Wrinkle-Induced Hexagonal Boron Nitride Nanochannels for Biomolecule Localization and Imaging
Abstract
Fluorescence-based single-molecule localization, transport, and sensing require spatial confinement to extend the molecule's residence time during imaging, sufficient temporal resolution to capture fast dynamics, and efficient fluorescence background suppression. Two-dimensional (2D) materials offer large-area, atomically flat surfaces suitable for massively parallel in-plane biomolecule imaging, yet achieving guided motion in one-dimensional confinements using top-down nanofabrication remains challenging. Here, we demonstrate that thermally induced wrinkles in exfoliated hexagonal boron nitride (hBN) act as self-assembled nanochannels that enable biomolecule confinement and imaging under wide-field fluorescence microscopy. By controlling annealing parameters and substrate properties, we obtain scalable and reproducible wrinkle networks whose densities and morphologies can be tuned. Structural characterization using atomic force and scanning electron microscopy is complemented by fluorescence imaging and Kelvin probe force microscopy, confirming that aqueous solutions fill and remain stably retained within the nanochannels for periods exceeding 10 hours. We further achieve selective ATTO647N-DNA localization and imaging in the one-dimensional channels through the formation of a graphene/hBN vertical heterostructure. The graphene overlayer serves as a quenching mask that suppresses background fluorescence both from high-strain hBN regions and from DNA adsorbed on top of the 2D layer. Overall, these results provide a scalable, lithography-free route for creating planar nanofluidic confinements fully compatible with single-molecule imaging. This platform enables fundamental nanobiology studies as well as on-chip biomolecule transport and sensing applications.