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A Hygroscopic Janus Heterojunction for Continuous Moisture-Triggered Electricity Generators

Yanfei Wu, Beibei Shao, Zheheng Song, Yajuan Li, Yatao Zou, Xin Chen, Jiangtao Di, Tao Song, Yusheng Wang, Baoquan Sun

2022ACS Applied Materials & Interfaces64 citationsDOI

Abstract

Moisture-triggered electricity generator (MEG) harvesting energy from the ubiquity of atmospheric moisture is one of the promising potential candidates for renewable power demand. However, MEG device performance is strongly dependent on the moisture concentration, which results in its large fluctuation of the electrical output. Here, a Janus heterojunction MEG device consisting of nanostructured silicon and hygroscopic polyelectrolyte incorporating hydrophilic carbon nanotube mesh is proposed to enable ambient moisture harvesting and continuous stable electrical output delivery. The nanostructured silicon with a large surface/volume ratio provides strong coupling interaction with water molecules for charge generation. A polyelectrolyte of polydiallyl dimethylammonium chloride (PDDA) can facilitate charge selective transporting and enhance the effectiveness of moisture-absorbing in an arid environment simultaneously. The conductive, porous, and hydrophilic carbon nanotube mesh allows water to be ripped through as well as the generated charges being collected timely. As such, any generated charge carriers in the Janus heterojunction can be efficiently swept toward their respective electrodes, because of the device asymmetric contact. A MEG device continuously delivers an open-circuit voltage of 1.0 V, short-circuit current density of 8.2 μA/cm2, and output power density of 2.2 μW/cm2 under an ambient environment (60% relative humidity, 25 °C), which is a record value over the previously reported values. Furthermore, the infrared thermal measurements also reveal that the moisture-triggered electricity generation power is likely ascribed to surrounding thermal energy collected by the MEG device. Our results provide an insightful rationale for the design of device structure and understanding of the working mechanism of MEG, which is of great importance to promote the efficient electricity conversion induced by moisture in the atmosphere.

Topics & Concepts

Materials scienceJanusCarbon nanotubeMoistureOptoelectronicsNanotechnologyHeterojunctionPower densityComposite materialPower (physics)Quantum mechanicsPhysicsSolar-Powered Water Purification MethodsAdvanced Sensor and Energy Harvesting MaterialsThermal Radiation and Cooling Technologies
A Hygroscopic Janus Heterojunction for Continuous Moisture-Triggered Electricity Generators | Litcius