Voltage gated inter-cation selective ion channels from graphene nanopores

Lauren Cantley, Jacob L. Swett, David Lloyd, David A. Cullen, Ke Zhou, Peter V. Bedworth, Scott Heise, Adam J. Rondinone, Zhiping Xu, Steve Sinton, J. Scott Bunch

Research output: Contribution to journalArticlepeer-review

43 Scopus citations

Abstract

With the ability to selectively control ionic flux, biological protein ion channels perform a fundamental role in many physiological processes. For practical applications that require the functionality of a biological ion channel, graphene provides a promising solid-state alternative, due to its atomic thinness and mechanical strength. Here, we demonstrate that nanopores introduced into graphene membranes, as large as 50 nm in diameter, exhibit inter-cation selectivity with a ∼20× preference for K+ over divalent cations and can be modulated by an applied gate voltage. Liquid atomic force microscopy of the graphene devices reveals surface nanobubbles near the pore to be responsible for the observed selective behavior. Molecular dynamics simulations indicate that translocation of ions across the pore likely occurs via a thin water layer at the edge of the pore and the nanobubble. Our results demonstrate a significant improvement in the inter-cation selectivity displayed by a solid-state nanopore device and by utilizing the pores in a de-wetted state, offers an approach to fabricate selective graphene membranes that does not rely on the fabrication of sub-nm pores.

Original languageEnglish
Pages (from-to)9856-9861
Number of pages6
JournalNanoscale
Volume11
Issue number20
DOIs
StatePublished - May 28 2019

Funding

The authors acknowledge K. Ekinci for the use of the optical table, C. Duan for lab use and useful discussions. This work was funded by the National Science Foundation (NSF), grant no. 1054406 (CMMI: CAREER, Atomic Scale Defect Engineering in Graphene Membranes), grant no. 1706322 (CBET: Bioengineering of Channelrhodopsins for Neurophotonic and Nanophotonic Applications) and by the NSF Graduate Research Fellowship Program under grant no. DGE-1247312. HIM perforation and aberration-corrected STEM imaging were conducted at Oak Ridge National Laboratory’s Center for Nanophase Materials Sciences (CNMS), a U.S. Department of Energy Office of Science User Facility.

FundersFunder number
National Science Foundation1054406, DGE-1247312, 1706322

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