Journal
ACS APPLIED ELECTRONIC MATERIALS
Volume 3, Issue 1, Pages 277-284Publisher
AMER CHEMICAL SOC
DOI: 10.1021/acsaelm.0c00849
Keywords
energy harvesting; pressure-responsive; vanadium pentoxide; agar gel; self-healing
Funding
- Ramanujan Research Grant of the Science and Engineering Research Board (SERB), India [SB/S2/RJN141/2014]
- DST Nano mission Research Grant of the Science and Engineering Research Board (SERB), India [DST/NM/NS/2018/141]
- IITG
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Metal-water batteries are gaining attention for their environmental compatibility, low cost, and high energy density. A pressure-responsive energy delivery system based on these principles has been developed, showing promising power density. By adjusting parameters such as layer dimensions, applied pressure, and ionic conductivity of the gel membrane, the output power of the devices can be further enhanced. Both gel and V2O5 membranes can be completely regenerated after damage, and the devices can be connected in series or parallel to increase voltage or current values.
Owing to their unique advantages like environmental compatibility, low cost, and high energy density, metal- water batteries are gaining a great deal of attention. The principles of metal-water batteries were applied here to develop a sustainable pressure-responsive energy delivery system. Application of a gentle pressure of 56 kPa on agar and a glycerol-based hydrogel membrane sandwiched between the aluminum foil and the nanofluidic V2O5 membrane (Al-gel-VO device) generates opencircuit voltage up to 1.3 V accompanied by an output current of 85 mu A (power density = 0.45 W m(-2)). The output power of Al-gel-VO can be further improved by tuning parameters like lateral dimensions of the layers, applied pressure, and ionic conductivity of the gel membrane. Remarkably, under ambient conditions, the hydrogel and V2O5-based devices can provide a constant potential difference up to five consecutive days. Unlike typical humidity-powered energy systems, the energy output of the current device is resistant to the diurnal variations in environmental conditions. Remarkably, both gel and V2O5 membranes can be completely regenerated after damage caused by prolonged use or accidents without any deterioration in the energy efficiencies. Moreover, the Al-gel-VO devices can also be connected in series (or parallel) to add up the voltage (or current) values of the individual devices.
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