posted on 2023-06-07, 20:29authored byJeongmin Oh, Hanjou Park, Jooyoun Kim, Yaewon Park
Mushroom
chitin membranes with controllable pore structures were
fabricated through a simple process with naturally abundant Agaricus bisporus mushrooms. A freeze-thaw method
was applied to alter the pore structures of the membranes, which consist
of chitin fibril clusters within the glucan matrix. With tunable pore
size and distribution, mushroom chitin membranes could effectively
separate stable oil/water emulsions (dodecane, toluene, isooctane,
and chili oil) with various chemical properties and concentrations
and particle contaminants (carbon black and microfibers) from water.
Chitin fibrils tightly pack with each other to form a dense membrane,
leading to no permeation of contaminants or water. An increasing number
of applied freeze-thaw cycles confers more tortuous pore structures
throughout the mushroom chitin membranes, leading to higher flux while
maintaining rejection performance. The 3D simulation constructed by
the X-ray computed tomography and GeoDict software also demonstrated
capturing a considerable amount of contaminants within the membranes’
pores, which can be easily removed by water rinsing for further successive
filtration. Furthermore, mushroom chitin membranes were almost completely
biodegraded after approximately a month of being buried in the soil
or kept in a lysozyme solution while possessing mechanical durability
demonstrated by consistent filtration performance for repeated usage
up to 15 cycles under ambient and external pressure. This research
is a proof of concept that mushroom-derived chitin develops functional
and biodegradable materials for environmental applications with scalability.