Issue 12, 2023

Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applications

Abstract

Fused-silica glass, as a desirable material with rigidity, biological inertness, and favorable light transmission for nanofluidic devices, should be assembled via low-temperature bonding technology to hermetically seal channels for stable liquid manipulation in extended-nano (101–103 nm) space. Confronted with the predicament of localized functionalization of nanofluidic applications (e.g. DNA microarray) with temperature-sensitive structures, the room-temperature direct bonding of glass chips to achieve modification of channels prior to bonding offers a considerably attractive solution to avoid component denaturation during the conventional post-bonding heating process. Therefore, we developed a nano-structure friendly and technically convenient room-temperature (RT, 25 °C) glass–glass direct bonding technology using polytetrafluoroethylene (PTFE)-assisted plasma modification without a requirement for special equipment. Unlike the establishment of chemical functionalities relying on immersion in potent but dangerous chemicals like HF, the fluorine radicals (F*) from PTFE pieces with superior chemical inertness were introduced on glass surfaces via O2 plasma sputtering and constructed fluorinated silicon oxides on the glass surfaces effectively, eliminating the significant etching effect of HF to protect fine nanostructures. Very strong bonding was obtained at RT with no heating and the high-pressure resistant glass–glass interfaces were evaluated under high-pressure-driven flow conditions up to 2 MPa based on a two-channel liquid introduction system. Moreover, the favorable optical transmittance of the fluorinated bonding interface demonstrated a capacity for high-resolution optical detection or liquid sensing.

Graphical abstract: Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applications

Supplementary files

Article information

Article type
Communication
Submitted
28 Feb 2023
Accepted
15 May 2023
First published
15 May 2023

Lab Chip, 2023,23, 2710-2719

Author version available

Room-temperature bonding of glass chips via PTFE-assisted plasma modification for nanofluidic applications

Q. Kang, C. Wang, K. Liu and T. Kitamori, Lab Chip, 2023, 23, 2710 DOI: 10.1039/D3LC00169E

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