Joule
Volume 4, Issue 1, 15 January 2020, Pages 247-261
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Article
Bio-inspired Nanocomposite Membranes for Osmotic Energy Harvesting

https://doi.org/10.1016/j.joule.2019.11.010Get rights and content
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Highlights

  • Nanocomposite membranes are engineered with molecular precision by a self-assembly process

  • High robustness and fast ion transport originate from biomimetic nanoscale architecture

  • Inexpensive components and membrane longevity make “blue energy” generation realistic

Context & Scale

Osmotic energy is a renewable energy with zero emissions and minimal daily variations. However, the membranes for osmotic energy harvesting must have multiple properties that are thought to be impossible to realize to make this technology viable. Here, we show that cartilage-inspired cation-selective composite membrane assembled from aramid nanofibers and boron nitride nanosheets make it possible by a layer-by-layer assembly technology. The osmotic energy can be harvested by both salt concentration gradient and pressure-driven streaming because of the high mechanical and transport characteristics of the membranes. The combination of high strength, toughness, chemical resilience, rapid ion transport, and structural versatility of aramid-boron nitride composites makes it a promising candidate for osmotic energy harvesting under realistic operational conditions and life-cycle requirements.

Summary

Osmotic energy represents a widespread and reliable source of renewable energy with minimal daily variability. The key technological bottleneck for osmotic electricity is that membranes must combine highly efficient ion rectification and high ionic flux with long-term robustness in seawater. Here, we show that nanocomposite membranes with structural organization inspired by soft biological tissues with high mechanical and transport characteristics can address these problems. The layered membranes engineered with molecular-scale precision from aramid nanofibers and BN nanosheets simultaneously display high stiffness and tensile strength even when exposed to repeated pressure drops and salinity gradients. The total generated power density over large areas exceeded 0.6 W m−2 and was retained for as long as 20 cycles (200 h), demonstrating exceptional robustness. Furthermore, the membranes showed high performance in osmotic energy harvesting in unprecedentedly wide ranges of temperature (0°C–95°C) and pH (2.8–10.8) essential for the economic viability of osmotic energy generators.

Keywords

biomimetic nanocomposites
membrane
boron nitride
aramid
layer-by-layer assembly
osmotic energy harvesting
cartilage
dialysis

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