Lianhui Li; Shouwei Gao; Mingming Hao; Xianqing Yang; Sijia Feng; Lili Li; Shuqi Wang; Zuoping Xiong; Fuqin Sun; Yue Li; Yuanyuan Bai; Yangyong Zhao; Zuankai Wang; Ting Zhang*;
Abstract:
Power generation from working environments involving a time-dependent variation in the ion concentration of
the aqueous solution is greatly preferred for many applications. Evaporation-induced hydrovoltaic effect has
been demonstrated to serve as a clean, renewable, and sustainable power source, however, such an electricity
generation approach is only limited to relatively low ion concentration of fluids. On the other hand, the primary
battery is capable of harvesting energy under high salinity conditions, but it becomes ineffective at the low ion
concentration. To circumvent the tradeoff, herein we report on the design of a flexible dual-mode electricity
nanogenerator (DM-ENG) that can harvest energy from a dynamically-changing aqueous solution. Distinct from
existing studies, our DM-ENG is constructed on a highly porous carbon black/PVA film bounded with negatively
charged groups, in which the top part is modified as hydrophobic and the bottom being hydrophilic. We show
that the generator maintains sustained performances in a wide range of ion concentrations over 10 orders of
magnitude. Moreover, the flexible generator exhibits excellent mechanical stability, and can be scaled-up, as
evidenced by the output of ~101.07 V by the integration of 100 power generators (seawater, 21 ◦C, 55% RH).
Full Paper: https://www.sciencedirect.com/science/article/pii/S2211285521002287