Stick–slip motion and controlled filling speed by the geometric design of soft micro-channels
Artikel i vetenskaplig tidskrift, 2018

Hypothesis

Liquid can move by capillary action through interconnected porous materials, as in fabric or paper towels. Today mass transport is controlled by chemical modification. It is, however, possible to direct mass transport by geometrical modifications. It is here proposed that it is possible to tailor capillary flow speed in a model system of micro-channels by the angle, size and position of attached side channels.

Experiments

A flexible, rapid, and cost-effective method is used to produce micro-channels in gels. It involves 3D-printed moulds in which gels are cast. Open channels of micrometre size with several side channels on either one or two sides are produced with tilting angles of 10 – 170°. On a horizontal plane the meniscus of water driven by surface tension is tracked in the main channel.

Findings

The presence of side channels on one side slowed down the speed of the meniscus in the main channel least. Channels having side channels on both sides with tilting angles of up to 30° indicated tremendously slower flow, and the liquid exhibited a stick-slip motion. Broader side channels decreased the speed more than thinner ones, as suggested by the hypothesis. Inertial forces are suggested to be important in branched channel systems studied here.

Foam structures

Lucas–Washburn equation

pinning meniscus

capillary action

Författare

Johanna Andersson

Anette Larsson Group

Anette Larsson

Anette Larsson Group

Anna Ström

Chalmers, Kemi och kemiteknik, Tillämpad kemi

Journal of Colloid and Interface Science

0021-9797 (ISSN)

Vol. 524 139-147

Ämneskategorier

Materialteknik

Fysikalisk kemi

Biomaterial

Kemiteknik

Materialkemi

Bioenergi

Biomaterialvetenskap

Styrkeområden

Materialvetenskap

DOI

10.1016/j.jcis.2018.03.070