Peak External Photocurrent Quantum Efficiency Exceeding 100% via MEG in a Quantum Dot Solar Cell

Semonin, Octavi E.; Luther, Joseph M.; Choi, Sukgeun; Chen, Hsiang‐Yu; Gao, Jianbo; Nozik, Arthur J.; Beard, Matthew C.

doi:10.1126/science.1209845

Cited by 1,534 publications

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References 37 publications

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“…O f the options for renewable energy, photovoltaic techno logies [1][2][3] with the potential to exceed the ShockleyQueisser limit 4 on single bandgap devices are particularly attractive [5][6][7][8] . One strategy is to sensitize a low bandgap semicon ductor with a higher bandgap material that can generate additional photocurrent from absorbed high energy photons 6,9 .…”

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“…One strategy is to sensitize a low bandgap semicon ductor with a higher bandgap material that can generate additional photocurrent from absorbed high energy photons 6,9 . Such an opportunity is offered by singlet fission, which is the spin conserving process by which a spin singlet exciton on an organic chromophore splits to form a pair of lower energy triplet excitons on neighbouring molecules 10 .…”

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“…Alivisatos and co workers used nanocrystals in photovoltaics dispersed in polymer matrices 32 , and subsequent studies have investigated bilayer struc tures 33 and hybrid organic/inorganic junctions 34 . There has also been steady progress in lead chalcogenide nanocrystal solar cells in a variety of device architectures [5][6][7]35,36 . In spite of this progress, there is a broad recognition of the need for innovations in materials.…”

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In situ measurement of exciton energy in hybrid singlet-fission solar cells

et al. 2012

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singlet exciton fission-sensitized solar cells have the potential to exceed the shockley-Queisser limit by generating additional photocurrent from high-energy photons. Pentacene is an organic semiconductor that undergoes efficient singlet fission-the conversion of singlet excitons into pairs of triplets. However, the pentacene triplet is non-emissive, and uncertainty regarding its energy has hindered device design. Here we present an in situ measurement of the pentacene triplet energy by fabricating a series of bilayer solar cells with infrared-absorbing nanocrystals of varying bandgaps. We show that the pentacene triplet energy is at least 0.85 eV and at most 1.00 eV in operating devices. our devices generate photocurrent from triplets, and achieve external quantum efficiencies up to 80%, and power conversion efficiencies of 4.7%. This establishes the general use of nanocrystal size series to measure the energy of non-emissive excited states, and suggests that fission-sensitized solar cells are a favourable candidate for third-generation photovoltaics.

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In situ measurement of exciton energy in hybrid singlet-fission solar cells

et al. 2012

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“…[1][2][3] These solids consist of macroscopic arrays of colloidally synthesized nanoparticles, wherein the band gap and the electronic properties of the composite array can be tuned by varying the size 4 and surface chemistry 5 of the constitutive elements, respectively. However, colloidally synthesized nanocrystals typically exhibit low impurity concentrations, 6 requiring post-synthetic treatments to effectively dope the nanocrystal solid.…”

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Controlled Chemical Doping of Semiconductor Nanocrystals Using Redox Buffers

2012

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Semiconductor nanocrystal solids are attractive materials for active layers in next-generation optoelectronic devices; however, their efficient implementation has been impeded by the lack of precise control over dopant concentrations. Herein we demonstrate a chemical strategy for the controlled doping of nanocrystal solids under equilibrium conditions. Exposing lead selenide nanocrystal thin films to solutions containing varying proportions of decamethylferrocene and decamethylferrocenium incrementally and reversibly increased the carrier concentration in the solid by 2 orders of magnitude from their native values. This application of redox buffers for controlled doping provides a new method for the precise control of the majority carrier concentration in porous semiconductor thin films.

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“…10). The MEG effect has been made responsible for the abnormally high efficiency of PbSe-sensitized TiO 2 photoelectrochemical cells [103] and PbSe photovoltaic cells [104].…”

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Nanoscale Effects in Water Splitting Photocatalysis

Osterloh

2015

Topics in Current Chemistry

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From a conceptual standpoint, the water photoelectrolysis reaction is the simplest way to convert solar energy into fuel. It is widely believed that nanostructured photocatalysts can improve the efficiency of the process and lower the costs. Indeed, nanostructured light absorbers have several advantages over traditional materials. This includes shorter charge transport pathways and larger redox active surface areas. It is also possible to adjust the energetics of small particles via the quantum size effect or with adsorbed ions. At the same time, nanostructured absorbers have significant disadvantages over conventional ones. The larger surface area promotes defect recombination and reduces the photovoltage that can be drawn from the absorber. The smaller size of the particles also makes electron-hole separation more difficult to achieve. This chapter discusses these issues using selected examples from the literature and from the laboratory of the author.

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Peak External Photocurrent Quantum Efficiency Exceeding 100% via MEG in a Quantum Dot Solar Cell

Cited by 1,534 publications

References 37 publications

In situ measurement of exciton energy in hybrid singlet-fission solar cells

In situ measurement of exciton energy in hybrid singlet-fission solar cells

Controlled Chemical Doping of Semiconductor Nanocrystals Using Redox Buffers

Nanoscale Effects in Water Splitting Photocatalysis

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