Ion-selective graphene nanomesh membrane for sustainable osmotic power generation
Zhipeng Gao, Yuyan Gao, Zehua Yu, Chao Ma, Duo Chen, Kang Liu, Huanyu Cheng, Yanbing Yang, Quan Yuan

TL;DR
A new graphene-based membrane with tiny pores and carboxyl groups efficiently generates osmotic power, offering a sustainable way to harvest blue energy.
Contribution
The development of a scalable graphene nanomesh membrane with uniform pores and carboxyl groups for high-performance osmotic power generation.
Findings
The GNM–COO− membrane achieves a power density of 175.1 W m⁻² at a 50-fold salinity gradient.
The membrane exhibits diode-like ionic rectification and stable performance for 2 months.
The membrane selectively transports K⁺ while blocking Cl⁻, enabling efficient directional ion flow.
Abstract
Atomically thin 2D membranes with minimum ion transport pathways and low ion transport resistance are ideally suited for constructing ion-selective membranes for electric power generation, and have attracted considerable recent interest. However, the practical applications of such 2D membranes for electric power generation have been severely limited due to the lack of nanoporous 2D membranes with narrow distributed nanopore arrays and sufficient charge density. Here, we report a centimeter-scale ultrathin graphene nanomesh (GNM) membrane with narrow pore size distribution (∼1.5 nm) and rich in carboxylic groups (GNM–COO−) for efficient osmotic power generation. The high-density nanometer pores anchored by negatively charged carboxylic groups allow efficient transport of K+ while selectively blocking Cl−. We show that the GNM–COO− membrane with asymmetric charge structure exhibits a…
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Taxonomy
TopicsNanopore and Nanochannel Transport Studies · Membrane-based Ion Separation Techniques · Membrane Separation Technologies
