Abstract: A method of making an erasable nanocellulose electronic structure comprising the steps of providing a nanocellulose sheet, adhering metal contacts onto the nanocellulose sheet, applying solder to the metal contacts, and attaching surface mount devices to the contacts. An erasable nanocellulose electronic structure comprising a nanocellulose sheet, a metal contact on the nanocellulose sheet, a layer of solder on the metal contact, and a surface mount device to the contact.

Abstract: Described herein are ultra-thin nanocellulose flexible electronic device on which SU-8, an epoxy material which can become highly stressed upon UV exposure, is printed on desired areas. Upon UV exposure and then release from the surface it is anchored on, the nanocellulose device will spontaneously self-mold into a desired form due to stress differences between the SU-8 and the nanocellulose sheet. The flexible electronics can be manufactured using standard printed circuit board processing techniques, including electroless metallization and soldering of surface mount components.

Abstract: Described herein are ultra-thin nanocellulose flexible electronic device on which SU-8, an epoxy material which can become highly stressed upon UV exposure, is printed on desired areas. Upon UV exposure and then release from the surface it is anchored on, the nanocellulose device will spontaneously self-mold into a desired form due to stress differences between the SU-8 and the nanocellulose sheet. The flexible electronics can be manufactured using standard printed circuit board processing techniques, including electroless metallization and soldering of surface mount components.

Abstract: Patterns of homogenous, electroless-plated metals within and on one or both sides of a porous substrate (such as nanocellulose sheets) enable the formation of an matrix of metal within pores of the substrate that can connect patterns on both sides of the substrate. These can serve as circuits with applications in, for example, wearable electronics.

Abstract: The properties of microbial pellicles are tuned by adjusting the physical culture conditions. A culture of Gluconacetobacter xylinus can be grown in a liquid growth media having a surface exposed to air so that a basal pellicle of microbial cellulose forms on the surface. Feeding the culture by adding additional liquid growth media at the surface, thereby submerging the basal pellicle; and then allowing the culture to grow again forms a second pellicle of microbial cellulose.

Abstract: A method of direct-write manufacturing (3D printing) includes a simple to manufacture printhead configured to create sheathed flow. The method is operable at room temperature and suitable for use with sensitive materials.

Abstract: A masked etching process can prepare patterned nanocellulose for use in conformal electronics such as electrodermal structures might be adhered to human skin.

Abstract: A masked etching process can prepare patterned nanocellulose for use in conformal electronics such as electrodermal structures might be adhered to human skin.