Charge-Transfer State Dynamics Following Hole and Electron Transfer in Organic Photovoltaic Devices

Bakulin, Artem A.; Dimitrov, Stoichko D.; Rao, Akshay; Chow, Philip C. Y.; Nielsen, Christian B.; Schroeder, Bob C.; McCulloch, Iain; Bakker, Huib J.; Durrant, James R.; Friend, Richard H.

doi:10.1021/jz301883y

Cited by 127 publications

(152 citation statements)

References 49 publications

(112 reference statements)

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“…67 This hot CT state theory was further supported by their subsequent work on other polymer:fullerene blends as well as polymer:perylene diimide blends ( Figure 6). [69][70][71][72][73][74] In addition to the above work, there are some other reports supporting the hot CT state theory. For example, the sub-bandgap CT excitation was reported to generate polarons which are more localized compared with those from the above-gap excitation, implying the importance of the excess thermal energy.…”

Section: Dissociation Via the Hot Ct Statesupporting

confidence: 64%

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Gao

Inganäs

2014

Phys. Chem. Chem. Phys.

203

250

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Charge generation in organic solar cells is a fundamental yet heavily debated issue. This article gives a balanced review of different mechanisms proposed to explain efficient charge generation in polymer-fullerene bulk-heterojunction solar cells. We discuss the effect of charge-transfer states, excess energy, external electric field, temperature, disorder of the materials, and delocalisation of the charge carriers on charge generation. Although a general consensus has not been reached yet, recent findings, based on both steady-state and transient measurements, have significantly advanced our understanding of this process.2

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Section: Dissociation Via the Hot Ct Statesupporting

confidence: 64%

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Gao

Inganäs

2014

Phys. Chem. Chem. Phys.

203

250

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“…This ability to generate dissociated charges (albeit with only a 70 % yield) in the absence of fullerene domains is most probably associated with the reasonably large energy offset ECS driving charge generation in this blend. 30,[63][64][65] However the absence of any phase structure to drive spatial separation of electrons and holes, and the absence of pure fullerene domains to facilitate rapid electron transport, these dissociated charges undergo relatively fast non-geminate recombination losses and a poor charge collection efficiency (except under strong reverse bias). The presence of aggregated fullerene domains suppresses the formation of bound charge pairs and the resultant geminate recombination losses.…”

Section: Discussionmentioning

confidence: 99%

Charge Separation in Intermixed Polymer:PC₇₀BM Photovoltaic Blends: Correlating Structural and Photophysical Length Scales as a Function of Blend Composition

et al. 2017

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A key challenge in achieving control over photocurrent generation by bulk-heterojunction organic solar cells is understanding how the morphology of the active layer impacts charge separation and in particular the separation dynamics within molecularly-intermixed donor-acceptor domains versus the dynamics between phase-segregated domains. This paper addresses this issue by studying blends and devices of the amorphous silicon-indacenodithiophene polymer SiIDT-DTBT and the acceptor PC70BM. By changing the blend composition, we modulate the size and density of the pure and intermixed domains on the nanometre lengthscale. Laser spectroscopic studies show that these changes in morphology correlate quantitatively with the changes in charge separation dynamics on the 2 nanosecond timescale, and with device photocurrent densities. At low fullerene compositions, where only a single, molecularly intermixed polymer-fullerene phase is observed, photoexcitation results in a ~30% charge loss from geminate polaron pair recombination, which is further studied via light intensity experiments showing that the radius of the polaron pairs in the intermixed phase is 3-5 nm. At high fullerene compositions (≥ 67%), where the intermixed domains are 1-3 nm and the pure fullerene phases reach ~4 nm, the geminate recombination is suppressed by the reduction of the intermixed phase making the fullerene domains accessible for electron escape.

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“…12 Free charges are therefore generated in quasi quantitative yield by both the ET and HT pathways, even if the driving force for HT and ET is different and populates the CT state with more or less excess energy. 11,12 This is evidence that charges formed in the PBDTTPD:PCBM blend (at domain interfaces or in the intermixed phase) are particularly well spatially separated, possibly thanks to the driving force provided by the pure regions, or to the delocalization in the polymer (see below).…”

Section: Part Ii: Charge Generation In Pbdttpd:pcbmmentioning

confidence: 96%

“…[8][9][10] Also, CS via hole transfer (HT) from photoexcited fullerene is not accounted for. [11][12][13][14][15][16][17][18] Moreover, the microstructure of the BHJ is much more complex in most polymer:fullerene blends. Amorphous and/or crystalline pure domains oen coexist with a phase where the polymer and fullerene are intimately mixed.…”

Section: Introductionmentioning

confidence: 99%

The influence of microstructure on charge separation dynamics in organic bulk heterojunction materials for solar cell applications

et al. 2014

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Light-induced charge formation is essential for the generation of photocurrent in organic solar cells. In order to gain a better understanding of this complex process, we have investigated the femtosecond dynamics of charge separation upon selective excitation of either the fullerene or the polymer in different bulk heterojunction blends with well-characterized microstructure. Blends of the pBTTT and PBDTTPD polymers with PCBM gave us access to three different scenarios: either a single intermixed phase, an intermixed phase with additional pure PCBM clusters, or a three-phase microstructure of pure polymer aggregates, pure fullerene clusters and intermixed regions. We found that ultrafast charge separation (by electron or hole transfer) occurs predominantly in intermixed regions, while charges are generated more slowly from excitons in pure domains that require diffusion to a charge generation site.The pure domains are helpful to prevent geminate charge recombination, but they must be sufficiently small not to become exciton traps. By varying the polymer packing, backbone planarity and chain length, we have shown that exciton diffusion out of small polymer aggregates in the highly efficient PBDTTPD:PCBM blend occurs within the same chain and is helped by delocalization.

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Charge-Transfer State Dynamics Following Hole and Electron Transfer in Organic Photovoltaic Devices

Cited by 127 publications

References 49 publications

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Charge Separation in Intermixed Polymer:PC₇₀BM Photovoltaic Blends: Correlating Structural and Photophysical Length Scales as a Function of Blend Composition

The influence of microstructure on charge separation dynamics in organic bulk heterojunction materials for solar cell applications

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Charge-Transfer State Dynamics Following Hole and Electron Transfer in Organic Photovoltaic Devices

Cited by 127 publications

References 49 publications

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Charge generation in polymer–fullerene bulk-heterojunction solar cells

Charge Separation in Intermixed Polymer:PC70BM Photovoltaic Blends: Correlating Structural and Photophysical Length Scales as a Function of Blend Composition

The influence of microstructure on charge separation dynamics in organic bulk heterojunction materials for solar cell applications

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Charge Separation in Intermixed Polymer:PC₇₀BM Photovoltaic Blends: Correlating Structural and Photophysical Length Scales as a Function of Blend Composition