Ferroelectric Extended Nanofluidic Channels for Room-Temperature Microfuel Cells

Yuriy Pihosh, Yutaka Kazoe, Kazuma Mawatari, Hangyeol Seo, Osamu Tabata, Toshiyuki Tsuchiya, Kenji Kitamura, Masahiro Tosa, Ivan Turkevych, Takehiko Kitamori

Research output: Contribution to journalArticlepeer-review


Integration of fuel cells into microfluidic devices requires development of innovative proton conductors. Conventional Nafion membranes are incompatible with planar-type microfluidic devices and require a high operation temperature of over 100 °C to achieve rapid proton transfer. In contrast, glass nanochannels (NCs) work as proton conductors even at room temperature and can be seamlessly integrated into microfluidic devices, which in turn makes microfuel cells (µFCs) attractive for a wide range of practical applications, such as power sources for ultrasmall autonomous electronics and chemo- or biosensors. However, the conductivity of NCs is limited by their small cross-sectional area. It is revealed that spontaneous polarization of lithium niobite (LiNbO3) used as the NC material enhances a surface charge of a SiO2 layer formed on LiNbO3 and induces a fast proton transfer in water in the NCs. It is demonstrated that a µFC containing the LiNbO3 NCs demonstrates a proton diffusion coefficient that is 1.8 times higher than that of a reference device with bare glass NCs. In addition, such a µFC achieves a remarkable power output of up to ≈54 mW cm−2 at room temperature, which is 1.4 times higher than that of the similar device with bare glass NCs.

Original languageEnglish
Article number1900252
JournalAdvanced Materials Technologies
Issue number9
Publication statusPublished - 2019 Sept 1
Externally publishedYes


  • fused silica
  • microfuel cells
  • nanochannels
  • proton mobility
  • spontaneous polarization

ASJC Scopus subject areas

  • General Materials Science
  • Mechanics of Materials
  • Industrial and Manufacturing Engineering


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