 treatment. The ITO surface was spin-coated with a PEIE buffer layer approximately 10 nm thick. The acceptor material was spin-coated onto the PEIE layer. An aqueous solution of poly(sodium 4-styrenesulfonate) (PSS; 30 mg mL−1; Mw: 70,000; Sigma-Aldrich) was spin-coated onto a pre-cleaned glass substrate at 3000 rpm for 30 s. A donor polymer was spin-coated onto the glass/PSS substrates. Details of the spin-coating conditions and film thicknesses are summarized in Supplementary Table 2. The glass/PSS/polymer substrate was gently placed upside down on the substrate with the ITO/PEIE/acceptor, and one drop of water was placed on the edge of these two substrates. Water selectively penetrated and dissolved the PSS layer, allowing the polymer layer to be transferred onto the bottom acceptor film. Photographs of the film transfer process have been published previously34. A MoO3 hole-transporting layer (7.5 nm) and Ag electrodes (100 nm) were deposited by thermal evaporation through a metal mask under high vacuum (~10−4 Pa). All samples were encapsulated with a glass cap and UV-curable resin in a dry N2-filled glovebox
UPS and LEIPS measurements
ITO substrates were used for the UPS and LEIPS measurements. UPS was performed with a photoelectron spectroscopy system (PHI5000 VersaProbe II, ULVAC-PHI Inc.) with He I excitation (21.2 eV). For all UPS measurements, a −5.0 V bias was applied to the samples. Detail of the LEIPS setup has been described elsewhere61. The samples were irradiated with an electron beam in a vacuum chamber with pressure below 1 × 10−7 Pa. The kinetic energies of the incident electrons were 0–4 eV to avoid sample damage, and the electron current densities were between 10−6 and 10−5 A cm−2. The emitted photons were collected by a photon detector equipped with an optical band-pass filter and a photomultiplier tube. The LEIPS spectrum was obtained by scanning the electron kinetic energy. To minimize the uncertainty in the electron affinity, the spectra were taken at different center wavelengths of the band-pass filter of 260, 285, and 335 nm.
Current-voltage characteristics
The J-V characteristics of the devices were measured under simulated solar illumination (AM 1.5, 100 mW cm−2) from a solar simulator with a 150 W Xe lamp (PEC-L11, Peccell Technologies). The light intensity was calibrated with a standard silicon solar cell (BS520, Bunkoh-Keiki). The active area of each device was defined by using a 0.12 cm2 metal mask.
EQE measurements
The EQE of each device was measured with monochromatic light (SM-250F, Bunkoh-Keiki). The light intensity was calibrated with a standard Si and InGaAs photodetector. The photocurrent was recorded using a lock-in amplifier (LI5640, NF) with a low-noise current amplifier (DLPCA-200, FEMTO). The lock-in frequency was 85 Hz. For measurements with a reverse bias, the DC voltage output of the current amplifier was used.
X-ray reflectivity measurements
X-ray reflectivity was performed with an X-ray diffractometer (Smartlab, Rigaku), and the reflection patterns were fitted by using GlobalFit software (Rigaku). Monochromatized Cu Kα radiation (λ = 0.154 nm) was generated at 45 kV and 200 mA. Films were prepared on a Si/SiO2 substrate using the same spin-coating conditions as for the photovoltaic devices.
Light absorption measurements
The spectral absorptance of the donor and the acceptor films in transmittance mode were measured with a UV-Vis spectrophotometer (V-670, JASCO) from 400 to 900 nm. Reflectance mode with an integrating sphere was used to measure the reflectance and transmittance of the devices, and the device absorptance was calculated by subtracting the measured reflectance and transmittance from 1.
Light intensity and temperature dependence of J-V characteristics
Devices were placed in a stainless-steel chamber filled with dry N2 (Kitano Seiki). The light source was a 5 W warm white light-emitting diode (LED) (XP-G2, Cree) with a homemade condensing lens system. The LED output power was controlled so that irradiated devices exhibited nearly identical performance to that under AM1.5, 100 mW cm−2 solar light. Light intensity was altered by a combination of two neutral-density filters. The intensity was calibrated using a standard silicon photodiode. Temperatures at both the sample stage and the device surface were measured by thermocouples.
PL and EL measurements
PL and EL were measured by using a spectrofluorometer equipped with a photomultiplier for the visible region and a liquid N2-cooled InGaAs detector for the infrared region (Nanolog, Horiba). A bias voltage was applied to the devices and the current was recorded using a source measurement unit (2400, Keithley).
Ellipsometry measurements and transfer matrix optical simulations
Ellipsometry measurements were conducted on an ellipsometer (RC2-UI, J.A. Woollam) in the wavelength range of 210 to 1690 nm with incident angles of 45° to 75°. The thin films of the organic materials were prepared on a fused silica substrate by spin-coating. The transmittance of each film was measured at the same time and was used to determine the optical constants. The isotropic optical model was used for the PCBM thin film, whereas out-of-plane anisotropic models were used to analyze the data for the other organic materials. A gradient component model in the vertical direction was used for the ITO. Optical simulations of the bilayer OSC devices were performed based on the previously reported transfer matrix model38,39. The film thickness of each layer was measured by X-ray reflectivity. The electric field distributions and energy dissipations of monochromatic light were calculated for all the locations in each layer. The unit of the layer thickness and the wavelength were set to 1 nm. The simulations were performed by using lab-made code run on MATLAB.
TPC measurements
An LED bias light with neutral-density filters was used. Perturbation was performed with an N2-dye pulse laser (KEC-160, Usho) with an excitation wavelength, repetition rate, and pulse duration of 532 nm, 100 Hz, and 0.4 ns, respectively. Resistance (50 Ω) was put parallel to the input of a digital oscilloscope (DS-5632, Iwatsu), and the transient current was calculated using Ohm’s law. The integral of the transient current over time provided the amount of transient charge.
Data availability
The authors declare that the main data supporting the findings of this study are available within the article and its Supplementary Information files. Extra data are available from the corresponding author upon reasonable request.
Code availability
The MATLAB code and the optical constants for the optical simulations are provided as a Source Data file.
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Acknowledgements
We thank Mr. Takanobu Sato (J. A. Woollam Japan) for conducting the ellipsometry measurements. This research was supported in part by JSPS KAKENHI (JP18K14301), JST ALCA (JPMJAL1404) and the Futaba Research Grant Program of the Futaba Foundation.
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K.N. designed the experiments and measured the J-V characteristics, EQE, light intensity dependence, temperature dependence, TPC, UPS, light absorption, EL, and PL. Y.C. prepared all PHJ devices and pristine films and measured the X-ray reflectivity. H.Y. developed the LEIPS system and supervised the LEIPS experiments. W.H. performed the LEIPS measurements. J.H. synthesized PDCBT. E.Z. and B.X. synthesized BTAs. K.T. supervised the overall project. K.N. and K.T. prepared the manuscript. All the authors reviewed the final manuscript.
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Nakano, K., Chen, Y., Xiao, B. et al. Anatomy of the energetic driving force for charge generation in organic solar cells. Nat Commun 10, 2520 (2019). https://doi.org/10.1038/s41467-019-10434-3
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DOI: https://doi.org/10.1038/s41467-019-10434-3
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