Your search keyword '"Xiao, Zhuojian"' showing total 2 results

1. Novel approach to enhance efficiency of hybrid silicon-based solar cells via synergistic effects of polymer and carbon nanotube composite film.

Author

Fan, Qingxia, Zhang, Qiang, Zhou, Wenbin, Xia, Xiaogang, Yang, Feng, Zhang, Nan, Xiao, Shiqi, Li, Kewei, Gu, Xiaogang, Xiao, Zhuojian, Chen, Huiliang, Wang, Yanchun, Liu, Huaping, Zhou, Weiya, and Xie, Sishen

Abstract

In this work, we put forward an effective approach by combining both highly transparent and conductive carbon nanotube (CNT) network and poly (3, 4-ethylene dioxythiophene):poly (styrenesulfonate) (PEDOT:PSS) film to co-form-coordinate heterojunctions with silicon, and have developed a hybrid PEDOT:PSS-CNT/n-Si solar cell. The power conversion efficiency (PCE) of the as-designed solar cell can be improved up to 10.2%, which is much higher than the PCE values of both PEDOT:PSS/n-Si (5.5%) and CNT/n-Si (6.1%) solar cells fabricated using the same materials and process. PEDOT:PSS can fill the hundreds nanometer scale pores of the CNT network, both CNT network and PEDOT:PSS patches contact with the silicon concomitantly and form p Synergy -n heterojunctions through seamless contact with n-Si. The PEDOT:PSS-CNT composite film exhibits a much lower sheet resistance and remains high optical transmittance. Once the photo-generated holes are extracted to the PEDOT:PSS-CNT composite film, CNT network can serve as a carrier transport bridge, which is different from the design that inserts an ultrathin polymer between the CNT and Si. Incorporation of the continuous CNT network with PEDOT:PSS jointly in the as-designed simple and explicit structure has generated synergistic effects, which can make full use of the respective merits and then considerably enhance the PCE of hybrid PEDOT:PSS-CNT/n-Si solar cells. [ABSTRACT FROM AUTHOR]

Published

2017

2. An integrated configuration with robust interfacial contact for durable and flexible zinc ion batteries.

Author

Chen, Penghui, Zhou, Weiya, Xiao, Zhuojian, Li, Shaoqing, Wang, Zibo, Wang, Yanchun, and Xie, Sishen

Abstract

The flexible zinc ion battery (ZIB) is deemed to be a promising candidate for flexible power supply due to its high security and low cost. However, conventional segregated battery configuration inevitably suffers from the relative displacement or detachment between two neighboring components at bending strain, which seriously degrade the performance of a flexible battery. Moreover, stubborn Zn dendrite drastically shortens the cycle life. Herein, by integrating Zn anode, zinc protective coating, polyamide separator and cathode into a single matrix, referred as the integrated electrode, a long cycle life and robust flexibility for ZIB in aqueous electrolyte are achieved. Seamless connection with the adjacent layers not only avoids the relative displacement or detachment caused by bending strain, but enhances the interfacial contact to promote the electrochemical kinetics. The built-in protective coating in the integrated configuration significantly inhibits the dendrites and side reactions for extending the durability. Furthermore, the integrated configuration makes the whole battery lighter, thinner and more powerful. Therefore, this work provides a new design idea for engineering innovative battery configuration and enables high performances for a flexible ZIB. Meanwhile, the research results would deliver great potential applications in flexible electronics and boost the development of configuration of energy storage devices. An ingenious configuration with robust interfacial contact is developed via the integration of Zn anode, zinc protective coating, polyamide separator and cathode into a single matrix, enabling the high flexibility and the dendrite-free boosted durability for zinc ion batteries. Image 1 • A flexible and durable zinc ion battery with integrated configuration is developed by manageable and scaleable process. • Continuous seamless connection prevents the displacement or detachment and ensures the steady electron transfer. • The built-in Zn anode protective coating inhibits dendrite growth and tightly glues the anode and polyamide separator. • The integrated configuration delivers significantly prolonged lifespan, reduced overpotential and boosted flexibility. [ABSTRACT FROM AUTHOR]

Published

2020