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Abstract
In pursuit of a sustainable future powered by renewable energy, hydrogen production through water splitting should achieve high energy efficiency with economical materials. Here, we present a nanofluidic electrolyzer that leverages overlapping cathode and anode electric double layers (EDLs) to drive the splitting of pure water. The strong electric field within the overlapping EDLs enhances ion migration and facilitates the dissociation of water molecules. Acidic and basic environments, that are created in situ at cathode and anode, respectively, enable the use of non-precious metal catalysts. All these merits allow the reactor to exhibit a current density of 2.8 A·cm-2 at 1.7 V with a nickel anode. This paves the way towards a new type of water electrolyzers without membranes, supporting electrolytes, or precious metal catalysts.
Supplementary materials
Title
Supplementary materials
Description
Materials and Methods
Supplementary Text
ST-1: Calibration of H2 detector
ST-2: Modeling of overlapping EDLs
ST-3: Formation of acid-base environment
ST-4: Target analysis for water electrolyzers
Table S1
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