Effects of Dispersion Forces on Structure and Photoinduced Charge

Aug 25, 2017 - We present a theoretical study on the role of van der Waals (vdW) interactions on the structure and, as a consequence, the photoinduced...
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Effects of Dispersion Forces on Structure and Photoinduced Charge Separation in Organic Photovoltaics Juan Pablo Martinez, Daniel Eduardo Trujillo-González, Andreas W. Götz, Fray de Landa Castillo-Alvarado, and Juan Ignacio Rodriguez Hernandez J. Phys. Chem. C, Just Accepted Manuscript • DOI: 10.1021/acs.jpcc.7b05107 • Publication Date (Web): 25 Aug 2017 Downloaded from http://pubs.acs.org on August 28, 2017

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Effects of Dispersion Forces on Structure and Photoinduced Charge Separation in Organic Photovoltaics Juan Pablo Martínez,∗,† Daniel Eduardo Trujillo-González,† Andreas W. Götz,∗,‡ Fray L. Castillo-Alvarado,† and Juan I. Rodríguez∗,† †Escuela Superior de Física y Matemáticas, Instituto Politécnico Nacional, Edificio 9, U.P. A.L.M., Col. San Pedro Zacatenco, C.P. 07738, Ciudad de México, México ‡San Diego Supercomputer Center, University of California San Diego, 9500 Gilman Drive, La Jolla, CA 92093-0505, USA E-mail: [email protected]; [email protected]; [email protected]

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Abstract We present a theoretical study on the role of van der Waals (vdW) interactions on the structure and, as a consequence, the photoinduced charge separation (CS) of a series of dimer complexes formed by the polymer P3HT and the fullerene derivative PCBM. CS rate constants for P3HT/PCBM dimer structures in which vdW interactions are taken into account agree well with experimental data. Without proper treatment of vdW interactions during geometry optimizations, the predicted CS rates can be too low by up to three orders of magnitude. These variations in computed CS rates are not due to changes in the Gibbs energy for CS. Instead, the electronic coupling increases by up to two orders of magnitude for structures obtained with dispersion-corrected density functionals that lead to deformations in the P3HT oligomer with pronounced π-π stacking interactions with PCBM.

Introduction The use of π-conjugated polymers as electron donors and fullerene derivatives as electron acceptors in bulk heterojunction (BHJ) organic photovoltaic devices (OPVs) represents an attractive alternative to silicon-based solar cells due to their potential low cost, flexibility, negligible toxicity, and short energy payback time. 1–7 Fullerene C60 and its derivatives perform well in OPVs due to their excellent electron acceptor capability, 8,9 and also their small internal reorganization energy. 10,11 Due to its high power conversion efficiency (PCE≈5%) 12,13 and internal quantum efficiency (≈0.8), 14 experimental studies based on transient absorption spectroscopy have been focused on the OPV blends made of poly(3-hexylthiophene) (P3HT) and [6,6]-phenyl-C61 -butyric acid methyl ester (PCBM), 15–17 reporting rate constants of charge separation (CS) kCS > 4 × 1012 s−1 . 18,19 Morphology of the BHJ active layer mainly at the donor-acceptor interface, the intermolecular distance (D) between donor and acceptor molecules, and exciton formation/dissociation/recombination are key factors that determine the CS process. 20–23 2

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Based on Marcus theory and its extensions, 24 density functional theory (DFT) based theoretical studies have been focused on the calculation of the CS and charge recombination (CR) rate constants of the P3HT/PCBM system, modeling P3HT with oligomers of several sizes. 22,25,26 The common-denominator conclusions of these studies are: 1) there is an uncertainty in the theoretically predicted structure at the P3HT/PCBM interface; 2) the rate constants (kCS and kCR ) can vary orders of magnitude depending on a particular structure of the P3HT/PCBM interface; 3) the theoretically computed values for kCS and kCR are usually 1 to 2 orders of magnitude below the experimental values. 25,26 Although there is strong experimental and theoretical evidence that van der Waals interactions (vdW) are indispensable to reach the so-called chemical accuracy in the structure and interaction energies of supramolecular systems formed by fullerenes and aromatic molecules, 27–31 surprisingly none of the DFT studies that reports CS and CR rates considered explicitly vdW interactions for the P3HT/PCBM interface. In this letter, the influence of vdW interactions on the electron transfer parameters that directly affect the photoinduced CS in the supramolecular dimer formed by an 8-unit oligomer of P3HT and PCBM are quantum chemically analyzed in detail for a series of five P3HT/PCBM dimers (see Figure 1).

Methodology and computational details The rate constant kCS was computed via Marcus theory for five P3HT/PCBM dimers (Figure 1), in two of which (I1 and I2) the P3HT adopts a U-shaped structure surrounding to PCBM due to vdW interactions as recently reported by us 32,33 (see Figure 1 (top) and discussion below). Isomer dimers I1 and I2 are local minima of the PES. Geometries were optimized in the gas phase at the DFT level using the Perdew-Burke-Ernzerhof (PBE) 34,35 exchange-correlation (xc) potential as implemented in the Amsterdam Density Functional (ADF2016) package. 36–38 The vdW interactions were taken into account via Grimme’s dis-

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persion correction scheme, termed DFT-D3, 39 in which the dispersion coefficient C6 for each pair of elements are obtained from ab-initio calculations using the Casimir-Polder formula considering the hydrates of each element, and the C8 coefficient is obtained recursively from C6 . All other parameters (cutoff radii, damping function parameter, etc.) are obtained empirically and only two of them are xc potential dependent (PBE-D3). 39 An all-electron uncontracted set of Slater-type orbitals (STOs) of triple-ζ quality (TZP) containing one set of polarization and diffuse functions was used to expand molecular orbitals for the geometry optimization procedure. Via time-dependent DFT (TDDFT) calculations, electron transfer parameters were determined in the gas phase at the PBE-D3/TZP optimized geometries for isomers I1 and I2. To better describe excitations with charge transfer (CT) character, the range-separated xc functional CAMY-B3LYP 40,41 was chosen to evaluate the energy terms involved in the photoinduced CS between P3HT and PCBM. 42 The frozen core approximation (FCA) was included to decrease computer demand, which freezes the core orbitals (1s for carbon and oxygen, and up to 2p for sulfur). 36 It is known that FCA usually has a negligible effect in the electronic transitions of interest since the main contributions come from frontier molecular orbitals (see below for our benchmark calculations on the adenine dimer electronic coupling). It has been reported that the P3HT alkyl side chains have a significant effect on the structure of isolated P3HT 43 and P3HT in the P3HT/PCBM dimer. 32,33 However, alkyl groups have hardly any effect on the optical properties and CS parameters. 26,44,45 Thus, in order to save computational resources, each hexyl group is replaced by a methyl group in the P3HT chain for the TDDFT calculations reported in this work. For dimers I3, I4 and I5, the CS parameters were computed via TDDFT single point calculations. It is worth mentioning that we tried to optimize I3 using the same xc potential PBE but without Grimme’s corrections to properly quantify how the lack of the vdW interactions affects the value of the charge separation rate constant kCS . However, these caculations did not lead to any binding between P3HT and PCBM. So we decided to consider these dimers (I3-I5) with ”idealistic” structures to have a reference point that is representative of approaches

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the electronic coupling, respectively; T is the temperature, kB and h ¯ are the Boltzmann and reduced Planck constants. The parameter λ is usually divided into two contributions: internal and external reorganization energies. The former, λint , is the energy required to rearrange all the nuclei of the system due to CS from a neutral to a charged state. 24 λint can be calculated by considering isolated donor and acceptor fragments as a separated contribution to the internal reorganization, which is a well known approximation, 46

λint = λD + λA

λD(A) =

 1 ′ ′ En − En + Eion − Eion , 2

(2)

(3)

where λD(A) is the reorganization energy of either the donor (D) or the acceptor (A). En(ion) is the energy of the neutral (ionic) state computed in the equilibrium geometry of the neutral (ionic) state; and En(ion) is the energy of the neutral (ionic) state computed in the ′

equilibrium geometry of the ionic (neutral) state. The ionic states are +1e− cation and -1e− anion states for the donor and acceptor fragments, respectively. The optimized geometries for both the neutral and ion for each fragment, donor (P3HT) and acceptor (PCBM), were obtained at the DFT level in order to apply Eq (3). The external reorganization energy corresponds to changes in the environment. However, since we are mainly interested in the influence of the structural conformation of the P3HT/PCBM dimer in the CS process, environmental effects are excluded from the current work. It should be noted that in some cases the environment can stabilize CT states such that the CS process enters the so called far inverted regime ( |∆G| ≫ λ) for which Marcus theory (Eq. (1)) can not be aplied. 47,48 Instead other more proper theories must be used. 49,50 Electron transfer coupling Vij was assessed using the orbital approximation within the energy splitting in dimer (ESID) method. 51–53 An all-electron DZP basis set was used to obtain Vij . As a benchmark calculation, the CS electronic coupling Vij was computed for the adenine dimer obtaining a value of 0.057 eV, which

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is in relatively good agreement with the reported value of 0.068 eV obtained via the fragment charge difference (FCD) method (the same value of 0.057 eV was obtained considering the FCA basis set approximation). It is worth mentioning that more accurate values are expected from a FCD approach since adiabatic states are computed using multi-configuration excited states as generated by TDDFT; therefore, it does not use orbital approximations to represent locally excited and CS states. 54,55 The good performance is attributed to the use of the range-separated CAMY-B3LYP/DZP, since ESID via PBE/DZP results in a Vij of 0.036 eV; that is, half of the expected value. The CS reaction under study is understood as follows:

P3HT/PCBM + hν −→ P3HT∗ /PCBM P3HT∗ /PCBM −→ P3HT+ /PCBM−

(4) (5)

wherein a molecular exciton localized at the P3HT fragment is initially formed by photon absorption (Equation 4), then the CS occurs after the dissociation of such a Frenkel exciton (Equation 5). Assuming a negligible entropic component, which may be valid under the Franck-Condon approximation, changes in electronic energy, ∆ECS , for CS reactions nearly correspond to ∆GCS . With the aim of assigning the excited states in Equations 4 and 5, the 30 lowest-in-energy electronic transitions were estimated under the Tamm-Dancoff approximation. 56

Results and discussion The five P3HT/PCBM dimer structures under study are schematized in Figure 1. For Isomer 1 (I1) and Isomer 2 (I2) (see Figure 1, top), vdW interactions were taken into account via the PBE-D3 scheme in a local geometry optimization procedure. As reported previously by us (see reference 32 for a detailed description of these isomers), when considering the vdW correction, the initially planar P3HT chain gets bent towards PCBM. In the final stable 7

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structures of I1 and I2, the P3HT chain is in a U-shaped conformation surrounding PCBM (the alkyl side chains get also bent towards PCBM). In isomers I1 and I2, the adjacent thiophene rings in the P3HT backbone chain show an alternate torsion (≈ 15 deg), which leads not only to a loss of planarity but also to a loss of the local translational symmetry that is related to the head-tail arrangement between neighboring thiophene rings. 32 The other three dimers considered in this letter were constructed by combining the optimized geometries of PCBM and planar P3HT, from I3 to I5. The intermolecular distance between PCBM and P3HT for the two U-shaped isomers and the planar dimer I3 is the typical π − π stacking distance (≈ 3.5 Å). We intentionally locate the planar P3HT at 4.5 and 5.5 Å from PCBM for dimers I4 and I5, respectively (see Figure 1, bottom). So, for P3HT/PCBM dimers I3 to I5, the vdW interactions were not taken into account. Table 1 shows the frontier orbital localization according to the fragments P3HT and PCBM for isomer I1. Interestingly, this distribution is nearly identical for all other dimers. 57 It can be observed that, in all dimers, molecular orbitals from HOMO-2 to HOMO are fully located at the P3HT fragment. Lower energy HOMOs are located at the PCBM moiety. Besides, frontier LUMOs are localized at the PCBM fragment; except for LUMO+4 (or LUMO+5 in the other dimers). In view of that, a low-in-energy electronic transition leading to the formation of an exciton fully situated at P3HT can take place from HOMO (or HOMO1, or HOMO-2) to LUMO+4. The resulting state can be represented as P3HT∗ /PCBM (see Equation 4). On the other hand, an electronic transition characterized by strong CS takes place from one of the frontier HOMOs located at P3HT to a LUMO located at PCBM, thus giving rise to a CS state represented as P3HT+ /PCBM− . Table 2 summarizes the ten lowest-energy electronic transitions in isomer I1. The formation of P3HT∗ /PCBM is given by the electronic transition with the highest oscillator strength value (f = 1.48), resulting in an excitation energy of 3.02 eV mainly originated from a HOMO-to-LUMO+4 transition; which also resembles the experimental maximum of 2.8 eV for pure P3HT films. 58 According to Tables 1 and 2, for isomer I1, there are two CS states,

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Table 1: Orbital localization according to fragments in isomer I1 of the P3HT/PCBM dimer. Orbital HOMO-6 HOMO-5 HOMO-4 HOMO-3 HOMO-2 HOMO-1 HOMO LUMO LUMO+1 LUMO+2 LUMO+3 LUMO+4 LUMO+5 LUMO+6

Fragment PCBM PCBM PCBM PCBM P3HT P3HT P3HT PCBM PCBM PCBM PCBM P3HT PCBM PCBM

P3HT+ /PCBM− . The first one (2.75 eV), CS1, is formed via the first electronic transition because of the main HOMO-to-LUMO contribution. The second one, CS2, is formed via the HOMO-to-LUMO+1 electronic transition characterized by an excitation energy of 2.93 eV and also a vanishing oscillator strength. Thus, there are two channels for the dissociation of the exciton P3HT∗ /PCBM into P3HT+ /PCBM− , via the photoinduced states CS1 and CS2 with a favorable driving force ∆GCS1 = −0.27 eV and ∆GCS2 = −0.09 eV, respectively. This second lowest-energy state CS2 has been reported previously for the P3HT/PCBM dimer and a set of other donor-acceptor pairs. 59 However, we found these two CS states with favorable driving force only for isomer I1. For isomer I2 and dimer I3 only one CS state with favorable driving force was found considering the ten lowest-energy electronic transitions. 57 For dimers I4 and I5 the Gibbs energy is positive. In Table 3, the transitions leading to the charge-localized exciton P3HT∗ /PCBM and P3HT+ /PCBM− are also reported. In the former, the reduced value of the oscillator strength in the U-shaped isomers I1 and I2 is due to a loss of symmetry resulting in a diminuition of the transition dipole moment of symmetry-allowed transitions. Hence the intensity of the main absorption peaks in these isomers is decreased as compared to the respective peaks 9

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Table 2: The ten lowest-energy electronic transitions for isomer I1. Excitation energies Eexc in eV, HOMO (H) to LUMO (L) orbital contribution along with its weight, and oscillator strength f . Contribution weights lower than 0.10 are ignored. Eexc 2.75 2.80 2.81 2.84 2.89 2.93 3.02 3.07 3.10 3.14

Transition H→L (0.34) H-3→L+1 (0.20) H-4→L (0.12) H-3→L (0.59) H→L (0.15) H-3→L+1 (0.39) H→L (0.18) H-3→L (0.16) H-5→L (0.49) H-4→L (0.31) H-4→L (0.31) H-5→L (0.28) H→L+1 (0.17) H→L+1 (0.46) H→L+2 (0.15) H→L+4 (0.34) H→L+5 (0.17) H-6→L+1 (0.45) H-4→L+1 (0.13) H→L+2 (0.13) H→L+2 (0.23) H-4→L+1 (0.22) H→L+1 (0.12) H-5→L+1 (0.32) H→L+2 (0.16) H-3→L+2 (0.14)

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f 0.05 0.03 0.03 0.00 0.04 0.01 1.48 0.18 0.10 0.02

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in the planar conformation. The intense peaks at 2.85 eV in the planar dimers I3 to I5 are in better agreement with the experimental peak of 2.8 eV of a pure P3HT film; as expected in view of the lack of distortions in the chain of P3HT. CS states are not accessed by light absorption (f = 0) but by the migration of an electron to a phase boundary through spatial translation upon dissociation of the state P3HT∗ /PCBM. The most favored driving force, ∆GCS1 = −0.27 eV, is calculated for isomer I1; even though I2 and I3 deviate by no more than 0.16 eV. Disfavored driving forces correspond to the dimers I4 and I5 which is attributed to the lack of interactions between frontier molecular orbitals; thus, CS states should not be modeled via isolated fragments and vdW interactions must be considered. Table 3 summarizes all the electron transfer parameters that influence kCS . Notice that the fastest CS reaction, which can be computed as the sum of the contribution of the two channels, 60 kCS−I1 = kCS1 + kCS2 = 5.97 × 1013 + 2.48 × 1013 = 8.46 × 1013 s−1 is calculated for the U-shaped isomer I1. This is up to two and three orders of magnitude higher than kCS in I2 (3.0 × 1011 s−1 ) and I3 (7.0 × 1010 s−1 ), respectively. The slow CS in dimers I4 and I5 is evidently due to their poor Vij and endergonic ∆GCS . Thus, there is an increase of kCS of 3 (1) orders of magnitude for isomers I1 (I2) with respect to I3 for which dispersion forces were not taken into consideration, although I3 does have a similar intermolecular distance (D = 3.5 Å). There is a difference of 6 orders of magnitude between the extreme cases, I1 and I5. Actually, notice that kCS−I1 = 8.46 × 1013 s−1 is the only value that reaches the experimental range (> 4 × 1012 s−1 ), 18,19 which is for the most stable isomer I1 for which vdW forces were taken into account. This underlines the necessity to work with realistic dimer structures, which are predicted when vdW forces are properly taken into account. In order to further analyze the cause of such high increase of kCS , let us focus on the main parameters that influence its value (λint , ∆GCS , and Vij ). For the internal reorganization energy λint (Equations 2-3 ) we obtained a value of 0.245 eV, which resembles the value of 0.27 eV obtained by spectroscopic studies 61 and the typical small value that characterizes systems involving fullerenes. 10,11,21 The variation of

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Table 3: Electronic couplings, Vij ; excitation energies, Eexc ; main HOMO (H) to LUMO (L) orbital contributions; oscillator strength values f ; and Gibbs energy for charge separation, ∆GCS , for each dimer under study. All energy terms in eV. The rate constant kCS is also provided in 1/s calculated with λint = 0.245 eV. Isomer I1

P3HT∗ /PCBM Eexc Transition f 0.0427 3.020 H→L+4 1.48

I2 I3 I4 I5

0.0031 0.0020 0.0004 0.0003

P3HT+ /PCBM− ∆GCS Eexc Transition f 2.745 H→L 0.05 -0.274 2.926 H→L+1 0.01 -0.094 3.062 H→L 0.00 -0.209 2.730 H→L+1 0.00 -0.116 2.858 H→L+1 0.00 0.008 2.977 H→L 0.00 0.126

Vij

3.271 2.846 2.850 2.852

H→L+5 H→L+5 H→L+5 H→L+5

0.75 3.00 3.13 3.17

kCS 5.97 × 1013 2.48 × 1013 3.02 × 1011 7.00 × 1010 3.68 × 108 1.30 × 107

λint over the five dimers was very small as expected due to the structural stability of C60 and its anion. For the P3HT chain, we found that the reorganization energy in the U-shaped and planar P3HT varies in the range of 0.159 to 0.163 eV, thus suggesting that λint remains constant through the five dimers, ∆λint = 4.1 meV. In view of that, considering a fixed value of λint = 0.245 eV for any dimer is a reasonable approximation, which in turn “eliminates” one independent variable for determining the variation of kCS . From Figure 2 (top), we can see an almost perfect linear correlation (R2 = 0.98) of ∆GCS for the five P3HT/PCBM dimers. Notice that this correlation is not just ∆GCS versus D, like previously reported, 21,62 since isomers I1, I2, and dimer I3 can be considered to approximately have the same average intermolecular distance (D ≈ 3.0 − 3.5 Å). What really makes the difference between these isomers (I1 and I2) is the drastic effect that vdW interactions produce on the dimer structures and, as a consequence, on the electronic and CS properties. Although there is a favorable driving force for I3 (∆GCS = −0.116 eV), which is not the case for the other two dimers with “idealistic” structures (I4 and I5), this driving force is increased by 100% (∆GCS−I1 = −0.274 eV, ∆GCS−I2 = −0.209 eV) for the isomers with ”realistic” structures (I1 and I2). In conclusion, there is not only an effect of the intermolecular distance on ∆GCS as previously remarked 62 but also an effect of the molecular orbital relaxation when the P3HT chain is bent in the equilibrium structures of isomers I1 and I2. An increase in the CS driving force directly results in a favorable change in kCS (see Equation 1). Our data show, 12

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however, that this favorable change is not the main factor that impacts the large increase in kCS . Changes in the electronic coupling have a significantly larger impact, while differences in ∆GCS result in an increase of kCS of less than one order of magnitude. The electronic coupling Vij = 0.002 eV (see Table 3) calculated for the planar dimer I3 is in qualitative agreement with the previously computed value of 0.013 eV; this latter was determined through a direct approach assuming that φLUMO in each fragment represents the nonadiabatic states, hφi |F |φj i, where F is the Kohn-Sham-Fock operator of the total system evaluated with the density matrix of the isolated fragments. 26 Increasing the distance between the fragments exponentially decreases the value of Vij , as described elsewhere 21 and confirmed by observing Vij from I3 to I5. However, Vij = 0.0427 eV for the U-shaped isomer I1 is one order of magnitude greater than Vij for I2 and two orders of magnitude greater than the one for dimers I3 to I5. After analyzing the quantities that determine Vij , 51–53,57 we found that this high increase in Vij is because the charge transfer matrix element for I1 is one order of magnitude greater than the one for I2 and I3, and two orders of magnitude greater than the one for I4 and I5. Even though I2 has a structure that includes effects of vdW interactions (see Figure 1, top), the electronic coupling is probably reduced in this isomer because of its local translational symmetry breaking related with the head-tail arrangement in the thiophene chain (isomer I1 does not show such a symmetry breaking). Notice that all the computed values of Vij (see Table 3) are sufficiently small so that the nonadiabatic approach, Equation 1, can be applied to assess kCS . Overall, there is an exponential increase of Vij with the five dimers. Notice again, like for ∆GCS , that this trend is not just Vij vs D because I1, I2, and I3 have on average a similar intermolecular distance D = 3.0 − 3.5 Å. Figure 2 (bottom) shows that there is a strong exponential correlation between ∆GCS and Vij (R2 = 0.84). This interesting correlation can be used for estimating Vij if the values of ∆GCS are known (or vice versa).

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0.20

∆GCS (eV)

0.10 0.00 −0.10 −0.20 −0.30 −0.40 1

2 3 4 5 P3HT/PCBM dimer isomer

10−1 Vij = 7 × 10−4 × e−11.34 ∆GCS Vij (eV)

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R2 = 0.8435

10−2

10−3

10−4 −0.3

−0.2

−0.1 0 ∆GCS (eV)

0.1

0.2

Figure 2: (top) Gibbs energy for photoinduced charge separation, ∆GCS , as a function of the dimer number as defined in 1. (bottom) Correlation between the electronic coupling for charge separation Vij (logarithmic scale) and ∆GCS . Trend lines and their corresponding equations are shown in the inset.

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Conclusions In this letter, the effects of the vdW interactions on the structure and, as a consequence, on the CS rate constant of the P3HT/PCBM dimer have been quantified. For the P3HT/PCBM isomers with realistic structures obtained by properly modeling the vdW interactions, I1 and I2, the CS reaction is predicted to be up to 3 (6) orders of magnitude faster than for P3HT/PCBM dimer structures with intermolecular distances of 3.5 Å (5.5 Å) in which vdW forces are not explicitly accounted for (I3 to I5). The fastest CS reaction is predicted for the vdW modified isomer I1, which is the only isomer whose CS rate constant value (kCS−I1 = 8.46 × 1013 s−1 ) falls into the experimentally measured range (kCS > 4 × 1012 s−1 ) for P3HT/PCBM active OPV layers. Small variations in the Gibbs energy for CS due to vdW effects, ∆GCS ≈ 0.2 eV, in the U-shaped as compared to the planar conformation do not have a significant impact on kCS , not affecting its order of magnitude. The electronic coupling Vij in isomers I1 and I2 increases by up to two and one orders of magnitude, respectively, with respect to the corresponding values for I3 to I5. This larger value of the electronic coupling is the main factor that leads to an increase of kCS by up to 3 and 6 orders of magnitude, respectively, with respect to the corresponding values of dimers I3 and I5. Therefore, we conclude that faster photoinduced CS is attained by states that are properly coupled electronically, which is the case here for the U-shaped isomers I1 and I2. These conclusions give quantitative evidence that vdW interactions should be taken into account for the proper quantum physical modeling of CS reactions, and thus computational predictions of the efficiency of BHJ organic solar cells.

Acknowledgement We acknowledge financial support from UC-MEXUS-CONACYT (Project 15-1462). The excellent service by the Dutch National Supercomputer (SURFsara Services), as well as the San Diego Supercomputer Center, is gratefully acknowledged. This work used the Ex15

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treme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation grant number ACI-1053575 (award TG-CHE130010 to AWG). JIR thanks support from SIP-IPN (project 20171617).

Supporting Information Available The following files are available free of charge. • SI1: Orbital localization. Excitation Energies. Electronic coupling integrals. This material is available free of charge via the Internet at http://pubs.acs.org/.

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