Energy level tuned indium arsenide colloidal quantum dot films for efficient photovoltaics

Song, Jee-Hun; Choi, Hyekyoung; Pham, Hien Thu; Jeong, Sohee

doi:10.1038/s41467-018-06399-4

Cited by 73 publications

(126 citation statements)

References 42 publications

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“…In parallel with the core/shell heterostructuring, alternative chemical means that remove surface dangling bonds or oxidation layers have been explored (summarized in Table 2). 8,41,75,76 The rst attempt was performed by Olga I. Micic et al, 77 who observed strong band-edge emissions from InP QDs when exposed to dilute solutions of HF or NH 4 F. The uoride chemicals eliminate (passivate) the surface deep states of InP QDs, reected as the suppression of parasitic emission at lower energies with a long recombination lifetime (>500 ns). Later, D. V. Talapin et al unveiled the surface etching of InP QDs with HF caused by the migration of photoexcited charge carriers to the P dangling bonds (Fig.…”

Section: Etching Of Surface Defectsmentioning

confidence: 99%

“…4b and c). 8 Additionally, surface ligands can treat the traps for passivation aer the synthesis. However, surface passivation using surface ligands aer the synthesis is considered less effective in III-V nanocrystals when compared with II-VI or IV-VI nanocrystals because of the covalency in surface dangling bonds.…”

Section: Etching Of Surface Defectsmentioning

confidence: 99%

“…Colloidal quantum dots (QDs), whose photophysical properties vary depending upon their dimension, are considered to be the most promising candidates for a variety of applications including displays, 1,2 photovoltaics, [3][4][5][6][7][8][9] and biomarkers. [10][11][12] Since 10-70% of the total number of atoms reside at the exterior of nanometer sized QDs, the impact of the QD surface on its photophysical and electrical properties is substantial.…”

Section: Introductionmentioning

confidence: 99%

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III–V colloidal nanocrystals: control of covalent surfaces

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Section: Etching Of Surface Defectsmentioning

confidence: 99%

Section: Etching Of Surface Defectsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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III–V colloidal nanocrystals: control of covalent surfaces

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“…Colloidal quantum dots (QDs) have received remarkable research attention due to their excellent properties such as tuneable bandgaps, multiple exciton effects and excellent stability [1][2][3][4][5][6][7][8] . These unique features facilitate their wide applications in optoelectronic devices such as photodetectors, [9][10][11][12] light emitting diodes [13][14] and photovoltaics [15][16][17] .…”

Section: Introductionmentioning

confidence: 99%

Flexible and efficient perovskite quantum dot solar cells via hybrid interfacial architecture

Zhao

Huang

et al. 2020

Preprint

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All-inorganic CsPbI3 perovskite quantum dots (QDs) have received intense research interest for photovoltaic applications because of the recently demonstrated higher power conversion efficiency compared to solar cells using other QD materials. These QD devices also exhibit good mechanical stability amongst various thin-film photovoltaic technologies. In this work, through developing a hybrid interfacial architecture consisting of CsPbI3 QD/PCBM heterojunctions, we report the formation of an energy cascade for efficient charge transfer at both QD heterointerfaces and QD/electron transport layer interfaces. The champion CsPbI3 QD solar cell has a best power conversion efficiency of 15.1%, which is among the highest report to date. Building on this strategy, we demonstrate the very first perovskite QD flexible solar cell with a record efficiency of 12.3%. A detailed morphological characterization reveals that the perovskite QD film can better retain structure integrity than perovskite bulk thin-film under external mechanical stress. This work is the first to demonstrate higher mechanical endurance of QD film compared to bulk thin-film, and highlights the importance of further research on high‐performance and flexible optoelectronic devices using solution-processed QDs.

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“…DOI: 10.1002/smll.202002460 enable the derivation of new materials with a tailored bandgap for nontoxic solar cell. [6,7] Meanwhile, QDs are the most potent materials that can overcome the Shockley-Queisser (S-Q) limit, the p-n junction limit of conventional solar cells, with a single material. The thermal energy loss of photons in a solar cell is reduced by energy conversion management methods such as carrier multiplication, up-and down-conversions, and hot carriers.…”

mentioning

confidence: 99%

Design Strategy of Quantum Dot Thin‐Film Solar Cells

Kim

Lim

Yun

et al. 2020

Small

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Quantum dots (QDs) are emerging photovoltaic materials that display exclusive characteristics that can be adjusted through modification of their size and surface chemistry. However, designing a QD‐based optoelectronic device requires specialized approaches compared with designing conventional bulk‐based solar cells. In this paper, design considerations for QD thin‐film solar cells are introduced from two different viewpoints: optics and electrics. The confined energy level of QDs contributes to the adjustment of their band alignment, enabling their absorption characteristics to be adapted to a specific device purpose. However, the materials selected for this energy adjustment can increase the light loss induced by interface reflection. Thus, management of the light path is important for optical QD solar cell design, whereas surface modification is a crucial issue for the electrical design of QD solar cells. QD thin‐film solar cell architectures are fabricated as a heterojunction today, and ligand exchange provides suitable doping states and enhanced carrier transfer for the junction. Lastly, the stability issues and methods on QD thin‐film solar cells are surveyed. Through these strategies, a QD solar cell study can provide valuable insights for future‐oriented solar cell technology.

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Energy level tuned indium arsenide colloidal quantum dot films for efficient photovoltaics

Cited by 73 publications

References 42 publications

III–V colloidal nanocrystals: control of covalent surfaces

III–V colloidal nanocrystals: control of covalent surfaces

Flexible and efficient perovskite quantum dot solar cells via hybrid interfacial architecture

Design Strategy of Quantum Dot Thin‐Film Solar Cells

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