Efficient solution-processed infrared photovoltaic cells: Planarized all-inorganic bulk heterojunction devices via inter-quantum-dot bridging during growth from solution

Klem, Ethan J. D.; MacNeil, D. D.; Cyr, Paul W.; Levina, Larissa; Sargent, Edward H.

doi:10.1063/1.2735674

Cited by 129 publications

(109 citation statements)

References 15 publications

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“…[14,16] The premise of this approach was to create a charge-separating (type-II) heterojunction to enable rapid dissociation of excitons into separated electrons and holes for independent transport to their respective contacts. [17,18] Recent work [13] has instead employed a single phase of light-absorbing material -a colloidal quantum dot solid -in which excitons are created, and charges travel within the same phase to their respective contacts. [19] A Schottky barrier [20] was formed at the interface between a low-work-function metal contact (Al) and the p-type quantum dot solid.…”

Section: Photovoltaicsmentioning

confidence: 99%

Solar Cells, Photodetectors, and Optical Sources from Infrared Colloidal Quantum Dots

2008

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Optoelectronic devices made via spin‐coating of soft materials onto an arbitrary substrate enable ready integration, low cost, and physical flexibility. The use of solution‐processed colloidal quantum dots offers the added advantage of quantum‐size‐effect tuning of material bandgap. Tuning across the near‐ and short‐wavelength infrared (SWIR) spectral regions enables applications in fiber‐optic communications, night vision and biomedical imaging, and efficient solar energy collection. Here we review progress in infrared solar cells, light sensors, and optical sources based on solution‐processed materials. The latest solution‐processed photovoltaics now provide 4.2% power conversion efficiencies in the infrared, placing them a factor of three away from enabling a doubling in overall solar power conversion efficiency of visible‐wavelength solution‐processed photovoltaics. The best solution‐processed photodetectors now provide sensitivities of 1013 Jones D* (normalized detectivity), exceeding the sensitivity of the best epitaxially grown SWIR photodetectors. Infrared optical sources, both broadband light‐emitting diodes and, more recently, lasers, have now also been reported at 1.5 µm.

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Section: Photovoltaicsmentioning

confidence: 99%

Solar Cells, Photodetectors, and Optical Sources from Infrared Colloidal Quantum Dots

2008

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“…This film contraction leads to film cracking-often on multiple length scales ranging from nanometers to micrometers-that renders the resultant film unacceptable for applications demanding exceptional uniformity. [1,7,8] Here, we demonstrate for the first time that useful levels of photoconductive gain and excellent morphology are not mutually exclusive. Solution-phase ligand exchange is the key to this achievement.…”

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confidence: 92%

Smooth‐Morphology Ultrasensitive Solution‐Processed Photodetectors

et al. 2008

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Solution-processed optoelectronic materials offer a route to low-cost photodetectors, large-area solar cells, and integrated optical sources. [1][2][3] While significant progress has been reported in organic and polymer spin-cast optoelectronics, colloidal quantum dots offer a distinct further advantage -the convenient tuning of absorption onset via the quantum size effect. [4] Electronic transport has recently been enhanced in sizeeffect-tuned colloidal quantum dot films using ligand exchange, resulting in ultrasensitive photodetectors in both visible and infrared wavelengths; however, solid-film ligand exchange generally results in rough film morphologies, incompatible with high-uniformity image sensors. [1,[5][6][7] The frequent cracking of films is attributed to the significant loss of volume during the exchange process. Here, we report a new route to visiblewavelength spin-cast PbS-nanocrystal photoconductive photodetectors with sub-1% roughness, compared to the $10% roughness obtained using previously reported approaches. The new procedure yields devices that exhibit 10 A W À1 responsivities and reveal an added significant advantage: when illumination conditions change, the photodetectors respond with a single time constant of 20 ms. This compares very favorably with the multisecond and multi-time-constant response of previously reported PbS-nanocrystal photoconductive photodetectors.To be relevant to imaging applications, a top-surface photodetector must exhibit three key traits: high sensitivity to the illumination of interest, spatial uniformity across an imaging array, and video-frame-rate speed of response. Sensitivity derives from the photoconductive gain-the number of electrical carriers collected per incident photon given at a specific light level-and the noise-equivalent power (NEP)-the lowest light level that can be distinguished from noise. Spatial uniformity better than 1% across a pixel array is sought to minimize the introduction of spatial noise, which produces an image photoresponse nonuniformity of the same order. Speed of response allowing video-capture frame rates demands sub-100 ms time constants.Large photoconductive gains, as high as thousands of electrons collected per incident photon, and large dark resistivities have recently been shown to enable record high sensitivity in PbS colloidal quantum dot photoconductive photodetectors.[7] These devices rely on enhanced chargecarrier mobilities, achieved by chemically displacing their original insulating oleate ligands with shorter ligands. The use of long aliphatic ligands in the synthesis and initial stages of processing prevent aggregation. However, films made from such materials are highly insulating. A procedure to exchange original ligands with shorter ones is needed to achieve sufficiently efficient carrier transport among the nanoparticles. Ligand removal, ligand replacement, and film crosslinking all produce the desired increase in mobility, critical to increased sensitivity; but are accompanied by a significant loss of film volum...

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“…More recently, the self-assembly of lead-salt nanocrystals into more complex nanowire (1D) (Cho et al, 2005;Jang et al, 2010;Koh et al, 2010), monolayer (2D) (Anikeeva et al, 2007(Anikeeva et al, , 2008Coe-Sullivan et al, 2003;Konstantatos et al, 2005;Steckel et al, 2003; and nanocrystalline films and superlattices structures (3D) (Hanrath et al, 2009;Klem et al, 2007Klem et al, , 2008Luther et al, 2008;Talapin et al, 2005) with a wide range of most promising optoelectronic properties has rapidly become a very active field of research, largely due to its facile solution-based processing. Recently, exciting reports such as the observation of superb multiple-exciton generation efficiencies (Sargent, 2009;Sukhovatkin et al, 2009), highly-efficient hot-electron injection (Tisdale et al, 2010), and cold-exciton recycling (Klar et al, 2009), have propelled nanocrystalline lead-chalcogenide film structures to the forefront of cutting-edge research (M. S. Kang et al, 2009;W.…”

Section: Directed Self-assembly Of Lead-salt Nanocrystalsmentioning

confidence: 99%

Hybrid Polyfluorene-Based Optoelectronic Devices

Cloutier¹

2012

Advanced Photonic Sciences

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Efficient solution-processed infrared photovoltaic cells: Planarized all-inorganic bulk heterojunction devices via inter-quantum-dot bridging during growth from solution

Cited by 129 publications

References 15 publications

Solar Cells, Photodetectors, and Optical Sources from Infrared Colloidal Quantum Dots

Solar Cells, Photodetectors, and Optical Sources from Infrared Colloidal Quantum Dots

Smooth‐Morphology Ultrasensitive Solution‐Processed Photodetectors

Hybrid Polyfluorene-Based Optoelectronic Devices

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