Understanding Charge Transfer in Carbon Nanotube–Fullerene Bulk Heterojunctions

Gong, Maogang; Shastry, Tejas A.; Cui, Qiannan; Kohlmeyer, Ryan R.; Luck, Kyle A.; Rowberg, Andrew J. E.; Marks, Tobin J.; Durstock, Michael F.; Zhao, Hui; Hersam, Mark C.; Ren, Shenqiang

doi:10.1021/acsami.5b01536

Cited by 23 publications

(42 citation statements)

References 55 publications

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“…The ideality factor was extracted from the slope of the dark current measurement (d d ( ) 1 V ln J − ) in the linear region of 0.28 to 0.38 V and 0.4 to 0.5 V, for the as-prepared and enriched (7 of 9) 1501345 wileyonlinelibrary.com (6,5) material, respectively. [ 38 ] Combining the increase in R SH and the signifi cantly smaller slope in the light-intensity-dependent V OC measurements indicates a marked reduction in trap-assisted recombination in solar cells made from the enriched (6,5) material, likely due to a reduction of the content of metallic SWCNTs. Having an ideality factor between 1 and 2 indicates recombination losses due to Shockley-Read-Hall (SRH) recombination, also called "trap charges," at or near the interface of the SWCNTs and C 60 .…”

Section: Resultsmentioning

confidence: 97%

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Performance Enhancement of Polymer‐Free Carbon Nanotube Solar Cells via Transfer Matrix Modeling

Pfohl

Glaser

Ludwig

et al. 2015

Advanced Energy Materials

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Polymer-free (6,5) single-walled carbon nanotubes (SWCNTs) prepared using the gel permeation approach are integrated into SWCNT:C 60 solar cells. Evaporation-driven self-assembly is used to form large-area SWCNT thin fi lms from the surfactant-stabilized aqueous suspensions. The thicknesses of various layers within the solar cell are optimized by theoretical modeling using transfer matrix calculations, where the distribution of the electric fi eld within the stack is matched to light absorption by the SWCNTs through either their primary (S 11 ) or secondary (S 22 ) absorption peaks, or a combination thereof. The validity of the model is verifi ed experimentally through a detailed parameter study and then used to develop SWCNT:C 60 solar cells with high open-circuit voltage (0.44 V) as well as a cutting-edge internal quantum effi ciency of up to 86% through the nanotube S 11 transition, over an active area of 0.105 cm 2 .

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Section: Resultsmentioning

confidence: 97%

“…The series resistance for the enriched (6,5) material is smaller but results only in a small increase in fi ll factor. [ 38 ] The increased slope for solar cells from as-prepared material is correlated with a reduction in V OC . [ 34 ] Reverse saturation current densities ( J 0 ) are on the same order for both materials.…”

Section: Resultsmentioning

confidence: 99%

Performance Enhancement of Polymer‐Free Carbon Nanotube Solar Cells via Transfer Matrix Modeling

Pfohl

Glaser

Ludwig

et al. 2015

Advanced Energy Materials

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“…The SWCNTs used in the devices presented in Figure 1 are purifi ed by density gradient ultracentrifugation (DGU). [ 9,[11][12][13]17 ] At these concentrations, SWCNTs act as the majority donor, and no signifi cant donor activity is observed for P3HT. [ 27 ] Figure 1 b shows the relative energy levels of the electrondonating SWCNTs and electron-accepting PC 71 BM.…”

Section: Enhancing Large-area Swcnt-fullerene Solar Cell Performance mentioning

confidence: 99%

“…[ 25,26 ] These SWCNTs have a diameter range of 0.8-1.2 nm, a broad chiral distribution enriched in the (8,7) chirality, and a semiconducting purity exceeding 97% as determined by optical absorbance spectroscopy. [ 17 ] Moreover, the high SWCNT:P3HT content allows the high stability and NIR absorption of SWCNTs to be realized in a thin-fi lm solar cell, [ 17 ] which further differentiates these active layers from the case where SWCNTs are only present in very low concentrations. Within the polychiral SWCNT distribution, smaller diameter (i.e., larger band gap) SWCNTs possess the desired type-II energy alignment for effi cient exciton separation, whereas larger diameter SWCNTs with narrower band gaps likely act as recombination sites.…”

Section: Enhancing Large-area Swcnt-fullerene Solar Cell Performance mentioning

confidence: 99%

“…[ 14,15 ] Despite these advances, SWCNT-fullerene solar cells have to date failed to demonstrate high performance over device areas larger than ≈1 mm 2 . [ 17 ] This recombination is in part due to the spatial inhomogeneities resulting from fullerene or SWCNT aggregates within the BHJ active layer. [ 15,16 ] Importantly, SWCNT-fullerene solar cells must maintain performance over areas on par with other TFPV technologies in order to exploit their exceptional absorption and chemical stability in hybrid or tandem photovoltaics, where an SWCNT-fullerene subcell would add value by harvesting NIR light and slowing degradation.…”

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confidence: 99%

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Enhanced Uniformity and Area Scaling in Carbon Nanotube–Fullerene Bulk‐Heterojunction Solar Cells Enabled by Solvent Additives

Shastry¹,

Clark²,

Rowberg³

et al. 2015

Advanced Energy Materials

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blends have recently demonstrated power conversion effi ciencies (PCEs) as high as 3.1% (2.5% NREL certifi ed) for device areas of 0.06-1.2 mm 2 . [7][8][9][10][11][12][13] These devices show excellent ambient stability and nearinfrared (NIR) absorption, [ 11 ] in contrast to other widely researched organic and perovskite photovoltaic technologies. [ 14,15 ] Despite these advances, SWCNT-fullerene solar cells have to date failed to demonstrate high performance over device areas larger than ≈1 mm 2 . In contrast, other TFPV technologies are routinely demonstrated at areas of 6 mm 2 and above. [ 15,16 ] Importantly, SWCNT-fullerene solar cells must maintain performance over areas on par with other TFPV technologies in order to exploit their exceptional absorption and chemical stability in hybrid or tandem photovoltaics, where an SWCNT-fullerene subcell would add value by harvesting NIR light and slowing degradation. Recently, it has been shown that trap-assisted recombination within the active layer limits performance in SWCNT-fullerene solar cells. [ 17 ] This recombination is in part due to the spatial inhomogeneities resulting from fullerene or SWCNT aggregates within the BHJ active layer. Such aggregates decrease the interfacial area between the donor and acceptor domains, limiting effi cient exciton dissociation and charge extraction. These aggregates also provide conductive pathways between both electrodes that electrically short the cell and limit both shortcircuit current density ( J sc ) and open-circuit voltage ( V oc ). [ 18 ] As the solar cell areas are increased, these negative effects begin to dominate the overall device performance, oftentimes with catastrophic consequences.Here, we report improved BHJ morphology and the resulting large-area device performance by incorporating the solvent additive 1,8-diiodooctane (DIO) within the SWCNT-fullerene active layer. DIO has previously been used as an additive in polymer solar cells and is known to break apart PC 71 BM aggregates, [ 16,19 ] which can have tremendous impact on solar cell performance. [ 20 ] We systematically vary the DIO concentration in the SWCNT-fullerene blend, fi nding that an optimal concentration of 1 vol% DIO enables large-area device performance that is comparable to smaller area devices. Atomic force microscopy (AFM) reveals that the addition of DIO signifi cantly reduces the Single-walled carbon nanotube (SWCNT) fullerene solar cells have recently attracted attention due to their low-cost processing, high environmental stability, and near-infrared absorption. While SWCNT-fullerene bulk-heterojunction photovoltaics employing an inverted architecture and polychiral SWCNTs have achieved effi ciencies exceeding 3% over device areas of ≈1 mm 2 , large-area SWCNT solar cells have not yet been demonstrated. In particular, with increasing device area, spatial inhomogeneities in the SWCNT fi lm have limited overall device performance. Here, 1,8-diiodooctane (DIO) is utilized as a solvent additive to reduce fullerene domain size and to impro...

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Recent Advances in Applications of Sorted Single‐Walled Carbon Nanotubes

Bati

Batmunkh

et al. 2019

Adv Funct Materials

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Single-walled carbon nanotubes (SWCNTs) exhibit outstanding properties that make them appealing in a wide range of applications. However, their properties are variable depending on the tube helicity (chirality), which has been a challenge for a long time and needs to be effectively controlled. In recent years, tremendous efforts have been made to control the electrical type/chirality of nanotubes through both direct controlled synthesis and postsynthesis separation methods. Driven by these breakthroughs, the applications of separated families of SWCNTs in various fields have emerged as a new topic of research. In this Review, an overview of recent advances in the use of highly purified and well-separated SWCNTs in a comprehensive range of applications is presented including photovoltaics, transistors, batteries, sensors, light emitters, biological/medical fields, and others. Finally, important future directions for the utilization of separated SWCNTs in these fields are provided.

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Understanding Charge Transfer in Carbon Nanotube–Fullerene Bulk Heterojunctions

Cited by 23 publications

References 55 publications

Performance Enhancement of Polymer‐Free Carbon Nanotube Solar Cells via Transfer Matrix Modeling

Performance Enhancement of Polymer‐Free Carbon Nanotube Solar Cells via Transfer Matrix Modeling

Enhanced Uniformity and Area Scaling in Carbon Nanotube–Fullerene Bulk‐Heterojunction Solar Cells Enabled by Solvent Additives

Recent Advances in Applications of Sorted Single‐Walled Carbon Nanotubes

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