A microfluidic labyrinth self-assembled by a chemical garden

Chemical gardens, self-assembling precipitates that spontaneously form when a metal salt is added to a solution of another precipitating anion, are of interest for various applications including producing reactive materials in controlled structures. Here, we report on two chemical garden reaction systems (CuCl2 and Cu(NO3)2 seed crystals submerged in sodium silicate) that produced self-assembled microfluidic labyrinths in a vertical 2D Hele-Shaw reactor. The formation of labyrinths as well as the specific growth modes of the precipitate were dependent on the silicate concentration: CuCl2 labyrinths formed only at 3 and 4 M silicate and Cu(NO3)2 labyrinths formed only at 4 and 5 M silicate. The labyrinth structures contained silicate on the exterior and crystalline material interpreted as hydrated minerals from the metal salt in their interiors. The bubble-guided tubes that form labyrinths can be controlled by changing the angle of the 2D reaction cell; this suggests that future experiments of this type could form self-organizing structures with controlled composition and orientation for use in microfluidics and various materials science applications. A chemical-garden reaction in 2D self-assembles a controllable bubble-guided microfluidic labyrinth.

Automated summary

This study reports on the formation of self-assembled microfluidic labyrinths in a vertical 2D Hele-Shaw reactor using two chemical garden reaction systems. The formation of labyrinths and the growth modes of the precipitate were dependent on the concentration of sodium silicate. The results suggest potential applications in microfluidics and materials science.