posted on 2023-03-24, 20:13authored byLeah K. Borden, Ankit Gargava, Uma J. Kokilepersaud, Srinivasa R. Raghavan
We demonstrate the use of electroadhesion
(EA), i.e., adhesion
induced by an electric field, to connect a variety of soft materials
into 3D structures. EA requires a cationic and an anionic material,
but these can be of diverse origin, including covalently cross-linked
hydrogels made by polymerizing charged monomers or physical gels/capsules
formed by the ionic cross-linking of biopolymers (e.g., alginate and
chitosan). Between each cationic/anionic pair, EA is induced rapidly
(in ∼10 s) by low voltages (∼10 V DC)and the
adhesion is permanent after the field is turned off. The adhesion
is strong enough to allow millimeter-scale capsules/gels to be assembled
in 3D into robust structures such as capsule–capsule chains,
capsule arrays on a base gel, and a 3D cube of capsules. EA-based
assembly of spherical building blocks can be done more precisely,
rapidly, and easily than by any alternative techniques. Moreover,
the adhesion can be reversed (by switching the polarity of the field)hence
any errors during assembly can be undone and fixed. EA can also be
used for selective sorting of charged soft matterfor example,
a ‘finger robot’ can selectively ‘pick up’
capsules of the opposite charge by EA and subsequently ‘drop
off’ these structures by reversing the polarity. Overall, our
work shows how electric fields can be used to connect soft matter
without the need for an adhesive or glue.