Xin Duan scite author profile

As one of the most promising hole transport layers (HTLs), nickel oxide (NiO x ) has received extensive attention due to its application in flexible largearea perovskite solar cells (PSCs). However, the poor interface contact caused by inherent easy-agglomeration phenomenon of NiO x nanoparticles (NPs) is still the bottleneck for achieving high-performance devices. Herein, a general strategy to synthesize NiO x NPs with high crystallinity and good dispersibility via the polymer network micro-precipitation method is reported. Promisingly, this approach realizes the flow-division of precipitant and the restraint of the NPs motion, thereby effectively alleviating the coagulation phenomenon caused by excessive local concentration and secondary movement adsorption. Furthermore, the addition of ionic liquid not only inhibits the secondary aggregation of NiO x NPs during the dispersion process, but also significantly enhances the properties of the colloidal solution. Ultimately, the 1.01 cm 2 PSCs based on the optimized NiO x HTLs achieve the champion power conversion efficiency of 20.91% and 19.17% on rigid and flexible substrates, respectively. Moreover, the reproducibility and stability of PSCs are also significantly improved, especially for flexible devices. Overall, this strategy provides the possibility for flexible, large-area fabrication of high-quality NiO x HTLs to promote the development of stable and efficient perovskite devices.

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A metamaterial electromagnetic energy rectifying surface with high harvesting efficiency

Duan

Chen

Zhou

2016

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A novel metamaterial rectifying surface (MRS) for electromagnetic energy capture and rectification with high harvesting efficiency is presented. It is fabricated on a three-layer printed circuit board, which comprises an array of periodic metamaterial particles in the shape of mirrored split rings, a metal ground, and integrated rectifiers employing Schottky diodes. Perfect impedance matching is engineered at two interfaces, i.e. one between free space and the surface, and the other between the metamaterial particles and the rectifiers, which are connected through optimally positioned vias. Therefore, the incident electromagnetic power is captured with almost no reflection by the metamaterial particles, then channeled maximally to the rectifiers, and finally converted to direct current efficiently. Moreover, the rectifiers are behind the metal ground, avoiding the disturbance of high power incident electromagnetic waves. Such a MRS working at 2.45 GHz is designed, manufactured and measured, achieving a harvesting efficiency up to 66.9% under an incident power density of 5 mW/cm2, compared with a simulated efficiency of 72.9%. This high harvesting efficiency makes the proposed MRS an effective receiving device in practical microwave power transmission applications.

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A Microwave Power Transmission Experiment Based on the Near-Field Focused Transmitter

Xing

Zhou

et al. 2019

Antennas Wirel. Propag. Lett.

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Wideband Metamaterial Electromagnetic Energy Harvester With High Capture Efficiency and Wide Incident Angle

Duan

Chen

Zhou

et al. 2018

Antennas Wirel. Propag. Lett.

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Xin Duan

Printable and Homogeneous NiO_x Hole Transport Layers Prepared by a Polymer‐Network Gel Method for Large‐Area and Flexible Perovskite Solar Cells

A metamaterial electromagnetic energy rectifying surface with high harvesting efficiency

A Microwave Power Transmission Experiment Based on the Near-Field Focused Transmitter

Wideband Metamaterial Electromagnetic Energy Harvester With High Capture Efficiency and Wide Incident Angle

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Xin Duan

Printable and Homogeneous NiOx Hole Transport Layers Prepared by a Polymer‐Network Gel Method for Large‐Area and Flexible Perovskite Solar Cells

A metamaterial electromagnetic energy rectifying surface with high harvesting efficiency

A Microwave Power Transmission Experiment Based on the Near-Field Focused Transmitter

Wideband Metamaterial Electromagnetic Energy Harvester With High Capture Efficiency and Wide Incident Angle

Contact Info

Product

Resources

About

Printable and Homogeneous NiO_x Hole Transport Layers Prepared by a Polymer‐Network Gel Method for Large‐Area and Flexible Perovskite Solar Cells