Yaqi Hu scite author profile

InP-based quantum dot light-emitting diodes (QLEDs), as less toxic than Cd-free and Pb-free optoelectronic devices, have become the most promising benign alternatives for the next generation lighting and display. However, the development of green-emitting InP-based QLEDs still remains a great challenge to the environmental preparation of InP quantum dots (QDs) and superior device performance. Herein, we reported the highly efficient green-emitting InP-based QLEDs regulated by the inner alloyed shell components. Based on the environmental phosphorus tris(dimethylamino)phosphine ((DMA)3P), we obtained highly efficient InP-based QDs with the narrowest full width at half maximum (~35 nm) and highest quantum yield (~97%) by inserting the gradient inner shell layer ZnSexS1−x without further post-treatment. More importantly, we concretely discussed the effect and physical mechanism of ZnSexS1–x layer on the performance of QDs and QLEDs through the characterization of structure, luminescence, femtosecond transient absorption, and ultraviolet photoelectron spectroscopy. We demonstrated that the insert inner alloyed shell ZnSexS1−x provided bifunctionality, which diminished the interface defects upon balancing the lattice mismatch and tailored the energy levels of InP-based QDs which could promote the balanced carrier injection. The resulting QLEDs applying the InP/ZnSe0.7S0.3/ZnS QDs as an emitter layer exhibited a maximum external quantum efficiency of 15.2% with the electroluminescence peak of 532 nm, which was almost the highest record of InP-based pure green-emitting QLEDs. These results demonstrated the applicability and processability of inner shell component engineering in the preparation of high-quality InP-based QLEDs.

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Accumulation of heavy metals in soil-crop systems: a review for wheat and corn

Wang

Liu

et al. 2017

Environ Sci Pollut Res

149

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The health risks arising from heavy metal pollution (HMP) in agricultural soils have attracted global attention, and research on the accumulation of heavy metals in soil-plant systems is the basis for human health risk assessments. This review studied the accumulation of seven typical heavy metals-Cd, Cr, As, Pb, Hg, Cu, and Zn-in soil-corn and soil-wheat systems. The findings indicated that, in general, wheat was more likely to accumulate heavy metals than corn. Bioconcentration factor (BCF) of the seven heavy metals in wheat and corn grains decreased exponentially with their average concentrations in soil. The seven heavy metals were ranked as follows, in ascending order of accumulation in corn grains: Pb < Cr < Zn < As < Cu < Cd

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Parent-children relationship and internet addiction of adolescents: The mediating role of self-concept

Huang

et al. 2019

Curr Psychol

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Inorganic Solid Phosphorus Precursor of Sodium Phosphaethynolate for Synthesis of Highly Luminescent InP-Based Quantum Dots

Shan²,

Cao

et al. 2021

ACS Energy Lett.

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InP-based quantum dots (QDs) have become the most highlighted candidates to be a less-toxic surrogate for Cd- and Pb-based optoelectronic devices. However, the development of InP QDs still lags due to the expensive and flammable phosphorus precursors. Herein, we introduce sodium phosphaethynolate as an alternative, cheap and low-toxic phosphorus source for the synthesis of highly emitting InP-based QDs. The resulting QDs possess a size-tunable photoluminescence wavelength range between 465 and 620 nm and high emission quantum yield between 43 and 97%. The proof-of-concept QD light-emitting diodes applying the InP-based QDs as an emitter layer exhibit a maximum external quantum efficiency of 1.47%, 6.88%, and 13.62% for blue, green, and red devices, respectively. These results prove the applicability and processability of this new phosphorus in the preparation of high-quality InP-based QDs.

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Photoelectrochemical sensing for hydroquinone based on porphyrin-functionalized Au nanoparticles on graphene

Zhang

et al. 2013

Biosensors and Bioelectronics

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Yaqi Hu

Highly efficient green InP-based quantum dot light-emitting diodes regulated by inner alloyed shell component

Accumulation of heavy metals in soil-crop systems: a review for wheat and corn

Parent-children relationship and internet addiction of adolescents: The mediating role of self-concept

Inorganic Solid Phosphorus Precursor of Sodium Phosphaethynolate for Synthesis of Highly Luminescent InP-Based Quantum Dots

Photoelectrochemical sensing for hydroquinone based on porphyrin-functionalized Au nanoparticles on graphene

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